Detection and analysis of genetic material of a biological organism can be employed for pathogen identification, genotyping, biomarker identification, personalized medicine, personalized nutrition, personalized skincare, personalized cosmeceuticals, personalized nutraceuticals, companion diagnostics, drug monitoring, pharmacogenetics and nutrigenomics. The identity of a species in a biological sample can be ascertained by comparing the nucleic acid present in the sample to the nucleic acid in a known reference sample. Before making this comparison, however, the nucleic acids must be extracted from the sample, amplified, and then detected. Typically, the extraction, amplification, and detection steps take place over the course of hours, days, or weeks in a laboratory or a hospital. For example, amplification usually involves the polymerase chain reaction (PCR) as described U.S. Pat. Nos. 4,683,202 and 4,683,195. To amplify the nucleic acids using conventional PCR, the nucleic acids must be repeatedly heated and cooled in the presence of enzymes, nucleotides, primers, and buffers.
Traditional methods and devices for extraction, amplification, and detection of nucleic acids are not typically robust enough to be performed in a mobile or field setting outside a specialized lab infrastructure. Extraction and amplification alone takes hours if not days, depending on the type of organism, the length of the nucleic acid strand, and the number of cycles. In addition, commercially available devices and methods require skilled labor, running water, and electricity. Furthermore, the temperature, pH, and buffer ingredients must be tightly controlled. Contaminants can inhibit or interfere with the nucleic acid polymerase enzymes used in replication, reducing the efficiency and fidelity of the amplification process. Similar restrictions apply to conventional techniques for extracting and detecting nucleic acids. Therefore, the need exists for an automated, integrated, compact, robust, rapid, accurate and easy-to-use device and method for detecting, quantifying and identifying nucleic acids.
The present invention relates to a system and method for rapid analysis, quantification, and identification of nucleic acids or proteins.
The present invention provides a portable or mobile or point-of-care (POC) system for extracting, optionally amplifying, and detecting (and optionally quantifying) nucleic acids or proteins using a compact integrated chip in combination with a portable system or mobile device for analyzing detected signals, and comparing and distributing the results via a wireless network. Swappable modules may be used for one or more of extraction, amplification and detection.
The present invention possesses a number of advantages. The present invention is faster, cheaper, more field-deployable and more precise than existing methods for detecting and analyzing nucleic acids or, in some embodiments, proteins. Unlike conventional methods, which take hours to weeks to characterize or analyze even large samples, the present invention typically produces measurements in under an hour, or under half an hour, for example, in minutes. The present invention is sensitive enough to detect nucleic acids extracted from a sample that contains a few cells (see Exemplification). Unlike the standard diagnostic devices and methods which require bench top equipment in a laboratory or a clinic, highly trained technicians, electricity, water, and, often, refrigeration of samples and reagents, the present invention can be implemented in a portable or mobile device employing an optionally disposable compact integrated chip. Results may be distributed via one or more communications networks such as a wireless network and/or the Internet. The system of the present invention does not require skilled labor or trained technicians, and can work outside of hospital or centralized lab infrastructure. The system of the present invention is robust to various environmental variables and can function at wide range of pH, temperatures, traditional overhead infrastructure and, optionally, without refrigeration.
The present invention can be employed to detect and distinguish nucleic acid molecules or proteins from a single biological organism or other source or a plurality of organisms or sources. Not only can the present invention detect and analyze an unknown nucleic acid but the methodology is sensitive enough to distinguish between species within a genus, or to distinguish point mutations and/or biomarker sequences and/or disease susceptibility alleles. In the embodiments of the present invention that employ disposable integrated chips, there is also a significant cost cutting effect when compared to the cost of the existing diagnostic assays.
Furthermore, in the embodiments of the present invention that employ a non-thermal nucleic acid amplification processes disclosed in U.S. Pat. No. 7,494,791 (the entire disclosure of which is hereby incorporated herein by reference), error rates of less than about 1×10−7 errors/base pair or better (e.g., less than 10−10 errors/base pair) can be achieved. Even with “difficult sequences” (a sequence on which a polymerase enzyme has the tendency to slip, make errors, or stop working; examples of difficult sequences include repeating sequences, poly-A sequences, GC-rich sequences, trinucleotide repeat sequences, etc.) error rates of less than 1×10−3 errors/base pair or better (e.g., less than 10−6 errors/base pair) can be achieved. The disclosed non-thermal nucleic acid amplification methods can be used to amplify sequences of up to 20,000 base pairs long, employing reagents that can survive more than 100 cycles of nucleic acid replication. Other isothermal methods of amplification may be used, for example a Loop Mediated Isothermal Amplification (LAMP) technique, such as those set forth in T. Notomi, et al., Nucleic Acids Research, 28, e63 (2000)); a Helicase-Dependent Amplification (HDA) technique, such as those set forth in Vincent M, Xu Y, Kong H. (2004), “Helicase-dependent isothermal DNA amplification,” EMBO Rep 5 (8): 795-800; a Strand Displacement Amplification (SDA) technique, such as those set forth in G. T. Walker, et. al., Proc. Natl. Acad. Sci USA, 89, 392-396 (1992); the entire teachings of all of which references are hereby incorporated herein by reference. Bridge, rolling circle and any other methods of amplification (thermal or isothermal) may be used.
In one embodiment according to the invention, there is provided a system for rapid analysis of biological samples. The system comprises a mobile device that receives at least one integrated chip. The mobile device processes the integrated chip to analyze a biological sample loaded thereon. The mobile device and the integrated chip together are configured to perform at least one of manipulation and control of a molecule or a fluidic system on the integrated chip. The mobile device and integrated chip together are configured to precision control at least one parameter that governs at least one of a plurality of steps of the analysis of the biological sample to within plus or minus 10%, plus or minus 1%, plus or minus 0.1%, plus or minus 0.01%, plus or minus 0.001% or plus or minus 0.0001%.
In another embodiment according to the invention, there is provided a system for rapid analysis of biological samples. The system comprises a portable control assembly that receives at least one compact integrated chip. The integrated chip comprises an extraction module; optionally a nucleic acid amplification module, in fluid communication with the extraction module; and a biological sample detection module, in fluid communication with the nucleic acid amplification module or extraction module. The portable control assembly processes the integrated chip to analyze a biological sample loaded thereon by employing: an extraction control module; a nucleic acid amplification control module operably connected to the extraction control module; and a biological sample detection control module operably connected with the nucleic acid amplification module and the extraction module.
In another embodiment according to the invention, there is provided a system for rapid analysis of biological samples. The system comprises a portable control assembly that receives at least one compact integrated chip. The integrated chip comprises an injection port for loading a biological sample and, optionally, one or more reagents, onto the integrated chip; an extraction module; a nucleic acid amplification module, in fluid communication with the extraction module; and a detection module, in fluid communication with the nucleic acid amplification module. The portable assembly comprises an extraction control module, comprising in some embodiments, for example, a magnetic particles capturing means for capturing magnetic particles introduced into the biological sample loaded onto the integrated chip; a nucleic acid amplification control module operably connected to the extraction control module, said nucleic acid amplification means comprising in some embodiments, for example, a thermoelectric, thin film, infrared or optical based or mechanical heating means for heating/cooling the nucleic acid amplification module of the integrated chip; and a detection control module operably connected with the nucleic acid amplification module and the nucleic acid extraction module. The detection control module comprises in some embodiments a fluorescence detection means for detecting nucleic acids or proteins; and in some embodiments, for example, a capillary electrophoresis (CE) control means operably connected to the fluorescence detection means, said CE control means further including a high voltage control unit for applying voltage across the nucleic acid detection module of the integrated chip, said voltage being sufficient for effecting separation of nucleic acids or proteins; and a fluid pressure generating means for moving the biological sample and/or nucleic acids through the integrated chip.
In another embodiment according to the invention, there is provided a method for rapid analysis of biological samples. The method comprises (1) providing at least one integrated chip, said integrated chip comprising: a nucleic acid extraction module; a nucleic acid amplification module, in fluid communication with the nucleic extraction module; and a nucleic acid detection module, in fluid communication with the nucleic acid amplification module, (2) loading the at least one biological sample onto the at least one integrated chip; (3) operably connecting a portable control assembly with at least one integrated chip, said portable control assembly comprising: a nucleic acid extraction control module; a nucleic acid amplification control module operably connected to the nucleic acid extraction control module; and a nucleic acid detection control module operably connected with the nucleic acid amplification module and the nucleic acid extraction module; and (4) activating the portable control assembly to effect extraction, amplification and detection of nucleic acid from the biological sample loaded onto said integrated chip.
In another embodiment according to the invention, there is provided a method for rapid analysis of biological samples. The method comprises (1) providing at least one integrated chip, said integrated chip comprising: a protein extraction module; and a protein detection module, in fluid communication with the protein extraction module, (2) loading the at least one biological sample onto the at least one integrated chip; (3) operably connecting a portable control assembly with at least one integrated chip, said portable control assembly comprising a protein extraction control module; and a protein detection control module operably connected with the protein extraction module; and (4) activating the portable control assembly to effect extraction and detection of protein from the biological sample loaded onto said integrated chip.
In another embodiment according to the invention, there is provided an integrated chip for rapid sequential extraction, amplification and separation of nucleic acid in a biological sample. The integrated chip comprises a housing having integrated therein microfluidic channels in sequential fluid communication with a nucleic acid extraction module, a nucleic acid amplification module and a nucleic acid separation module; at least one sample inlet port for injecting biological samples and reagents in fluid communication with the nucleic acid extraction module; wherein the nucleic acid extraction module comprises at least one extraction chamber for extracting nucleic acids from the biological samples, said extraction chamber connected to the sample inlet port by at least one sample transport channel; wherein the nucleic acid amplification module comprises at least one amplification chamber for amplifying nucleic acids, said nucleic acid amplification chamber connected to the extraction chamber by at least one nucleic acid transport channel; and wherein the nucleic acid separation module comprises at least one detection channel for separating and detecting the nucleic acids, said detection channel connected to the nucleic acid amplification chamber by at least one amplification product transport channel.
In another embodiment according to the invention, there is provided a method for rapid analysis of biological samples. The method comprises providing at least one integrated chip, said integrated chip comprising: a nucleic acid extraction module; a nucleic acid amplification module, in fluid communication with the nucleic extraction module; and a nucleic acid detection module, in fluid communication with the nucleic acid amplification module. The method further comprises loading the at least one biological sample onto the at least one integrated chip; and operably connecting a portable control assembly with at least one integrated chip. The portable control assembly comprises a nucleic acid extraction control module; a nucleic acid amplification control module operably connected to the nucleic acid extraction control module; and a nucleic acid detection control module operably connected with the nucleic acid amplification module and the nucleic acid extraction module. The method further comprises activating the portable control assembly to effect extraction, amplification and detection of nucleic acid from the biological sample loaded onto said integrated chip; and, based on the detection of the nucleic acid from the biological sample, determining at least one biomarker associated with a person who is the source of the at least one biological sample.
In further, related embodiments, the method may comprise, based on at least one biomarker, determining at least one of: (i) a dosage of at least one drug to effect therapeutic treatment of a disease condition associated with the at least one biomarker; (ii) a combination of a plurality of drugs to effect therapeutic treatment of the disease condition associated with the at least one biomarker; and (iii) a determination of whether the person who is the source of the at least one biological sample is a responder to a drug therapy for the disease condition associated with the at least one biomarker.
In other, related embodiments, the method may comprise, based on the detection of the nucleic acid from the biological sample, determining an amount, in the at least one biological sample, of at least one biomarker associated with a person who is the source of the at least one biological sample; and, based on the amount of the at least one biomarker in the at least one biological sample, determining a degree of progress of treatment of a disease condition associated with the at least one biomarker, in the person who is the source of the at least one biological sample.
In further related embodiments, the method may comprise, based on the detection of the nucleic acid from the biological sample, determining at least one biomarker associated with a person who is the source of the at least one biological sample; and based on the at least one biomarker, determining at least one of (i) a selection of a personal care product for the person who is the source of the at least one biological sample, (ii) a delivery amount of the personal care product for the person, (iii) for example, a cosmetic skin type of the person, and (iv) an amount of at least one cosmetic biomarker of the person in the at least one biological sample.
In other related embodiments, the method may comprise, based on the detection of the nucleic acid from the biological sample, determining an amount, in the at least one biological sample, of at least one cosmetic biomarker associated with a person who is the source of the at least one biological sample; and, based on the amount of the at least one biomarker in the at least one biological sample, determining a degree of progress of a cosmetic treatment in the person who is the source of the at least one biological sample.
In further related embodiments, the method may comprise, based on the detection of the nucleic acid from the biological sample, determining at least one biomarker associated with a person who is the source of the at least one biological sample; and, based on the at least one biomarker, determining a degree or type of health of the person who is the source of the at least one biological sample.
In other related embodiments, the method may comprise, based on the detection of the nucleic acid from the biological sample, determining at least one biomarker associated with a person who is the source of the at least one biological sample; and, based on the at least one biomarker, determining whether the person who is the source of the at least one biological sample is a member of a subset genetic population relative to the at least one biomarker.
In further related embodiments, the method may comprise, based on the detection of the nucleic acid from the biological sample, determining at least one biomarker associated with a person who is the source of the at least one biological sample; and, based on the at least one biomarker, determining at least a portion of a personalized genomic profile of a person who is the source of the at least one biological sample.
In further, related embodiments, determining the at least a portion of the personalized genomic profile may comprise detecting a nucleic acid related to wellness of the person, sports nutrition of the person, personalized diet of the person and nutrition or personalized nutrition of the person.
In another embodiment according to the invention, there is provided a system for rapid analysis of biological samples. The system comprises at least one integrated chip, said integrated chip comprising: a nucleic acid extraction module; a nucleic acid amplification module, in fluid communication with the nucleic extraction module; and a nucleic acid detection module, in fluid communication with the nucleic acid amplification module, at least one biological sample being loaded onto the at least one integrated chip. The system further comprises a portable control assembly comprising: a nucleic acid extraction control module; a nucleic acid amplification control module operably connected to the nucleic acid extraction control module; and a nucleic acid detection control module operably connected with the nucleic acid amplification module and the nucleic acid extraction module; the portable control assembly effecting extraction, amplification and detection of nucleic acid from the biological sample loaded onto said integrated chip. The system further comprises a genetic analysis unit configured to determine, based on the detection of the nucleic acid from the biological sample, at least one biomarker associated with a person who is the source of the at least one biological sample. The genetic analysis unit is further configured to determine, based on the at least one biomarker, at least a portion of a personalized genomic profile of a person who is the source of the at least one biological sample.
In another embodiment according to the invention, there is provided a system for rapid analysis of biological samples. The system comprises at least one integrated chip, said integrated chip comprising: a nucleic acid extraction module; a nucleic acid amplification module, in fluid communication with the nucleic extraction module; and a nucleic acid detection module, in fluid communication with the nucleic acid amplification module, at least one biological sample being loaded onto the at least one integrated chip. The system further comprises a portable control assembly comprising: a nucleic acid extraction control module; a nucleic acid amplification control module operably connected to the nucleic acid extraction control module; and a nucleic acid detection control module operably connected with the nucleic acid amplification module and the nucleic acid extraction module; the portable control assembly effecting extraction, amplification and detection of nucleic acid from the biological sample loaded onto said integrated chip. The system further comprises a genetic analysis unit configured to determine, based on the detection of the nucleic acid from the biological sample, at least one biomarker associated with a person who is the source of the at least one biological sample; and a cardiac pulsation control unit coupled to the genetic analysis unit and configured to control an Enhanced External Counter Pulsation (EECP) or other cardiac pulsation unit based on the at least one biomarker.
Embodiments can perform protein separation such as by electrophoresis.
Further related systems and methods are provided.
The foregoing will be apparent from the following more particular description of example embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating embodiments of the present invention.
A description of example embodiments of the invention follows.
As used herein, the term “fluid” refers to both a gas or a liquid.
As used herein, the term “microfluidic” refers to a device and/or methods operating at or with relating to volumes of fluids from 0.1-100 μL, and preferably between 1 and 10 μL.
As used herein, the term “fluidic system” means a system flowing fluid, for example flowing fluid in at least one channel, at least one chamber, at least one well and/or at least one port, each of which may be microfluidic.
As used herein, “nucleic acid” refers to a macromolecule composed of chains (a polymer or an oligomer) of monomeric nucleotide. The most common nucleic acids are deoxyribonucleic acid (DNA) and ribonucleic acid (RNA). It is further understood that the present invention can be used to detect and identify samples containing artificial nucleic acids such as peptide nucleic acid (PNA), morpholino, locked nucleic acid (LNA), glycol nucleic acid (GNA) and threose nucleic acid (TNA), among others. In various embodiments of the present invention, nucleic acids can be derived from a variety of sources such as bacteria, virus, humans, and animals, as well as sources such as plants and fungi, among others. The source can be a pathogen. Alternatively, the source can be a synthetic organism. Nucleic acids can be genomic, extrachromosomal or synthetic. Where the term “DNA” is used herein, one of ordinary skill in the art will appreciate that the methods and devices described herein can be applied to other nucleic acids, for example, RNA or those mentioned above. In addition, the terms “nucleic acid,” “polynucleotide,” and “oligonucleotide” are used herein to include a polymeric form of nucleotides of any length, including, but not limited to, ribonucleotides or deoxyribonucleotides. There is no intended distinction in length between these terms. Further, these terms refer only to the primary structure of the molecule. Thus, in certain embodiments these terms can include triple-, double- and single-stranded DNA, PNA, as well as triple-, double- and single-stranded RNA. They also include modifications, such as by methylation and/or by capping, and unmodified forms of the polynucleotide. More particularly, the terms “nucleic acid,” “polynucleotide,” and “oligonucleotide,” include polydeoxyribonucleotides (containing 2-deoxy-D-ribose), polyribonucleotides (containing D-ribose), any other type of polynucleotide which is an N- or C-glycoside of a purine or pyrimidine base, and other polymers containing nonnucleotidic backbones, for example, polyamide (e.g., peptide nucleic acids (PNAs)) and polymorpholino (commercially available from Anti-Virals, Inc., Corvallis, Oreg., U.S.A., as Neugene) polymers, and other synthetic sequence-specific nucleic acid polymers providing that the polymers contain nucleobases in a configuration which allows for base pairing and base stacking, such as is found in DNA and RNA.
As used herein, a “protein” is a biological molecule consisting of one or more chains of amino acids. Proteins differ from one another primarily in their sequence of amino acids, which is dictated by the nucleotide sequence of the encoding gene. A peptide is a single linear polymer chain of two or more amino acids bonded together by peptide bonds between the carboxyl and amino groups of adjacent amino acid residues; multiple peptides in a chain can be referred to as a polypeptide. Proteins can be made of one or more polypeptides. Shortly after or even during synthesis, the residues in a protein are often chemically modified by posttranslational modification, which alters the physical and chemical properties, folding, stability, activity, and ultimately, the function of the proteins. Sometimes proteins have non-peptide groups attached, which can be called prosthetic groups or cofactors.
As used herein, a “biological sample” includes a sample of any material that contains nucleic acids and/or proteins that can be extracted, analyzed and detected. Preferably, the material is in liquid or gaseous form, or can be dissolved or suspended in a liquid or gas, or can be liquefied or turned into a gaseous form, or otherwise prepared for analysis by the device and method of the present invention. Solid samples like stool or soil samples could be placed in water and then loaded onto the chip, for example. Aerosol biological samples may be used. The “biological sample” may be, or may be part of, a tissue sample, a biofluid sample, an environmental sample or another type of sample. Preferably, the biological sample is derived from a biological fluid, such as but not limited to blood, saliva, semen, urine, amniotic fluid, cerebrospinal fluid, synovial fluid, vitreous fluid, gastric fluid, nasopharyngeal aspirate and/or lymph. The biological sample can also be a material or fluid that is contaminated with a nucleic acid and/or protein source. The biological sample can be a tissue sample, a water sample, an air sample, a food sample or a crop sample. Preferably, a biological sample analysis detects any one or more of water-born pathogen, air-born pathogen, food-born pathogen or crop-born pathogen.
As used herein, the term “biological analysis” refers to the implementation of biochemical assays in which samples such as cells, nucleic acid, proteins or other biological molecules are used as starting material to extract information for the purposes of diagnosis, species identification, distinguish point mutations and/or disease susceptibility alleles, qualitative analysis, quantitative analysis (e.g., to ascertain viral load), and for other purposes taught herein. An example of an application of this technology is pathogen detection by extracting genetic information from cells. As used herein, the “steps” of a “biological analysis” refers to the steps of extraction, optionally amplification, and detection.
As used herein, a “biomarker” refers to a measured characteristic which may be used as an indicator of some biological state or condition. For example, a biomarker may be measured and evaluated to examine normal biological processes, pathogenic processes, or pharmacologic responses to a therapeutic treatment.
As used herein, a “therapeutic treatment” is the attempted remediation of a health problem.
As used herein, a “genetic analysis unit” refers to a processor, such as a hardware computer processor or other dedicated digital signal processor, that receives electronic signals, stores electronic signals, outputs electronic signals, and processes electronic signals, for example based on a computer program, where the electronic signals are related to a genetic analysis. For example, the genetic analysis unit may be programmed to determine biomarkers based on an input signal related to detected nucleic acids, and to determine and output a personalized genomic profile based on the biomarkers.
As used herein, a “dispensing control unit” refers to a processor, such as a hardware computer processor or other dedicated digital signal processor, that receives electronic signals, stores electronic signals, outputs electronic signals, and processes electronic signals, for example based on a computer program, where the electronic signals are related to dispensing at least a portion of a product. For example, the dispensing control unit may be configured to determine at least a portion of a product to dispense based at least in part on a personalized genomic profile.
As used herein, a “dispensing activator” refers to a device or system configured to dispense at least a portion of a product. For example, the dispensing activator may comprise at least a portion of one of: a vending machine; an automated teller machine; and a kiosk; and may comprise a three dimensional printer configured to print at least a portion of the product, or to dispense a prepackaged product
Portions of embodiments of the present invention, such as a genetic analysis unit, can be implemented using one or more computer systems and may, for example, be a portion of program code, operating on a computer processor. For example, the embodiments may be implemented using hardware, software or a combination thereof. When implemented in software, the software code can be stored on any form of non-transient computer-readable medium and loaded and executed on any suitable processor or collection of processors, whether provided in a single computer or distributed among multiple computers.
As one skilled in the art will appreciate, the present invention can include a hardware portion, a software portion and/or a combination of software and hardware portions. In one embodiment, the present invention is a portable processing means that interfaces with a compact integrated chip to, in one embodiment, extract, amplify, and detect nucleic acids in a biological sample according to computer-useable instructions embodied on a computer-readable medium, or in another embodiment to separate proteins such as by electrophoresis. The system may use swappable modules, as discussed further below in connection with
As used herein, the term “compact” refers to a microfluidic device layout design that minimizes space used by the fluid channels, chambers, wells and ports, as discussed below, such as achieved, for example, by a microfluidic device layout. In one embodiment, the use of intersecting fluid channels and shared wells exemplifies a compact design. As used herein, the term “integrated” refers to a microfluidic device layout design in which fluid channels, chambers, wells and ports used for various purposes are assembled on/in the same microfluidic device. For example, the embodiment of the chip shown in
The system can store the indications pertaining to the detected nucleic acid in the computer-readable medium or cloud and compare those indications to records stored in genomic or transcriptomic databases, which may be stored in the computer-readable medium or in a remote location. In alternative embodiments, the information pertaining to a reference standard is stored in a computer-readable memory disposed within the system. In yet another embodiment, a nucleic acid standard is included in an integrated chip that can be employed with the system of the present invention.
The processor means may comprise, for example, a minicomputer, a microcomputer, a UNIX machine, a personal computer such as one with an Intel processor or similar device, microprocessor or other appropriate computer or even a smartphone. It also usually comprises conventional computer components (not shown) such as a motherboard, a central processing unit (CPU), random access memory (RAM), disk drives, and peripherals such as a keyboard and a display. The RAM stores an operating system such as Windows CE or other operating system and appropriate software for processing signals pertaining to detected nucleic acids or proteins.
Portions of embodiments of the present invention described herein can be implemented using one or more computer systems. For example, the embodiments may be implemented using hardware, software or a combination thereof. When implemented in software, the software code can be stored on any form of non-transient computer-readable medium and loaded and executed on any suitable processor or collection of processors, whether provided in a single computer or distributed among multiple computers.
Further, it should be appreciated that a computer may be embodied in any of a number of forms, such as a laptop computer, a tablet computer, or a computer embedded in a device not generally regarded as a computer but with suitable processing capabilities, including a Personal Digital Assistant (PDA), a smart phone or any other suitable portable or mobile electronic device.
Also, a computer may have one or more input and output devices. These devices can be used, among other things, to present a user interface. Examples of output devices that can be used to provide a user interface include printers or display screens for visual presentation of output and speakers or other sound generating devices for audible presentation of output. Examples of input devices that can be used for a user interface include keyboards, and pointing devices, such as mice, touch pads, and digitizing tablets. As another example, a computer may receive input information through speech recognition or in other audible format.
Such computers may be interconnected by one or more networks in any suitable form, including as a local area network or a wide area network, such as an enterprise network or the Internet. Such networks may be based on any suitable technology and may operate according to any suitable protocol and may include wireless networks, wired networks or fiber optic networks.
Also, the various methods or processes outlined herein may be coded as software that is executable on one or more processors that employ any one of a variety of operating systems or platforms. Additionally, such software may be written using any of a number of suitable programming languages and/or programming or scripting tools, and also may be compiled as executable machine language code or intermediate code that is executed on a framework or virtual machine.
In this respect, at least a portion of the invention may be embodied as a computer readable medium (or multiple computer readable media) (e.g., a computer memory, one or more floppy discs, compact discs, optical discs, magnetic tapes, flash memories, circuit configurations in Field Programmable Gate Arrays or other semiconductor devices, or other tangible computer storage medium) encoded with one or more programs that, when executed on one or more computers or other processors, perform methods that implement the various embodiments of the invention discussed above. The computer readable medium or media can be transportable, such that the program or programs stored thereon can be loaded onto one or more different computers or other processors to implement various aspects of the present invention as discussed above.
In this respect, it should be appreciated that one implementation of the above-described embodiments comprises at least one computer-readable medium encoded with a computer program (e.g., a plurality of instructions), which, when executed on a processor, performs some or all of the above-discussed functions of these embodiments. As used herein, the term “computer-readable medium” encompasses only a non-transient computer-readable medium that can be considered to be a machine or a manufacture (i.e., article of manufacture). A computer-readable medium may be, for example, a tangible medium on which computer-readable information may be encoded or stored, a storage medium on which computer-readable information may be encoded or stored, and/or a non-transitory medium on which computer-readable information may be encoded or stored. Other non-exhaustive examples of computer-readable media include a computer memory (e.g., a ROM, a RAM, a flash memory, or other type of computer memory), a magnetic disc or tape, an optical disc, and/or other types of computer-readable media that can be considered to be a machine or a manufacture.
The terms “program” or “software” are used herein in a generic sense to refer to any type of computer code or set of computer-executable instructions that can be employed to program a computer or other processor to implement various aspects of the present invention as discussed above. Additionally, it should be appreciated that according to one aspect of this embodiment, one or more computer programs that when executed perform methods of the present invention need not reside on a single computer or processor, but may be distributed in a modular fashion amongst a number of different computers or processors to implement various aspects of the present invention.
Computer-executable instructions may be in many forms, such as program modules, executed by one or more computers or other devices. Generally, program modules include routines, programs, objects, components, data structures, etc. that perform particular tasks or implement particular abstract data types. Typically the functionality of the program modules may be combined or distributed as desired in various embodiments.
In one embodiment, the portable assay system 10 is about the size of a mobile wireless device, as shown in
Once the user loads the integrated chip 20, the portable assay system 10 extracts, amplifies, and detects nucleic acids in the sample 22 using methods described below, or depending upon other modules used such as electrophoresis. A microprocessor (not shown) processes the detected signal, which may be presented to the user via the display means 12 and transmitted to other users via a communication means 18. The communication means 18 may be used to transmit and receive modulated data signals pertaining to the biological sample 22.
The term “modulated data signal” refers to a propagated signal that has one or more of its characteristics set or changed to encode information in the signal. An exemplary modulated data signal includes a carrier wave or other transport mechanism. Communications media include any information-delivery media. By way of example but not limitation, communication media include: wired media, such as a wired network or direct-wired connection, and wireless media such as acoustic, infrared, radio, microwave, spread-spectrum, and other wireless-media technologies.
The present invention can include a genomic or transcriptomic database for storing a plurality of genomic or transcriptomic profiles or target biomarker sequences. In one embodiment, the present invention can include a signal profile of a single reference sample. The device of the present invention can also connect to a remotely located genomic or transcriptomic database, such as those maintained by the National Institutes of Health, Center for Disease Control, etc. Such connection would facilitate tracking and coordinating responses to outbreaks of disease at widely dispersed analysis sites. Exemplary analysis sites include hospitals, border crossings, airports, refugee camps, farms, quarantine zones, disaster sites, homeless shelters, nursing homes, meat-packing plants, and food processing centers. Those skilled in the art will appreciate still other analysis sites to which the present invention is applicable.
The present invention need not connect directly to genomic or transcriptomic databases, although it may if need be. In other embodiments, the device can connect to genomic or transcriptomic databases through various networks, public or private, such as Local-Area Networks (LANs), Wide-Area Networks (WANs), or the Internet. In one embodiment, genomic databases are accessible across a public network such as the Internet. Data is communicated in a secure means, such as via Secure Socket Layer (SSL) or secure copy.
In the embodiment shown in
In some versions of the invention, the device is mobile, or POC and optionally hand-held.
The portable assay system 10 (
Each of the modules may comprise one of various implementations and combinations, as shown in
Biological sample 22 (
Nucleic acids are extracted in the nucleic acid extraction module 25 of the integrated chip 20 (
In one embodiment, magnetic beads can have a nucleic acid probe attached thereto, optionally, covalently. In this embodiment, a small electromagnet or magnet may be used to control the magnetic beads in the extraction module. Magnetic beads that can be employed are any of the commercially available magnetic beads nucleic acid purification kits available from such vendors as Agencourt Bioscience, Cosmo Bio Co., Ltd. Invitek GmbH, Polysciences, Inc., Roche Applied Science, B-Bridge International, Dynal Biotech, Novagen, or Promega. The use of magnetic beads for DNA or RNA purification is described, for example in Caldarelli-Stefano et al., “Use of magnetic beads for tissue DNA extraction and IS6110 Mycobacterium tuberculosis PCR”, Mol Pathol. 1999 June; 52(3): 158-160.
As shown in
The extracted nucleic acids can be amplified within the nucleic acid amplification module 27 of the integrated chip 20 (
In some embodiments, nucleic acid amplification includes reverse transcription polymerase chain reaction (RT-PCR).
Referring to
As shown in
In another embodiment, the module 50 (see
In other embodiments, the module 50 (see
In other embodiments, the module 50 (see
As used herein, the term “tension”, when used in the context of nucleic acid amplification, processing and/or detection, refers to an alternative to thermal cyling or thermal denaturation of double-stranded nucleic acid or to a non-thermally driven process of nucleic acid amplification or denaturation or annealing or primer extension. Application of “tension” to nucleic acids is a result of applying a physical force, other than derived solely from thermal energy, to nucleic acid strands. Tension can be “precision controlled” (as defined elsewhere herein), and/or adjustably controlled and/or variable.
The precision controlled tension can be mechanical tension, hydrodynamic tension, electromagnetic tension or a combination thereof. Furthermore, in some embodiments, the means for applying controlled tension to the nucleic acid strands are configured to operate isothermally. As used herein in the context of nucleic acid amplification, processing and detection, the term “isothermal” refers to a method of nucleic acid amplification in which no thermal cycling is necessary, and, preferably, a process of amplification all steps of which can be performed at substantially the same temperature.
The embodiments that employ the means for controlled tension to nucleic acid strands within the nucleic acid amplification module of the integrated chip (see
The embodiments employing means for applying controlled tension to nucleic acid strands include a mechanism for applying a variable and controlled amount of tension to the nucleic acid molecules retained within the nucleic acid amplification module of the integrated chip (see
The amplified nucleic acids are detected in the nucleic acid detection module 29 of the integrated chip 20 (
In various embodiments, module 60 can comprise a fluorescence or electro-optic detection means 950 for detecting nucleic acids as shown in
The amplified nucleic acids may be separated and detected using capillary electrophoresis as disclosed in U.S. Pat. No. 6,261,431, incorporated herein by reference in its entirety. In some embodiments, module 60 can comprise a capillary electrophoresis (CE) control means for effecting separation of nucleic acids, said CE control means operably connected to the fluorescence detection means. The CE control means can further include a high voltage control unit for applying voltage across the nucleic acid detection module 60 of the integrated chip 20, said voltage being sufficient for effecting separation of nucleic acids.
Referring to
In alternative embodiments, the nucleic acid detection control module 60 further comprises a hybridization microarray such as GeneChip® microarrays, available from Affimetrix, Santa Clara, CA.
In one embodiment, the nucleic acid detection control module 60 comprises an electrochemical means for detecting nucleic acids. An example of an electrochemical means for detecting nucleic acids is provided in U.S. Pat. App. Pub. US 2008/0081329, incorporated herein by reference in its entirety. Briefly, such means implement a method for determining the presence or absence of a target substrate in a test sample. The means include an electrode having a conductive surface, and a probe that is bound to the conductive surface and is capable of binding to a target substrate. The conductive-surface bound probe is contacted with the test sample to form a surface-bound target complex. The surface-bound target complex further comprises a first redox complex. The surface-bound probe or the surface-bound target complex, if present, are contacted with a fluid medium comprising a second redox complex, wherein one of the first or the second redox complex is a redox transition metal complex that is capable of undergoing an oxidation-reduction reaction and the other of the first or the second redox complex is a redox-catalyst complex that is capable of catalyzing the oxidation-reduction reaction of the redox transition metal complex. The redox transition metal complex does not undergo any significant amount of oxidation-reduction reaction in the absence of the redox-catalyst complex. The oxidation-reduction reaction of the redox transition metal complex that is catalyzed by the redox-catalyst complex is detected.
In another embodiment, the nucleic acid detection control module 60 comprises an impedance-measuring means for detecting nucleic acids. An example of an impedance-measuring means for detecting nucleic acids is described, for example, in U.S. Pat. No. 7,169,556, incorporated herein by reference in its entirety. Briefly, the method comprises contacting a nucleic acid having a first portion and a second portion with a substrate having oligonucleotides attached thereto, the oligonucleotides being located between a pair of electrodes, the oligonucleotides having a sequence complementary to a first portion of the sequence of said nucleic acid, the contacting taking place under conditions effective to allow hybridization of the oligonucleotides on the substrate with said nucleic acid. After hybridization of a nucleic acid and an oligonucleotide has occurred, the nucleic acid bound to the substrate is contacted with a first type of conductive particles (e.g., metal beads), the conductive particles being made of a material which can conduct electricity, the conductive particles having one or more types of oligonucleotides attached thereto, at least one of the types of oligonucleotides having a sequence complementary to a second portion of the sequence of said nucleic acid, the contacting taking place under conditions effective to allow hybridization of the oligonucleotides on the conductive particles with the nucleic acid so as to form a test substrate having conductive particles complexed thereto. After the second hybridization has occurred, the test substrate is contacted with an aqueous salt solution having a salt concentration effective to sufficiently dehybridize and remove non-specifically bound conductive particles. Hybridization/dehybridization results in a detectable change in impedance between the electrodes resulting from the presence of specifically bound conductive particles.
In accordance with an embodiment of the invention, any one of many different possible techniques for extraction, amplification and detection may be used in combination; or indeed one or more of extraction, amplification and detection may be omitted altogether from the combination of extraction, amplification and detection. For example, in the modular system of
In accordance with an embodiment of the invention, different integrated chips may be able to be analyzed by a single mobile device, with each of the different possible integrated chips implementing a different functionality that is recognized and performed by the single mobile device. For example, one chip may be used for analyzing nucleic acids, and another chip may be used in the same mobile device for analyzing proteins.
A diagram of a typical flow of material and data through the system of the present invention, such as the modular system depicted in
Likewise, in some embodiments, a Peltier device or thin film heater or other means of temperature control can be used to heat and cool the nucleic acid amplification chamber 108 (
In some embodiments, the system 10 (
Means for controlling valves (such as valves shown in more detail in
In some embodiments, the system 10 (
In certain embodiments, the signal intensity versus time may be analyzed to give an indication of the types and quantities of the nucleic acid species present in the biological sample 22 (
In other embodiments, the system 10 further comprises a data displaying means for outputting data.
The portable assay system 10 interfaces with the integrated chip 20 through electrical, thermal, and mechanical interfaces. Clamps and/or catches hold the chip in place with sufficient steadiness to ensure that vibrations do not cause electrodes, detectors (such as photodetectors), or heater to become misaligned. A heater (and optionally a cooling element like an inkjet cooler) (not shown) positioned under, above or on the amplification control module 40 heats and/or cools certain sections of the chip, as described below. Similarly, electrodes positioned near the detection control module 60 can be used to control the separation and flow of fluid through the chip, as described below. Because the chip 20 is transparent, electromagnetic beams, such as infrared or electromagnetic beams for heating or optical beams for interrogating fluorescent tags, can be used to probe wells, chambers, and channels in the chip 20.
While the description below refers to specific embodiments of the integrated chip 20 (
In one embodiment, the present invention is a compact integrated chip for use with a system for rapid analysis of biological samples.
The integrated chip 20 may be formed of glass, any plastic with good optical properties including but not limited to, Polyethylene, Polypropylene, Poly(Urethane-Imide), poly(tetrafluoroethylene), polycarbonate, Cyclic Olefin Copolymer (COC), polyamides, Cyclic Olefin Polymer (COP), poly(methyl methacrylate), polyacrylamide, polystyrene, PMMA, or any other suitable material or combination of materials.
The integrated chip comprises at least one sample inlet port for injecting biological samples and reagents; a nucleic acid extraction module, comprising at least one extraction chamber for extracting nucleic acids from the biological samples, said extraction chamber connected to the sample inlet port by at least one sample transport channel; a nucleic acid amplification module, comprising at least one amplification chamber for amplifying nucleic acids, said nucleic acid amplification chamber connected to the extraction chamber by at least one nucleic acid transport channel; and a nucleic acid detection module, comprising at least one detection channel for separating and detecting the nucleic acids, said detection channel connected to nucleic acid amplification chamber by at least one amplification product transport channel. Preferably, the at least one sample inlet port, the at least one extraction chamber, the at least one amplification chamber, and the at least one detection channel are arranged to minimize the utilization of space. As discussed above in connection with
Preferably, the nucleic acid amplification module further includes at least one reagent addition port in fluid communication with at least one nucleic acid transport channel. In certain embodiments, the nucleic acid detection module further comprises at least one sample well in fluid communication with at least one amplification product transport channel. In some embodiments, the nucleic acid detection module further comprises at least one sample waste well in fluid communication with at least one detection channel; a buffer waste well in fluid communication with at least one detection channel; and a buffer well in fluid communication with at least one detection channel. Preferably, the integrated chip of the present invention comprises at least two sample inlet ports; at least two nucleic acid extraction chambers, each said nucleic acid extraction chamber connected to one of the at least two sample inlet ports by a respective sample transport channel; at least two nucleic acid amplification chambers, each said nucleic acid amplification chamber connected to one of the at least two extraction chambers by a respective nucleic acid transport channel; and at least two detection channels, each said detection channel connected to a respective nucleic acid amplification chamber by a respective amplification product transport channel.
In embodiments, at least two detection channels intersect. In one embodiment, shown in
The integrated chip can further comprise at least two reagent addition ports, each said reagent addition port in fluid communication with a respective nucleic acid transport channel; at least two sample wells, each said sample well in fluid communication with a respective amplification product transport channel. Preferably, at least two sample wells are configured for use for addition and/or disposal of additional reagents.
In certain embodiments, the integrated chip further comprises at least one sample waste well, each said at least one sample waste well connected with at least two detection channels by at least two sample waste channels. Preferably, at least one sample waste well is configured for use for addition and/or disposal of additional reagents.
In other embodiments, the integrated chip further comprises at least one buffer waste well, each said buffer waste well in fluid communication with at least two detection channels; and a buffer well in fluid communication with at least two detection channel. Preferably, at least one buffer waste well and the buffer well are configured for use for addition and/or disposal of additional reagents.
In one embodiment, the buffer well is disposed at the point of intersection of at least two detection channels, and wherein the buffer well is in fluid communication with said intersecting detection channels.
Preferably, wherein each sample waste channel connects to the detection channel downstream from the at least one amplification product transport channel, thereby effectively increasing the cross-section of the intersection of the at least one amplification product transport channel and the at least one amplification product transport channel (see
In some embodiments, the integrated chip further including microfabricated protrusions (posts) disposed in at least one nucleic acid extraction chamber and/or in at least one sample transport channel. As discussed earlier, microfabricated protrusions disposed on the integrated chip can be used for mechanical shearing of cells in the biological sample, as described, for example, in U.S. Pat. No. 5,635,358 and WO 2006/06029387, incorporated herein by reference in their entirety.
The integrated chip can further be provided with at least two electrodes for applying voltage across the at least one detection channel. In other embodiments, the integrated chip can include additional electrical contacts for providing power and/or control signals to electrically-actuated mechanism that can be disposed within the integrated chip.
In one aspect, the present invention is a novel valve assembly as shown in
In one embodiment, the valve assembly comprises a microfluidic channel for transporting fluid, said microfluidic channel formed between a top surface and a bottom surface and having a longitudinal axis; a valving port in the top surface for receiving a passive plug; and a passive plug configured for insertion into the valving port. Preferably, the portion of the bottom surface opposite the valving port has uniform depth along longitudinal axis. This arrangement simplifies the manufacturing process of the integrated chip by eliminating or reducing the stringency for alignment of the parts.
In another embodiment, the valve assembly comprises a transport channel for transporting fluid; a ferrofluidic channel intersecting said transport channel; a first ferrofluidic reservoir and a second ferrofluidic reservoir, said first and second ferrofluidic reservoirs connected by the ferrofluidic channel; ferrofluid in either one or both ferrofluidic reservoirs; and a permanent magnet or an electromagnet for filling the ferrofluidic channel with the ferrofluid. Ferrofluids are typically colloidal mixtures comprising magnetic particles suspended in a liquid and further having a detergent/surfactant admixed to the liquid to prevent the particles from clumping together. (See also Berger, et al. (July 1999). “Preparation and properties of an aqueous ferrofluid”. Journal of Chemical Education 76 (7): pp. 943-948), incorporated herein by reference in its entirety.) Any commercially available ferrofluids can be used, such as, for example, ferrofluid available from Ferrotec Corporation, Bedford, NH.
In yet another embodiment, and now referring to
In the embodiment shown in
Each sample region 130 includes one sample inlet port 100, one extraction chamber 104, one amplification chamber 108 and one detection channel 112. It is understood that for each biological sample, there is a separate and discernable pathway from a respective sample inlet port to a respective extraction chamber, further to a respective amplification chamber and then to a respective detection channel. Thus, cross-contamination of sample is avoided and sample integrity is ensured. However, there are common wells (e.g. sample waste wells 118 and buffer wells 112) that are shared by several sample regions. This sharing reduces space required for the integrated chip layout and also reduces waste of material.
It will be understood that the chip may be configured with any number of sample regions (for example, 1, 12, 24, 256, 386 or 512), provided that the size of a sample region 130 is sufficient to extract, amplify, and detect nucleic acids. The sample regions 130 can be used to analyze multiple different samples for the same target biomarker sequence or pathogen, one sample for multiple different pathogens or biomarkers, or any suitable permutation or combination of samples and pathogens or biomarkers, providing suitable references are available.
The biological sample 22 (see
Fluid flow through the channels, ports, wells, and chambers is controlled by a combination of valves and propulsions means, which may be a hand-pumped syringe coupled to the sample inlet port 100. Other propulsion means such as peristaltic pumps or piston pumps can also be used. The propulsion means propel fluids through channels and chamber unless a closed valve blocks the fluid flow. Valves may use any one of a number of technologies, including technologies such as manually actuated plugs, mechanically actuated plugs, electromagnetically actuated plugs, ferrofluidic valves, pneumatic valves, or any other suitable technology.
For example,
Fluid enters the well 702 through an inlet 704. Fluid can exit the well 702 through either outlet port 706a or outlet port 706b, depending on the position of the ferrofluid 602. As shown in
Referring again the embodiment shown in
The user completes the extraction process by flushing the extraction chamber 104 with a wash (not shown) injected through the sample inlet port. The wash flows through the extraction chamber 104 to a reagent inlet/outlet port 106, from which the user extracts the wash products. The user may repeat the wash cycle until the extracted nucleic acid is sufficiently free of contamination to be amplified and detected.
Once the extracted nucleic acid is free of contaminants, it is forced (e.g., by applying pressure from a syringe or a pump) downstream into a nucleic acid amplification chamber 108, which the user then loads with reagents via the reagent inlet/outlet port 106. The user then isolates the amplification chamber by closing the appropriate valves before initiating amplification by conventional amplification techniques. A thermoelectric heater (not shown) may be used to heat and cool the reagents in the amplification chamber 108. In one embodiment, reagents include primers, a DNA polymerase (such as Taq polymerase), deoxynucleotide triphosphates, buffer solution, and divalent cations.
Once the nucleic acid is sufficiently amplified, the valves isolating the amplification chamber 108 are opened and the amplified nucleic acids are flushed into a sample well 120, which is connected to a detection channel 112 via a transport channel 102 as shown in
In one embodiment, capillary electrophoresis is used to detect and identify nucleic acids present in the biological sample 22. Capillary electrophoresis involves running an electric current through an electrolyte, such as an aqueous buffer solution, mixed with the sample under test in a short (on the order of 50 μm long) channel such as the detection channel 112. The current causes the sample to migrate down the detection channel 112; however, the compounds separate as they migrate because their migration speeds depend on their molecular weights, the current, and the channel size, among other variables.
In one embodiment, the user adds electrolyte solution and, optionally, sieving matrix, to the detection channel 112 through a buffer well 116 (also shown in
In an embodiment, the fluorescence signal 1010 is produced by illuminating the separated load 140 with a laser beam 1004 or LED or other light source of the appropriate frequency. A laser 1002 generates the laser beam 1004, which may be directed to the measurement region using a mirror 1006. Alternatively, the laser beam 1004 may be focused onto the sample with a lens. The beam may also be generated by light-emitting diode or other light source instead of a laser and it may or may not be coupled via fiberoptic cable. It will be understood that a variety of optical arrangements may be used to interrogate the species 140.
The laser beam 1004 excites the separated load 140 to produce a fluorescent beam 1010, which is separated from the laser beam 1004 with a dichroic beamsplitter 1007. In an embodiment, a detector 1012 produces a photocurrent (not shown) in response to the intensity of the fluorescent beam 1010. The photocurrent may be fed to a processor 1014, which may be used to analyze the detected fluorescent beam 1010. For example, the analysis might comprise comparing the detected signal to the reference signal trace 1021 from a known reference sample on an output signal graph 1020, where matching peaks in the traces indicate the presence of identical biomarker sequences or pathogens. Integrating the areas under the peaks gives an indication of the relative amounts of biomarkers or pathogen (i.e., the viral load) present in each sample. In embodiments, software correlates the output signal graph 1020 with the reference signal trace 1021 using standard correlation techniques to yield an output suitable for interpretation by a user.
Embodiments of the present invention include an integrated chip capable of performing the above mentioned biological assay in a single device, also referred to as an integrated microfluidic chip or lab-on-a-chip. The integrated chip is designed to sequentially perform the following three processes: (1) extraction from biological cells; (2) sequence specific nucleic acid amplification by PCR; and (3) size separation of amplified DNA by capillary electrophoresis combined with fluorescence detection of separated DNA.
It will be appreciated that a similar integrated microfluidic chip or lab-on-a-chip to that discussed in the present section may be used for protein detection, with appropriate modification of the techniques for use with protein detection. For example, in detection of a protein, one embodiment may use only an extraction module and a detection module without using amplification. Further, in some embodiments, only a detection module may be used. In other embodiments, only an extraction and nucleic acid sequencing and detection module may be used with no amplification module. Any one of these modules may be used alone or in combination with each other.
In one embodiment, the invention set forth herein is an integrated chip for rapid extraction, amplification and separation of nucleic acid in a biological sample. The invention also comprises a hardware system that receives at least one integrated chip. The integrated chip is a microfluidic device that includes microfluidic channels in sequential fluid communication with functional modules: a nucleic acid extraction module, a nucleic acid amplification module and a nucleic acid separation module.
In one embodiment, a biological sample of interest is loaded onto the integrated chip and the nucleic acid is extracted from the biological sample within the extraction module. For example, the biological sample includes cells, and the cellular DNA is extracted from the cells. The extraction process, preferably, employs nucleic acid precipitation using magnetic beads. The extracted nucleic acid is then transported by fluid pressure into the nucleic acid amplification module, where the nucleic acid is amplified using a polymerase chain reaction. In some embodiments, the amplification employs thermal cycling. In other embodiments, the amplification employs isothermal techniques of amplification including but not limited to the teachings of U.S. Pat. Nos. 7,494,791, 8,632,973 and U.S. patent application Ser. No. 14/106,399, all of Nanobiosym, Inc., the entire teachings of which references are hereby incorporated herein by reference. The amplified nucleic acid products are then transported by fluid pressure into the nucleic acid separation module, where the nucleic acids are separated and detected by employing capillary electrophoresis. Preferably, fluorescently nucleic acid primers are used and the nucleic acid products are detected using fluorescent detection. The three sequential processes described above occur within the same integrated chip.
The sequential process of extraction, amplification, separation/detection is controlled by a hardware system that includes a nucleic acid control module, a nucleic acid amplification control module, and a nucleic acid detection control module. Preferably, these modules respectively control: (1) application of magnet for the precipitation of the magnetic beads-attached nucleic acids, (2) thermal cycling during the amplification of the extracted nucleic acids, and (3) fluorescent-assisted detection of the nucleic acids.
With reference to
Returning to
In the specific embodiment shown in
The reagent inlet/outlet ports 106 are in turn connected to another set of enclosed amplification chambers 108 designed for amplification. Amplification chambers 108 are also connected to sample wells 120 on one side and the reagent inlet/outlet ports 106 (shared with respective extraction chambers 104) on the other side, again enabling fluid flow-through across the amplification chambers 108.
Finally, each of the fluidic paths is independently terminated to a set of individual separation/detection channels (CE channels) 112, in which electrophoresis separation is achieved prior to fluorescence detection towards the end of the CE channels 112. The electrophoresis module is once again uniquely designed to multiplex the injection and separation of all eight samples that were previously subjected to the extraction and amplification processes on-chip.
The wells 120 on the electrophoresis side of the amplification chambers 108 are open and are utilized as CE sample wells 120. Thus, each sample (or amplification product) has a separate CE sample well 120 leading from its respective amplification chamber 108. However, the buffer well 116 required for the CE assay is shared between samples (either all or between two adjacent sample paths) as shown in
Typically, the chip 20 is about the size of a thick credit card. In one embodiment, the chip 20 has a length from 2.5 cm to 25 cm, a width from 2.5 cm to 15 cm, and a thickness from 0.1 mm to 10 mm; preferably, the integrated chip 20 is about 5 cm wide by 10 cm long by 2 mm thick. One of skill in the art will appreciate that size and design of a specific chip will be a matter of design preference.
In a preferred embodiment, the chip 20 feature dimensions are 10-200 μm by 10-200 μm (e.g., 50 μm by 20 μm) for detection (CE) channels 112, and 10-1000 μm by 10-1000 μm (e.g., 200 μm by 100 μm) for all other channels. It will be appreciated that for the channels through which the magnetic beads will flow, a channel dimension is selected to ensure the unobstructed flow of the magnetic beads. The detection (CE) channels 112 can be 10-120 mm long (for example, 80 mm) long. Larger detection CE channels 112 size require higher voltages for CE analysis. The sizes of the other channels, such as transport channels 102, as well as the channels connecting extraction chambers 104 and reagent inlet/outlet ports 106, reagent inlet/outlet ports 106 and amplification chambers 108, amplification chambers 108 and sample wells 120, sample wells 120 and detection channels 112, are not critical.
In preferred embodiments, the circular wells and chambers, such as the buffer wells 116, are 5-15 mm (for example, 10 mm) in diameter and 0.05-1 mm (for example, 0.5 mm) deep. Hexagonal chambers, such as the extraction chambers 104, may be 5-25 (for example, 15 mm) long (tapered edges) and 5-15 mm (for example, 10 mm) wide. This sort of hexagon design facilitates easy fluid flow in the extraction chambers 104, particularly because the process involves high volume fluid flow. Other embodiments can accommodate circular chambers that are 0.1-30 mm in diameter and 0.01-19 mm deep and hexagonal chambers that are 1-25 mm long (tapered edges) and 1-30 mm wide.
Preferred embodiments of the access wells and inlet ports, such as the inlet wells 100, are 0.9-5 mm in diameter, with depths determined by the thickness of the plastic used to make the chip 20. Alternative embodiments can accommodate access wells with diameters of 0.5-10 mm. Again, well depth is determined by the thickness of the plastic used, and is typically between 0.5-2 mm.
Embodiments of the microfluidic chips fabricated for the purpose and application described here are manufactured of plastic, polymers, or biodegradable polymers; hence these chips are cost efficient to produce and can be used as disposable devices. The disposable aspect thus ensures that issues such as carry-over contamination, a typical problem associated with reuse of biological processing tools, are minimized to the extent of elimination. These chips can also be manufactured with glass, silicon and other materials.
The fabrication process associated with the manufacturing of these chips involves microfabrication of structures in silicon (Si) or glass or aluminum (Al) or other such material to create a master with the desired microfluidic structures. This creates negative microfluidic structures on the microfabricated Si/glass device. The process then involves molding a rubber based mold on this microfabricated Si/glass device to form a positive mold. Hot embossing of the rubber mold on a plastic plaque forms the microfluidic structure identical to the initial Si/glass microfabricated device. In this process, the plastic plaque is heated and pressed onto the positive rubber mold, causing the plaque to become malleable. This malleability makes the plastic of the plaque conforms to the pattern on the rubber mold, forming a negative structure in the plastic plaque identical to the negative structure of the initial Si/glass microfabricated device. The plastic plaques having the negative structure embossed thereon are finally drilled and bonded to another unprocessed plastic plaque to form closed fluidic structures.
For the embossing and bonding, plastic materials such as Polyethelene, Polypropylene, Poly(Urethane-Imide), poly(tetrafluoroethylene), polycarbonate, polyimides, Cyclic Olefin Copolymer (COC) and Cyclic Olefin Polymer (COP), poly(methyl methacrylate), polyacrylamide, polystyrene, or other such materials, can be utilized depending on the customization that the particular application demands.
The above process of hot embossing to manufacture plastic microfluidic chips enables production of low cost devices suitable for disposable use. Furthermore, since plastic manufacturing is generally scalable in a non-linear cost ratio, it is also possible to greatly reduce the cost of production by batch processing these microfluidic devices. The manufactured plastic microfluidic chips can be used to perform biological assays as described below.
Referring to
This integrated process involves lysis of cells, magnetic bead binding to nucleic acid, resuspension/elusion of nucleic acid bound beads, amplification of the extracted nucleic acid and detection of the amplified nucleic acid. During the extraction process, the sample is incubated and washed to produce extracted DNA in an extraction chamber 104. In amplification, which occur in a amplification module 27, extracted DNA is loaded into an amplification chamber 108 along with amplification master mix. The DNA and the amplification master mix are sealed in the amplification chamber 108, which is heated and cooled according to an appropriate thermal protocol. Once the protocol is complete, the amplified sample is transferred to a sample well 120 for subsequent separation and detection. Sieving matrix/gel, buffer, and optionally molecular size standards are loaded into the appropriate CE wells and buffer wells (wells 114, 116, 118, and 120), and a first electric field is applied, causing the sample to enter a detection (CE) channel 112. Applying a second electric field to the detection channel 112 causes the sample to separate into species that propagate past a detection area, where fluorescent tags attached to the species can be stimulated and detected. Extraction, amplification, and detection are described in greater detail below.
It will be appreciated that a similar extraction module to that discussed below in the present section may be used for protein extraction, with appropriate modification of the below-described nucleic acids techniques for use with protein extraction.
The nucleic acid extraction method incorporated in this integrated chip utilizes magnetic beads, wherein nucleic acid from chemically lysed cells are captured by the magnetic beads. Magnetic beads can be coated with any suitable ligand that would bind to the target being isolated. Examples of the coatings include streptavidin (for use with biotinylated targets), antibodies against the desired target, protein A, protein G, oligo-dT (for use with mRNA).
These beads can be retained within the chamber for optional subsequent amplification directly from the beads with the DNA attached or by eluting the DNA from the beads prior to amplification. To implement the extraction assay, initially a combination of lysis buffer and the streptavidin coated magnetic beads (available from, e.g., Dynal Direct®, available from Invitrogen, or prepared by the end-user according to protocols well known in the art) are mixed with the cell sample and the extraction process performed as per the protocol described below. The components and specification of buffers and beads used in the extraction protocol are also detailed in the following protocol.
An exemplary protocol for the extraction procedure for use with compact integrated chips, including the chip 20 shown in
Next, the magnetic beads/lysis solution is loaded into the extraction chamber, which contains the earlier dispensed cell sample, via the wells 100. Dispensing the bead solution into the extraction chamber causes mixing of the cells with the bead solution during flow.
As used herein, the term “lysis buffer” refers to any buffer that is used for the purpose of lysing cells for use in experiments that analyze the compounds of the cells. Typically, a lysis buffer includes a detergent that causes cell membrane to break up. Examples of such detergents include Triton X-100, NP40 or Tween-20. Other components of a lysis buffer can include protease inhibitors, DNAses; magnesium salts, lysozime, disulfide reducing agents such as 8-mercaptoethanol, ion chelating agents such as EDTA, and preservatives such as soidium azide. One of ordinary skill in the art will appreciate that the specific buffer used is determined based on the starting material and the target being analyzed.
Once the extraction chambers 104 are filled, the magnetic bead loading is stopped. The filled extraction chamber is incubated at room temperature for a few minutes to permit binding of the target, e.g. DNA, to the ligands coated onto the magnetic beads.
In some embodiments, upon completion of the incubation, a magnet is placed (or engaged, if an electromagnet is used) under the extraction chamber 104 of chip 20 (
In some embodiments, with the magnet still engaged, the crude extract is washed from the extraction chamber. The washing solution is loaded into the same well on-chip as the earlier loadings. Examples of a washing solution include Tris/EDTA (TE) buffer, a phosphate buffer (NaH2PO4, NaCl, pH 8), or other standard washing buffers well known in the art.
In some embodiments, the washing step can be repeated for a number of times sufficient to ensure that the target being purified (e.g. DNA) is free of the lysis solution and cell debris. Those skilled in the art will be able to readily ascertain the number of washing cycles needed to achieve this. The trapped target molecules (e.g., DNA) can now be eluted off into the extraction chamber 104 by using standard elution buffers, as is well known in the art.
The solution flowing through the extraction chamber 104 will be removed through the reagent inlet/outlet port 106 on the other end of the extraction chamber by a pipette, syringe, a pump, or any other suitable means. This waste solution is periodically removed through reagent inlet/outlet port 106.
DNA/RNA amplifications may be performed in a few different ways. One method involves adding the magnetic beads, which are not known to inhibit amplification, with the DNA/RNA attached to the beads, directly to the amplification master mix. In other embodiments, DNA/RNA detection can be made directly without amplification, for example by directly reading the nucleic acid sequence.
As used herein, the term “master mix” refers to a solution that contains a polymerase (e.g., Taq DNA Polymerase, reverse transcriptase), magnesium chloride and a mix of deoxyribonucleotide (dNTPs) in a reaction buffer (e.g. an aqueous solution of (NH4)2SO4, TrisHCl, Tween-20, pH 8.8). Those of skill in the art will appreciate that a specific master mix is selected based on the target being amplified, test condition and the preferred polymerase.
The second method involves eluting the DNA or RNA from beads, followed by re-suspending the DNA in any standard buffer known in the art that does not inhibit amplification.
If beads with the nucleic acids attached are used directly in the amplification, then the master mix is loaded into the amplification chamber 108. The magnet below the extraction chamber 104 is then disengaged, allowing the magnetic beads to float freely in the extraction chamber. To prevent the magnetic beads (and the DNA attached to the beads) from flowing out of the extraction chamber 104, the ports 106 and wells 120 on either side of the extraction chamber 104 are sealed. For example, the reagent inlet/outlet ports 106 and wells 120 can be sealed with plug valves or the channels 102 connecting the inlet/outlet ports 106 and wells 120 to the extraction chamber 104 can be sealed using elastic or ferrofluidic valves. Thus the beads can move freely within the extraction chamber 104 but are prevented from exiting the extraction chamber 104. The extraction is complete and the chip is ready to be subjected to amplification.
Otherwise, if beads with DNA attached are not used, the extraction chamber is flushed with a re-suspension buffer. The re-suspension buffer is loaded into the extraction chamber 104 until it completely refills the extraction chamber 104, displacing and unloading the washing buffer from the extraction chamber 104. Then the magnet below the extraction chamber 104 is disengaged and the wells 100 and reagent inlet/outlet ports 106 are sealed using appropriate valving.
Next, the chip is heated to 50-90° C. (e.g., 70° C.) on a Peltier device or other appropriate source of heat typically used as a means to control or adjust the temperature, such as a temperature control method for amplification. This causes the elution of DNA from the magnetic beads.
After heating, the valves blocking fluid transport from the extraction chambers 104 to the amplification chambers 108 through the transport channels 102 are open. Finally, the extracted DNA/RNA/protein is flushed from the extraction chamber 104 into amplification chamber 108.
The DNA/RNA/protein extraction process is complete, and the extracted DNA, whether attached to the magnetic beads or not, is ready for on-chip amplification as detailed below. Depending on the volume of DNA/RNA solution required for amplification or detection (i.e., concentration of DNA), a portion of the eluted DNA/RNA can be unloaded from the extraction chamber and the amplification master mix added.
In accordance with embodiments of the invention, as discussed elsewhere herein, an amplification module may be isothermal or may be thermal. Likewise, in accordance with other embodiments of the invention, as discussed elsewhere herein, an amplification module may be replaced by only one cycle of amplification or DNA/RNA replication or DNA/RNA sequencing and this process may be isothermal or may be thermal. In another embodiment, no amplification is performed.
In one embodiment, the extracted DNA/RNA from the extraction module and an amplification master mix are mixed in the amplification module 108. The amplification master mix contains (apart from other standard reagents detailed later) a set of sequence specific forward and reverse primers to amplify a genetic sequence of interest (typically a unique characteristic of the species) in the extracted DNA/RNA.
In some embodiments, once the desired quantity of amplification master mix is loaded in the amplification chamber 108, thermal cycling is performed at the desired DNA denaturation temperature (70-100° C.) and primer annealing temperatures (40-70° C.).
In some embodiments, the amplification is achieved by placing the integrated chip with a means of precise temperature control and for example a programmed temperature cycling protocol. (See, for example, the protocol for amplification of a 700 bp DNA fragment characteristic of the E. coli DH10B cells described in Exemplification section.) A skilled person can readily ascertain the number of cycles based upon the starting concentration of the sample and the desired concentration of the final amplification product.
In other embodiments, the amplification is achieved by placing the integrated chip with a means of precision control of the DNA or RNA molecules and for example a programmed tension cycling protocol.
In one embodiment, the amplification is performed using the hardware module described in details below.
In certain embodiments, one of ordinary skill in the art will add 10° C. to the above temperatures and add an additional minute to each incubation time.
The completion of the thermal or tension cycling results in the amplification of DNA/RNA sequence as designed in the primers, ready for analysis using the method described subsequently.
In certain embodiments, upon completion of the amplification/replication of a specific DNA sequence, the replicated/amplified DNA molecules are subjected to size separation and then fluorescence detection in the separation module 29 of the chip 20, shown in
Referring again to
Those skilled in the art will also appreciate that different gel media can be used for electrophoresis separation. For example, polyacrylamide or agarose gel (e.g., varying concentrations 0.1% to 20%) may be used for DNA and RNA separation. Sodium dodecyl sulfate (SDS) polyacrylamide gel or agarose gel may be used for protein separation. In protein analysis, low acrylamide concentrations can be used to separate high molecular weight proteins (e.g., 5% for 40-200 kDa), while high acrylamide concentrations can be used to separate proteins of low molecular weight (e.g., 15% for 10-40 kDa). Similarly, low agarose concentrations can be used for separating high molecular weight nucleic acid (e.g., 0.5% for 1-30 kbp) and high agarose concentrations to separate low molecular weight nucleic acid (e.g., 1.5% for 0.1-2 kbp).
Examples of a buffer suitable for use in capillary electrophoresis include the Tris/Borate/EDTA (TBE) buffer (e.g. for nucleic acids being separated on an agarose matrix), Tris/glycine/SDS (e.g., for proteins being separated on a polyacrylamide gel). A skilled person will appreciate that the choice of a running buffer will depend on the target being analyzed.
Alternatively, if size standards are also to be used to verify the size of the amplification product, the size standards (e.g., Gene Scan TAMRA orr ABI) can be added to the amplification product and the running buffer loaded atop. The running buffer and the amplified DNA can be mixed to form a homogenous suspension within the well 120. In this case, to enable fluorescence detection of the DNA, primers labeled with a fluorophore similar to the size standards (e.g., VIC, ABI) will result in the labeling of the amplified DNA, as can be expected by the amplification process.
Any molecular weight standards suitable for nucleic acid separation can be used. Examples include GelPilot® molecular weight marker, available from QiaGen, and a Molecular Weight Ladder available from New England Biolabs.
Fluorescently labeled nucleic acid primers are commercially available (e.g. from Sigma-Aldrich) or can be synthesized by one of ordinary skill according to known protocols. (See, for example, Prudnikov et. al. Nucleic Acids Res. 1996 Nov. 15; 24(22): 4535-4542, or the protocol available online at the URL http://info.med.yale.edu/genetics/ward/tavi/n_label.html. The entire teachings of both of these publications are incorporated herein by reference.) Examples of fluorescent labels include fluorescein, 6-Carboxyfluorescein, 5′-tetrachloro-fluorescein, Texas Red (sulforhodamine 101 acid chloride), quantum dots, and fluorescently tagged nanoparticles.
The application of the strong electric field 131 causes the separation of DNA molecules based on molecule size. Further down the detection channels 112 from the initial positioning of the DNA in the CE channel 112 (for example, 75 mm from the point where the DNA 23 was trapped in the path between the buffer well 116 and buffer waste well 114), fluorescence can be stimulated by suitably illuminating separated species 140 with a laser source or LED or other light source with a wavelength matched with the excitation wavelength of the fluorophore attached to the species 140. The skilled person can readily ascertain the appropriate wavelength to be used based upon the fluorophore selected.
As is described below with reference to
The separation module 29 of the chip 20 (
In any embodiment described herein, the length of the detection channel 112 can be adjusted from a few centimeters to many meters to accommodate separation of a many number of independent molecules. This improves the ability to resolve separated molecules.
Similarly, the applied electric fields (e.g., electric field 130 and strong electric field 131) can be changed from millivolts to many thousands of volts to attain the desired level of fragment (DNA/RNA/proteins) separation. This also improves the ability to resolve separated molecules. The skilled person will be able to ascertain the electric field to be applied based upon length of detection channels 112 (
Those skilled in the art will also appreciate that different gel media can be used for electrophoresis separation. For example, polyacrylamide or agarose gel (e.g., varying concentrations 0.1% to 20%) may be used for DNA and RNA separation. Sodium dodecyl sulfate (SDS) polyacrylamide gel or agarose gel may be used for protein separation. In protein analysis, low acrylamide concentrations can be used to separate high molecular weight proteins (e.g., 5% for 40-200 kDa), while high acrylamide concentrations can be used to separate proteins of low molecular weight (e.g., 15% for 10-40 kDa). Similarly, low agarose concentrations can be used for separating high molecular weight nucleic acid (e.g., 0.5% for 1-30 kbp) and high agarose concentrations to separate low molecular weight nucleic acid (e.g., 1.5% for 0.1-2 kbp).
In addition, non-optical detection strategies, such as electrochemical detection strategies, may be used, alleviating the need to fluorescently label the molecules to be detected by separation.
In an example embodiment, different integrated chips can be prepared for analyzing different pathogens, diseases, and biological samples.
End-users of the integrated chip described herein can deploy the chip and the hardware system (described below) at the respective locations to analyze a variety of biological samples, as described above with reference to
Referring to
In other embodiments, the integrated chip of the present invention can include at least two electrodes for applying voltage across the at least one detection channel 112. In other embodiments, the integrated chip can include at least one flow control valve for controlling fluid flow through the at least microfluidic channel. The valves can be passive plugs or can be any of the valving system described in details below.
An embodiment according to the present invention exploits nanomanipulation and precision control of molecules at the nanoscale. By precision controlling molecules or fluidic systems with ultra high precision, an embodiment according to the invention can dramatically improve the overall quality produced by the chemical and biochemical reactions conducted under highly controlled and tunable conditions on nano-engineered chips or precision engineered chips. Therefore, by exploiting nanotechnology an embodiment according to the invention can improve not only on at least one step of the integrated process, but can also dramatically improve the overall signal to noise ratio, increasing the ability to detect trace amounts of biological targets such as pathogenic nucleic acids, biomarker sequences or proteins in a fluid sample. The precision control elements in nano-engineered chips according to an embodiment of the invention, and in a platform device according to an embodiment of the invention, tighten the overall Gaussian spread in the products produced by on-chip reactions, enabling orders of magnitude improvement across several critical performance metrics, including rapidity, accuracy, deployability, adaptability, and robustness.
An embodiment according to the invention permits precision or nanoscale control of nucleic acids and proteins. A nanoscale or precision reactor permits an unanticipated improvement in time, cost, speed and infrastructure required to perform analysis of biological samples as compared with conventional, larger scale systems. For example, tension can be applied to a nucleic acid such as by an electromagnetic field exerted in a reaction chamber, which can cause a nucleic acid, such as a 2 nm wide DNA molecule, to stretch in a given direction. This speeds up the tendency of a reaction to occur, for example by opening the DNA. Thus, small scale control of the molecule is realized. Control on such a small scale permits the achievement of a greater signal to noise ratio, an improved yield and reduces the time for equilibration in a reaction chamber. Various forces may be used to control at the nanoscale, for example mechanical, electromagnetic forces and/or hydrodynamic forces, and using types of tension taught in U.S. Pat. No. 7,494,791, the entire disclosure of which is incorporated herein by reference.
As used herein, the term “precision control” of a parameter refers to the ability to control the parameter such that repeated measurements of the parameter under unchanged conditions show the same results, to within the degree of precision, and further refers to the ability to adjust the parameter to a new value of the parameter, with such a degree of precision. For example, in accordance with an embodiment of the invention, a parameter that governs at least one step of a reaction used to analyze a biological sample may be precision controlled to within a degree of plus or minus 10%, plus or minus 1%, plus or minus 0.1%, plus or minus 0.01%, plus or minus 0.001% or plus or minus 0.0001%, and may be adjustable to a new value of the parameter, with such a degree of precision. Such precision control can be performed in many ways, including for example by using controlled fluid flow or by applying tension, including both for proteins and nucleic acids.
As used herein, applying tension to a nucleic acid or protein includes direct and indirect application of force to a nucleic acid or protein that tends to stretch or elongate the nucleic acid or protein. As examples, tension can be applied to a nucleic acid or protein by direct application of mechanical tension, by hydrodynamic stresses in a fluid flow, or electromagnetic fields, whether acting on the nucleic acid or protein molecules themselves and/or on surfaces, substrates, or particles and the like that are bound to the nucleic acid or protein.
In accordance with an embodiment of the invention, tension that tends to stretch a nucleic acid may be applied in at least one cycle. Further, tension that tends to stretch the nucleic acid may be applied and optionally varied during each cycle of the following steps (a)-(e) in a nucleic acid amplification method:
In addition, at least one cycle of steps (b) or (d) comprises applying tension that tends to stretch the nucleic acid to the one or more template strands. In some versions, the process can be performed isothermally.
In accordance with an embodiment of the invention, precision control may be achieved using, for example, hydrodynamic focusing, such as that taught in Wong et al., “Deformation of DNA molecules by hydrodynamic focusing,” J. Fluid Mech., 2003, vol. 497, pp. 55-65, Cambridge University Press; and/or using mechanical force, such as using techniques taught by Liphardt et al., “Reversible Unfolding of Single RNA Molecules by Mechanical Force,” Science, 2001, vol. 292, pp. 733-737, American Society for the Advancement of Science; the entire teachings of both of which references are hereby incorporated herein by reference. Other techniques may be used.
The level of precision control may be on the scale of nanometers, given that, for example, DNA is 2 nm in diameter and proteins may be 10 nm in diameter. In accordance with an embodiment of the invention, control of the translational position or rotational orientation of a molecule may be achieved to within less than 100 nm, less than 10 nm, or less than 1 nm. In addition, the reaction chambers themselves may be on a small scale, such as less than 10 mm, less than 1 mm, less than 100 microns, less than 10 microns, less than 1 micron, less than 100 nm, less than 10 nm or less than 1 nm in largest dimension. Further, the temperature, pressure, diffusion rate, tension, chemical concentration, salt concentration, enzyme concentration or other parameters that modulate or govern the reaction may be varied within a tightly controlled range, for example by plus or minus 10%, plus or minus 1%, plus or minus 0.1%, plus or minus 0.01%, plus or minus 0.001% or plus or minus 0.0001%.
As used herein, where a system is “configured” to perform precision control of a parameter, such precision control of parameters may be performed, for example, using one or more software or hardware modules implemented under the control of a computer processor in a mobile device according to an embodiment of the invention. The computer processor may include one or more control modules, which receive digitally encoded signals corresponding to values of one or more parameters to be controlled, and which are specially programmed to perform closed loop control of those parameters to be controlled. For instance, the control module may receive a value of the parameter, and, based on the value of the parameter, may adjust one or more forces or other conditions applied to a molecule being analyzed (for example using application of tension). As a result of the adjustments implemented by the control module, the parameter will then change, and a closed feedback loop may therefore be formed under which the control module performs closed loop control of the one or more parameters to be controlled. In addition to receiving digitally encoded signals from one or more other computer modules, the control module may also receive one or more sensor inputs from one or more sensors, which sense values of parameters to be controlled; for example a temperature or pressure sensor may provide a temperature or pressure sensor input to the control module.
As described above, the compact integrated chip with biological assay is intended to be disposable. The instant invention also includes a hardware system that comprises mechanical, electrical and electronic devices, as well computer-readable instructions for controlling these devices. A skilled person will appreciate that such hardware system can be configured to accommodate various designs of chips utilizing the above biological processing modules (e.g., nucleic acid extraction, thermal or isothermal amplification, laser-based fluorescence detection, and CE separation).
Referring to
The microprocessor/computer interface 408 means may comprise, for example, an appropriate computer such as any taught herein, and conventional computer components such as any taught herein; and may comprise RAM storing an operating such as any taught herein and appropriate software for processing signals pertaining to detected nucleic acids.
Referring again to
In
A laser source 602 with the desired wavelength and a suitable filter arrangement (not shown) illuminates a selected portion of the chip 20 via a lens 606. The illumination excites fluorophores attached to the DNA or proteins, causing the flurophores to emit radiation (not shown) at a wavelength other than the laser wavelength. Filters block the laser light and transmit the emitted radiation, which is collected with a lens 607. The lens 607 focuses the filtered radiation onto a detector 608, such as a photomultiplier tube, avalanche photodiode, charge-coupled device, or other suitable detector. The detector emits a signal, such as a photocurrent, that is amplified (and filtered, if necessary) by a signal amplifier circuit 610. A computer 408 records and processes the amplified signal; the computer 408 may also be used to control the high-voltage supply 620 and laser 602 with a software interface as described below. Those skilled in the art will appreciate that alternative arrangements of optical components may be used to interrogate the fluorescent markers attached to the DNA.
A cover 754 can be positioned with a hinge or other suitable mechanism over the chip held in the recess 758 of the holder 752. Positioning the cover 754 over the chip causes electrodes 776 to be inserted into appropriate wells of the chip (e.g., CE wells 114, 116, 118, and 120 of chip 20 in
The hardware system 400 also includes a detection system similar to the one shown in
Some embodiments of the present invention include a software module configured to control each of the three biological hardware modules (that is, the extraction control module 402, the amplification control module 404, and the detection control module 406 of the hardware system 400, shown in
The GUI allows a user to control the extraction module through user input or pre-programmed initiation of the magnetic field. In some embodiment, the magnetic field can be applied discontinuously for specified time intervals, as specified by the protocol described above. The GUI also allows the user to specify the temperature application for specified periods of time.
The GUI allows the user to set user-specified temperatures (typically 3 different temperatures, as specified earlier) and resident time intervals for each temperature. The user can also specify the desired number of thermal cycles, repeating the above input temperatures and time parameters. The GUI enables the user to set microprocessor/computer data acquisition of chip/sample temperature from the hardware setup; the resulting data can be displayed in a real-time temperature versus time graph.
In addition, the GUI gives the user the ability to: (1) choose and energize any pair of electrodes to configure for application of high-voltage signals; (2) specify in sequence the above selection for a given time interval, as desired by the user; (3) obtain feedback monitoring of the applied voltage across any of the energized pair of electrodes and graphically represent this data as a function of time; (4) obtain feedback monitoring of current from any of the energized pair of electrodes and graphically represent this data as a function of time; (5) graphically represent the acquired fluorescence signal as a function of time; and (6) identify/distinguish a fluorescence signal (peak/intensity) from size standard signals. These features can be used to confirm the amplification to identify the presence (or absence) of a sequence in the DNA.
The hardware system and the computer-readable instructions of the present invention can also facilitate comparison of data obtained by analyzing the biological sample using the integrated chip described herein to a genomic database that stores a plurality of genomic profiles.
Microfluidic valves and pumps are typically utilized in a chip, such as chip 20 of
For example, and referring to
In other embodiments, various valving systems can be used. Such systems are described elsewhere herein, for example with reference to
Still other embodiments of the integrated microfluidic chip include a valve technology termed “elastic valves,” examples of which are shown in
In another configuration of operation, the above-described elastic valves can be embedded in the chip, rather than inserted or operated with an external interface, to achieve higher levels of automation. An example of such a configuration would involve a fabrication process where the elastic membranes are sandwiched between the two layers of the chip along any channel that requires flow control. The inlet air tube that is utilized to actuate the elastic membrane valve is also embedded in the chip and brought to the periphery of the chip for external air pressure line connection. Both the embedded and external valving and pumping systems can effectively be used to valve/pump volumes ranging from nanoliters to many milliliters.
As shown in
In an embodiment according to the invention, there is provided a portable system for extracting, optionally amplifying, and detecting nucleic acids using a compact integrated chip in combination with a portable system for analyzing detected signals, and comparing and distributing the results via a wireless network. A portable, chip-based diagnostic device may be used for the rapid and accurate detection of DNA/RNA signatures in biological samples. The portable device may be used as a platform for personalized and mobilized nanomedicine or companion diagnostics and as a tool to improve efficacy, decrease toxicity, and help accelerate clinical trials and regulatory approvals on novel drugs.
In one embodiment, a system may be used in a method for conducting personalized medicine. In a broad sense, personalized medicine uses genetics to provide the right patient with the right drug at the right dose for the right outcome. In an embodiment according to the invention, a portable assay system is used to extract, amplify, and detect nucleic acids in the sample, and in particular to detect personalized biomarkers based on the nucleic acids. The system may then determine an appropriate dosage and/or drug combination for delivery of customized medicine based on the detected personalized biomarkers. A targeted drug and companion diagnostic may be provided. In addition, the system may be used to determine if a person is a responder to a drug therapy. The system can also be used to help stratify patients to enhance drug safety and efficacy, and can help optimize dosing and therapeutic regimens. Further, the system may be used for monitoring a person, for example by monitoring levels of a nucleic acid found in biosamples from the person taken at different times. Such monitoring may be used, for example, to track the progress of a treatment in a patient, or for monitoring a disease in the person. For example, diabetes and other chronic diseases may be diagnosed, classified or monitored via DNA/RNA markers, for example, such as inflammation markers. For example, determining a personalized genomic profile can include detecting nucleic acids indicative of a type or subtype of diabetes.
In another embodiment, a portable system according to an embodiment of the invention may be used to assist in making regulatory clinical trials smaller and less costly, by enriching study populations. Personalizing trials with subset genetic populations can dramatically enhance therapeutic effect, and shorten the approval process. The resulting drug and companion diagnostic combination have a premium value for the target genetic population.
In another embodiment, a portable system according to the invention may be used for providing personalized care, for example in the fields of cosmetics, cosmeceuticals and in skin care applications. For example, a portable assay system may be used to extract, amplify, and detect nucleic acids in the sample; and in particular to detect personalized biomarkers based on the nucleic acids. The system may then determine a type, amount or combination of a personal care product to deliver based on the personalized biomarkers. For example, the system may be used for the selection and delivery of cosmetics based on personalized cosmetic biomarkers. In one example, a skin type is determined based on personalized biomarkers, which may then be used to determine a type, amount or combination of cosmetic products to deliver to a person. A mobile device may be used to measure and quantify, in real time, the presence of key biomarkers (which could, for example, be DNA or RNA based). Sequence biomarkers (e.g., beauty biomarkers such as age related locus, certain aging genes or gene expression patterns, skin quality) can be measured against skin products. A portable system according to an embodiment of the invention can be used to correlate the genotype of individuals with such sequence biomarkers. An integrated chip can be customized to go along with a library of target genes for beauty biometrics. An individual's beauty biometrics can be measured by quantifying the individual's beauty biomarkers in real time via a portable system according to an embodiment of the invention. It can then be seen how these biomarkers change over time with the use of corresponding cosmetic products. Embodiments may also be used for wellness applications, for nutrigenomics, and for ayurvedic genomics, for example performing ayurvedic diagnosis via genes corresponding to the vata, kapha and pitta body type.
In another embodiment, a portable system according to the invention may be used in which the detection capabilities of an integrated chip are coupled with specific, uniquely determined pharmaceutical products. For example, a portable assay system may be used to extract, amplify, and detect nucleic acids in the sample; and in particular to detect personalized biomarkers based on the nucleic acids, where the personalized biomarkers may indicate the presence of a specific strain of a disease or pathogen. The system may then uniquely determine a customized dosage and/or drug combination to deliver based on the specific strain biomarkers. In one example, drug dosages and/or combinations to deliver may be determined for specific strains of human immunodeficiency virus (HIV). A portable system according to the invention may be used for point-of-care detection of HIV strains, HIV viral load determination, and HIV genotyping or as drug monitoring devices or tools to monitor and prevent mother to child transmission of HIV.
More generally, an embodiment according to the invention may be used to genotype any organism, thereby determining at least one of: predisposition to a genetic disease, a strain of a disease, and antibiotic resistance of a disease condition. For example, a type of viral hepatitis may be determined; or a cancer gene may be identified.
In various embodiments, a portable system according to the invention may be used in a variety of different possible industries. For example, a portable assay system may be used to extract, amplify, and detect nucleic acids in the sample. The detected nucleic acids may then be used in any of a variety of different possible industries (in addition to industries discussed elsewhere herein). For example, the detected nucleic acids may relate to food safety, agricultural diseases, veterinary applications, archaeology, forensics, nutrition, nutriceuticals, nutrigenomics, water testing/sanitation, food and beverages, environmental monitoring, customs, security, defense, biofuels, sports and wellness; and may be used for theragnosis.
A system according to an embodiment of the invention may be used to determine a personalized genomic profile of a person who is the source of a biological sample. The personalized genomic profile can then be used to personalize a nutriceutical, a cosmeceutical, a pharmaceutical, a food or beverage, or nutrition for the person based on the personalized genomic profile. The personalized genomic profile can, for example, be used for personalized wellness, personalized sports nutrition, personalized diet or personalized nutrition for the person. In the field of sports, for example, inflammatory markers can be determined in order to detect, measure and treat an injury in an athlete, such as a traumatic brain injury for an athlete in a contact sport. In another embodiment, markers can be determined to evaluate blood doping in sports. In another embodiment, RNA markers can be measured for various kinds of phenotypic expression.
A system according to an embodiment of the invention can be used for personalized nutrition, in which a chip reader (such as a nucleic acid extraction control module, a nucleic acid amplification control module and a nucleic acid detection control module) and software is customized to help personalize food and beverages and nutrition based on a person's DNA/RNA profiles. In a broad sense, personalized nutrition involves using genetics to provide the right consumer with the right nutrition in real time for the right outcome. In an embodiment according to the invention, companion personalized nutritional additives can be provided to a person based on their DNA/RNA profile. Targeted nutrition and a companion diagnostic can be provided, and companion diagnostics for health and wellness biomarkers can be developed. A holistic and integrative approach to health and wellness can be provided. Consumers can be provided with feedback to measure their progress, not just by commonly accepted phenothypical markers, but also by DNA/RNA biomarkers that provide robust and credible measurements of progress. By determining a person's genetic profile, or their predisposition based on their DNA/RNA markers, the person's diet can be personalized. A personalized genomic profile can be used to determine a person's nutritional predisposition, such as a genetic food allergy, intolerance or sensitivity, for example gluten sensitivity, gluten intolerance or lactose intolerance, and to personalize a diet on the basis of that profile. Inflammatory markers can be measured as a way of monitoring whether a certain diet is tolerated or not. In addition, nutritional deficiencies can be detected, measured, and then addressed by adding micronutrients into a food or beverage. For example, vitamin deficiencies, mineral deficiencies and other deficiencies (such as Vitamin B12 deficiency, folate deficiency, iron deficiency) can be measured based on biomarkers measured by an embodiment according to the invention. The deficiency can then be addressed by providing appropriate micronutrient supplementation in a food or beverage. In addition, a probiotic or prebiotic that is deficient or altered in a person's microbiome may be determined. For example, a biological sample from a person's saliva, gut or urine can be obtained and analyzed to determine what probiotics or prebiotics in the person's microbiome are deficient or altered, such as in the person's oral microbiome or gut microbiome. The deficient probiotic or prebiotic can then be supplemented in the person's food or beverages, to help the person restore a normal microbiome.
In an embodiment according to the invention, personalized nutrition can be performed based on determining biomarkers of inflammation. Inflammation is implicated in a variety of conditions, including cancer, cardiovascular conditions, Alzheimer's Disease, pulmonary diseases, arthritis, autoimmune diseases, neurological diseases and diabetes. In an embodiment according to the invention, by determining a person's genetic profile, or their predisposition based on their DNA/RNA markers, the person's diet can be personalized. By way of example, selected cardiovascular inflammatory biomarkers that may be determined, measured and/or monitored in accordance with an embodiment of the invention are listed in
In another embodiment according to the invention, the consumer experience of a food or beverage can be augmented by dispensing a food or beverage based on a person's nutrigenomic profile. Systems taught herein may be embedded in the form factor of a dispensing activator, such as at least a portion of a vending machine, an automated teller machine, or a kiosk, which may be controlled based on control inputs from a system taught herein. For example, a person may provide a biological sample to a genetic analysis unit configured to determine biomarkers associated with the person. Based on the biomarkers, a personalized genomic profile of a person who is the source of the at least one biological sample can be determined. A dispensing control unit is then configured to determine a product, or a portion of a product, to dispense based on the personalized genomic profile. A dispensing activator is coupled to the dispensing control unit, and configured to dispense at least a portion of the product under control of the dispensing control unit. Using such a system, for example, a consumer could insert a biological sample, such as a saliva sample, into a vending machine, which would determine, based on the consumer's nutrigenomic profile, which food or drink was most suitable for the consumer. The dispensing activator can comprise a three dimensional printer configured to print at least a portion of the product, or the dispensing activator can be configured to dispense a prepackaged product. The product can, for example, be a food, a beverage, a cosmeceutical, a nutriceutical, a pharmaceutical, a herbal medicine, an alternative medicine and a cosmetic. The dispensing control unit can be configured to determine the product, or portion of a product, to dispense based on a nutritional predisposition, nutritional deficiency, and at least one probiotic or prebiotic that is deficient or altered in a microbiome, any of which may be determined by detecting nucleic acids based on embodiments taught herein. A three-dimensional printing machine can, for example, be used to print a consumer's food or beverage at a vending machine or kiosk, based on the consumer's genetic profile. Additional information may be input by the consumer using a user interface, such as a keyboard, touchpad, speech recognition interface, augmented reality interface, or other user interface. A consumer may, for example, be given some information regarding alternative ingredients that would be beneficial based on the consumer's profile, and is then enabled to choose one or more of the ingredients using the user interface, to custom build a food or drink. A system such as a vending machine can integrate point-of-use companion diagnostics and point-of-use production of nutrition-enhanced food or beverages, for example using three-dimensional printing of the food or beverages. Food, beverages, cosmeceuticals, nutraceuticals and cosmetics can be three dimensionally printed in this fashion. In cosmetics, for example, a customer at a kiosk at a cosmetics counter, can be provided with a customized profile using a system taught herein, and can then be enabled to print the customer's own cosmetics, such as a skin care solution. Similar systems may be provided for nutraceuticals, herbals, alternative medicines, herbal teas, food products and beverages. For example, spices or other ingredients such as turmeric, cinnamon, green tea or other anti-inflammatory ingredients can be provided in juices, in order to reduce a consumer's inflammation levels. Custom doses can be provided by a control system based on the customer's genetic profile, in the foregoing embodiments.
In another embodiment according to the invention, systems taught herein are used coupled with an Enhanced External Counter Pulsation (EECP) therapy machine. Levels of cardiac markers, inflammation markers and other markers associated with improvement in cardiac function are monitored in real time by nucleic acid analysis systems taught herein, and used to provide electronic control inputs to the EECP machine, for example to increase or decrease blood flow or titrate dosing. For example, inflammation factors, VEGF, endothelial autogrowth factors, other gene expression patterns, cardiac markers, DNA/RNA markers that are correlated with cardiac status, and so on, may be monitored by systems taught herein. By coupling nucleic acid analysis systems taught herein with an EECP therapy machine, there may be provided a tool that helps to reverse atherosclerosis with a combined effect produced by stimulating endothelial repair with flow and with the measurement of inflammatory factors. Biomarkers that are implicated in the atherosclerotic process can be monitored on multiple channels of a nucleic acid analysis system, simultaneously, and electronic control inputs provided to the EECP machine based on the levels of the biomarkers.
In various embodiments, results provided by a portable system according to the invention may include a viral load (e.g., in copies/ml), a predicted cell count per volume (e.g., a predicted CD4 count in cells/mm3), and a titration of drug dosing.
In further embodiments according to the invention, a portable system according to the invention may communicate with other systems in a variety of different possible ways. The portable system may transmit and receive modulated data signals pertaining to the biological sample, and may communicate via wired media (e.g., a wired network or direct-wired connection) or wireless media (e.g., acoustic, infrared, radio, microwave, spread-spectrum). The portable system may, for example, communicate via the World Wide Web, and/or a mobile network, and/or via text message (such as an SMS message). The portable system may connect to a remote genomic database that stores genomic profiles. The portable system may store, or transmit or receive, a signal profile of a single reference sample.
In further embodiments according to the invention, the portable system or mobile device may be implemented as part of, or interface with, any of a variety of different possible widely available handheld or tablet devices, such as a smartphone, Personal Digital Assistant (PDA), cellular phone, or other handheld or tablet device, employing an optionally disposable compact integrated chip. In addition, similar graphical user interfaces and external design may be used as are used on such widely available handheld or tablet devices. In one example, an embodiment according to the invention may be implemented in, or interface with, or use a similar graphical user interface or external interface to that of an iPhone, iPad, or iPod, all sold by Apple Inc. of Cupertino, California, U.S.A., or a Galaxy, sold by Samsung Electronics Co., Ltd. of Suwon, South Korea.
In an embodiment according to the invention, the portable system, or multiple such portable systems at dispersed locations, may be used to track the outbreak of disease at dispersed analysis sites. The portable system may connect through one or more networks (e.g., a Local Area Network, a Wide-Area Network, and/or the Internet); and may engage in a two-way exchange of information between a central data center and the system end-user. The data center can provide known pathogen/disease mapping information to the end-user/invention system for biological sample analysis, and subsequently the invention system/end-user can transmit assay results to the data center. The data center can receive geographic location information and other case identification information from the end-users/invention system. The data center can monitor incoming assay results from the plurality of deployed units/invention systems and employs pattern detection programs, for example to track the outbreak of a disease. The data center can programmatically generate notifications to remote portable systems according to the invention, upon detection of threshold patterns.
In various embodiments, the system of the present invention can be used to identify pathogens, diagnose disorders having a genetic marker, or genotype an individual. The methods of the present invention generally comprise (1) providing at least one integrated chip; (2) loading the at least one biological sample onto the at least one integrated chip; (3) operably connecting a portable control assembly with at least one integrated chip; and (4) activating the portable control assembly to effect extraction, amplification and detection of nucleic acid from the biological sample loaded onto said integrated chip.
The present invention can be used to diagnose and detect a wide variety of pathogens and disorders that have nucleic acid-based genetic material and/or genetic components. In addition to detection of such targets as HIV, HBV, HCV and sexually transmitted diseases, the system and method of the present invention can be used to detect and diagnose molecular diagnostic targets arising in the fields of oncology, cardiovascular, identity testing and prenatal screening.
Preferably, biological sample is derived from a biological fluid, such as but not limited to blood, saliva, semen, urine, amniotic fluid, cerebrospinal fluid, synovial fluid, vitreous fluid, gastric fluid, nasopharyngeal aspirate and/or lymph.
A biological sample can be a tissue sample, a water sample, an air sample, a food sample or a crop sample. Preferably, the biological sample analysis detects any one or more of water-born pathogen, air-born pathogen, food-born pathogen or crop-born pathogen.
The pathogen detectable by the system and method of the present invention can come from a variety of hosts. The host, whether biological or non-biological, should be capable of supporting replication of an infectious agent by allowing the infectious agent to replicate in or on the host. Examples of such hosts include liquid or solid in vitro culture media, cells or tissues of animals, plants or unicellular organisms, whole organisms including mammals such as humans.
The system and methods of the present invention can be employed in one of more of the following areas. In one embodiment, the system and method of the present invention can be employed in the area of defense against biological weapons. For example, the present invention can be used for point-of-incidence and real-time pathogen-detection. In another embodiment, the system and method of the present invention can be employed in the area of life sciences. For example, the present invention can be used as and with a portable analytical instrument. In another embodiment, the system and method of the present invention can be employed in the area of clinical diagnostics. For example, the present invention can be used to diagnose and/or identify pathogens by doctors, nurses or untrained users in hospitals, homes or in the field. The present invention can also be used for genotyping an organism, thereby determining predisposition to genetic diseases, if any, or antibiotic resistance, if any. The present invention can also be used to determine pathogens present in a patient and the sensitivity and resistance profiles of those pathogens to various antibiotics. The present invention can also be used as a drug monitoring device, a prognostic indicator of disease, and a theragnostic device. In another embodiment, the system and method of the present invention can be employed in the area of industrial and agricultural monitoring. For example, the present invention can be used to monitor and/or detect pathogens born by food, crops, livestock, and the like. In another embodiment, the system and method of the present invention can be employed in the area of forensics. For example, the present invention can be used to genetically identify an individual.
In one embodiment, genetic disorders and disorders having a genetic component can be diagnosed by employing the system and method of the present invention. For example, numerous oncogenes have been identified, including p53, implicated in the development of breast, colorectal and other cancers; c-erbB2, associated with breast cancer development and metastasis; and BRCA1, involved in 50% of all inherited breast cancers, and also associated with increased risk for prostate and other cancers. Screening for the these genetic markers can be accomplished using the system and methods described herein.
Infectious agents which can be diagnosed using the system and method of the present invention include, but are not limited to, bacteria, viruses, fungi, actinomycetes, and parasites. Examples include, but are not limited to, Escherichia, Shigella, Salmonella, Arizona (salmonella subgenus III), Citrobacter, Klebsiella, Enterogacter, Serratia, Proteus, Providentia, Morganella; Vibrio and Campylobacter; Brucella such as undulant fever; Yersinia; Pasteurella; Francisella; Actinocacillosis; Haemophilus, Bordetella (e.g. Bordetella pertussis); Pseudomonas and Legionella; Bacteroides, Fusobacterium, Streptobacillus and Calymmatobacterium; Bacillus (spore forming aerobes); Clostridium (spore-forming anaerobes); Listeria and Erysipelothrix; Corynebacterium; Mycobacterium; Spirochetes; Rickettsias; Chlamydia; Mycoplasmas; Poxviruses; Herpesviruses; Papovaviruses; Adenoviruses; Orthomyxoviruses, Paramyxoviruses; Rhabdoviruses; Cytomegalovirus; Retroviruses; Picornaviruses; Cornaviruses; Rotaviruses; Hepatitis viruses (e.g., hepatitis C virus, hepatitis B virus); Togaviruses; Bunyaviruses; Arenaviruses; Cryptococcus; Candida (e.g., Candida albicans, Candida glabrata, Candida parapsilosis, Candida tropicalis); Sporothrux; Ilestoplasma; Coccidioides; Blastomyces; Aspergilli; Zygomycetes; Dematiaceae; Fusarium; Protozoa; Nemathelminthes; and Platyhelminthes.
In other embodiments, retroviruses such as HIV-1, HIV-2, any of HIV-1 Groups M, N, O or P, any of HIV-1 Group M subtypes A-K, or any other known type or subtype of HIV, HTLV-1 and HTLV-2 and herpesviruses such as HSV-1, HSV-2, VZV, EBV, CMV, and HHV-6 can be detected using the system and methods of the present invention.
In other embodiments, the disorders and diseases that can be detected using the system and methods of the present invention include: Borellia, human T-cell lymphoma/leukemia virus-I, human T-cell lymphoma/leukemia virus-II, human immunodeficiency virus, influenza virus, parainfluenza virus, adenoviruses, HSV, VZV, HPV (generic, 6, 11, 16, 18, 31, 33), Moraxella catarrhalis, Streptococcus pneumonia, Haemophilus influenza, Legionella spp.; human parvovirus B19, Group B streptococcus.
In other embodiments, the disorders and diseases that can be detected using the system and methods of the present invention include genetic disorders and disorders for which there is a genetic predisposition. Example include, but are not limited to, Cystic fibrosis, Gaucher disease, Medium chain acyl dehydrogenase deficiency, Myotonic dystrophy, Sodium channelopathies, Chloride channelopathies, Duchenne/Becker muscular dystrophy.
In certain embodiments, the following pathogens can be diagnosed: a Human Immunodeficiency Virus, a TB bacterium, Hepatitis C Virus, SARS virus, Chlamydia trachomatis, Cytomegalovirus, Gardnerella vaginalis, Group A Streptococcus, Group B Streptococcus, Human Papilloma Virus, Neisseria gonorrhoeae, Trichomonas vaginalis, Bordetella pertussis, and E. coli.
In one embodiment, the infectious agent being detected is methicillin-resistant S. aureus (MRSA). Staphylococcus aureus represents one of the most significant pathogens causing nosocomial and community-acquired infections. Beta-lactam antibiotics are the preferred drugs for serious S. aureus infections. Since the introduction of methicillin into clinical use in 1961, the occurrence of methicillin-resistant S. aureus (MRSA) strains has increased steadily, and nosocomial infections have become a serious problem worldwide. Therefore, the detection of methicillin resistance has important implications for therapy and management of patients. In the clinical laboratory, S. aureus is identified by growth characteristics and the subsequent detection of catalase and coagulase activities or specific surface constituents. The DNase and thermostable endonuclease tests have been used as confirmatory tests for inconclusive or negative coagulase tests. Conventional susceptibility testing of S. aureus reliably detects resistance to methicillin or oxacillin if agar dilution or agar screening methods are used according to NCCLS standards. Methicillin resistance is associated with the production of a penicillin-binding protein, encoded by the mecA gene, or, in rare cases, with the hyperproduction of beta-lactamase.
Conventional methods of detecting MRSA employ broth- and agar-based antimicrobial susceptibility testing and provide a phenotypic profile of the response of a given microbe to an array of agents. These methods are slow and fraught with problems, such as false positives and false-negatives are common. These failings are due to the expression of the resistance genes in staphylococci, which may be expressed in a very heterogeneous fashion, making phenotypic characterization of resistance difficult. Molecular methods, targeting detection of the resistance gene, mec A, may be used. Screening for mutations in an amplified product may be facilitated by the use of high-density probe arrays such as the Affimetrix® Genechips™ that can be employed in the practice of the present invention.
Similarly detecting drug-resistance by detecting specific antimicrobial-drug resistance genes (resistance genotyping) can be accomplished in many organisms. Examples are listed in the following Table 1:
Enterobacteriaceae
Haemophilus influenzae
Neisseria gonorrhoeae
Enterobacteriaceae and
Mycobacterium
tuberuclosis
In other embodiments, the viral and microbial diseases that can be detected by employing the system and method of the present invention are those listed in Table 2:
Ehrlichia
Bordetella pertussis
Legionella pneumophila
Chlamydia pneumoniae
Mycoplasma pneumoniae
Helicobacter pylori
In further embodiments, the infectious diseases listed in Table 3 can be tested by employing the system and method of the present invention:
Chlamydia trachomatis detection
Neisseria gonorrhoeae detection
C. trachomatis/N. gonorrhoeae
Mycobacterium tuberculosis detection
Gardnerella, T. vaginalis, and Candida
Given the above features and advantages of the present invention, many advances in health care (and other industries), especially across multiple sectors, are enabled. The sectors in the healthcare industry include:
In an example embodiment, laboratories or pharmaceutical companies serve as distribution points of a variety of prepared integrated chips described above. Different chips are prepared for analyzing different pathogens and diseases. End-users of the chips are from the various sectors and deploy the portable assay system (described above) at respective locations and environments including in-home patient use, in the field (e.g., crops and veterinary check points), at remote/rural locations as well as at hospitals/medical centers, ports of entry and the like. Due to the plug and play configuration (i.e., quick reader turnaround, chip assay variety and chip disposability) between the invention integrated chips and portable assay system, a given portable assay system/device of the present invention may read a variety of different chips (for detecting different pathogens/diseases) at a site or may be dedicated to reading one type of chip (for detecting a certain pathogen/disease).
During use of the portable assay system, there is a two-way exchange of information between a central data center (where working data libraries and bioinformatics data reside or are maintained) and the system end-user. In this two way exchange, the data center provides known pathogen/disease mapping information to the end-user/invention system for biological sample analysis, and subsequently the invention system/end-user transmits assay results to the data center. In addition to the assay results, the data center may receive geographic location information and other case identification information from the end-users/invention system. The data center monitors incoming assay results from the plurality of deployed units/invention systems and employs pattern detection programs (common in the art). For example, a pattern in the number of cases of a given disease in a concentrated geographical area may be detected, or a pattern of movement (spreading) of a given disease may be detected based on the data received from the plural end-users. Other pattern detection and monitoring for certain conditions or occurrences of pathogens/diseases (e.g., in water supplies, food crops, blood banks, etc.) is contemplated.
In turn, the data center may be configured to programmatically generate notifications upon detection of threshold patterns. The data center may notify medical personnel (ambulance, emergency room, physician), military units, governmental agencies and so on. Such notification may be on a subscription basis where receiving parties pay a subscription to participate in the data center alerts and notifications. Different subscription levels may exists where parties/users pay at one level to have access rights to the data libraries and at another level to have access to the collected assay results data. Another subscription level may provide the automated alerts and notifications to a subscriber using subscriber supplied contact information (where and in what media/form to send the alerts).
As used herein, the notifications and alerts may be in the form of email, phone call, alarm or other audible and/or visual indication.
In addition, the data center may be configured to further respond to the end user after receiving and processing assay results from the end-user. With the given assay results, the data center cross references other known related information such as genotype, effective therapy/treatment, and so forth. The data center transmits this additional information to the end-user for on-site use.
Accordingly the present invention provides enhanced methods of medical care and treatment, disease control, bio-defense (point of incidence and real-time pathogen detection, as well as real-time tracking of infection and contagion), and other multi-sector, across industry use.
The inventions described herein can be configured or utilized in products or devices that include but are not limited to handheld devices, computer tablets, notebooks, smart phones, implantable devices (implantables), ingestible devices (ingestibles), wearable devices (wearables) and injectable devices (injectables).
A “wearable device” is a device intended for use on an external part of the body, such as an arm, leg, skin, buccal patch, torso. The wearable device is configured to be retained on the body, such as but not limited to clip-on, bracelet, adhesive patch, skin patches, buccal patches, glasses, headband, ankleband, shoe accessory (at the sole of the foot), etc. The implantable device can routinely perform the operations of the devices described herein and optionally interface the output of the operations of the device with a computer, such as by wireless communications. A wearable device in accordance with an embodiment of the invention may comprise one or more separate components, which may or may not be attached or mechanically interfaced together and/or may be located in one or more different external parts of the body, and which may communicate with each other wirelessly and/or using wired communications. A wearable device in accordance with an embodiment of the invention may also comprise only a portion of the devices described herein, and may communicate wirelessly and/or by wire with other portions of such a device herein, with such other portions being inside and/or outside the human body. Exemplary wearable devices are shown in
An “implantable device” is a device that is placed into a surgically or naturally formed cavity of the human body if it is intended to remain there for a period of days, months or longer. The implantable device can routinely perform the operations of the device described herein and optionally interface the output of the operations of the device with a computer, such as by wireless communications. An implantable device in accordance with an embodiment of the invention may comprise one or more separate components, which may or may not be attached or mechanically interfaced together and/or may be located in one or more different portions of the human body, and which may communicate with each other wirelessly and/or using wired communications. An implantable device in accordance with an embodiment of the invention may also comprise only a portion of the devices described herein, and may communicate wirelessly and/or by wire with other portions of such a device herein, with such other portions being inside and/or outside the human body.
An “ingestible device” is a device that can be delivered to a patient orally for personal monitoring. For example, the device can be an ingestible event marker used to record time-stamped, patient-logged events using the devices described herein. The ingestible component links wirelessly through communication to an external recorder which records the date and time of ingestion as well as the unique serial number of the ingestible device.
An “injectable device” is a device that can be injected into a site within the human body and that is capable of being retained at the intended site within the body. The injectable device can routinely perform the operations of the devices described herein and optionally interface the output of the operations of the device with a computer, such as by wireless communications.
Exemplary devices for an implantable, injectable or ingestible are shown in
A DNA Purification Procedure
The following example is described with reference to an integrated chip as shown in
A user injects a biological sample, magnetic beads and lysis buffer into nucleic acid extraction chambers 104 through sample inlet ports 100, then loads the integrated chip 20 into the portable assay system (10,
The user seals the amplification chambers 108, preferably using passive plug valves inserted into reagent addition ports 106 and sample wells 120. Once the chamber is sealed, the extracted DNA mixes with a PCR master mix before a Peltier cooler cycles the temperature between 50° C. and 97° C. up to 35 times to amplify the extracted DNA. Once amplification is complete, the user unseals the amplification chamber, then propels the amplified nucleic acid to the detection module using a hand-pumped syringe coupled to the integrated chip through reagent addition ports 106.
The user loads polymer gel/sieving matrix and the CE running buffer into the eight detection channels 112 through buffer well 116. Next, molecular weight standards are loaded into sample wells 120. Next, the user applies 400 V across electrodes situated on or near the sample well 120 and the sample waste wells 118 to draw the amplified nucleic acid into the detection channels 112. Once a sufficient amount of the amplified nucleic acid enters the detection channel, the user switches off the 400 V field, then applies a 6 kV field from the buffer waste well to the buffer well. This causes the molecular weight standard to separate along the detection channels 112, providing reference times. After optionally flushing the detection channels 112, the user repeats the process using the amplified nucleic acids loaded forced into sample wells 120 by syringe pressure applied to the nucleic acid amplification chambers 108. This causes the amplified nucleic acids to separate into species and migrate down the detection channels 112.
As they migrate, the molecular weight standards or the amplified nucleic acid species pass through a measurement region 1005, where they are interrogated under the control of the detection control module 60 configured to detect fluorescence signals as shown in
The detected, processed signal is matched against the signal from a known reference analyzed under identical conditions to identify pathogens in the sample. The system represents this identification process with an output signal graph 1020. Analyzing the known reference yields a reference signal trace 1021 with peaks corresponding to known pathogens in known amounts. Comparing the time ordinate of a signal peak 1022 from the unknown sample to the reference signal trace 1021 gives the user an indication of the pathogen type; the system determines the viral load by calculating the area under the signal peak 1022.
Cell Cultures
To demonstrate the performance of the integrated chip, E. coli cells were used for experimental testing. E. coli cells (DH-10B, Invitrogen) were cultured overnight in 5 mL tubes in LB media (Invitrogen) at about 37° C. on a shaker at 200 rpm. The stock culture was then either used directly for experiments or diluted (in RNAse free water) to obtain the desired cell dilution/concentration. The cultured cell concentration was obtained by measuring the culture in a spectrophotometer (Ultraspec 10, Amersham Biosciences, UK). Details of the E. coli type are as follows: E. coli, DH10B cells (ElectroMAX™ DH10B™, cat #: 12033-015, Invitrogen, US); Genotype: F-mcrA Δ(mrr-hsdRMS-mcrBC) φ80lacZ ΔM15 ΔlacX74 recA1 endA1 araD139 Δ(ara, leu)7697 galU galK λ-rpsL nupG tonA; Approximate size of the entire genomic DNA is about 4.6×106 bp.
Using these cells, experiments were performed on-chip. Two sets of experiments are presented below. In the first set, stock culture (from 0.2-2 μL) was used directly for chip experiments. In the second set of experiments, 1 μL of stock culture was serially diluted to up to infinite dilution. In each of these experiments, measurements were made during the course of the biological assay, both for the cells and DNA concentration, hence enabling quantified data for analysis. Cells were quantified as described earlier, while DNA concentration was performed on the Nanovue® (GE Health Sciences) spectrophotometer. However, due to the detection limits of both the utilized spectrophotometers, quantification of low concentration samples was challenging until the completion of the biological assay involving amplification which enabled DNA amplification that was easily quantifiable. The following experiments were performed on the integrated chip using the protocols outlined above.
Identification of a Pathogen Using Stock Cell Culture
Amplification was then performed in the amplification chamber on-chip.
Finally, upon completion of amplification, the DNA concentration was again measured and the molecular count and amplification factors were derived.
Conventional gel based electrophoresis enabled verification of the size of the resulting amplification product to be about 700 bp, as shown in
As performed earlier, the extracted DNA was re-suspended in 2 μL of water, followed by the addition of about 8 μL of amplification master mix. Amplification was then performed on-chip.
DNA concentrations were measured prior and upon amplification. The data was then used to derive the DNA concentration and amplification factor for each culture dilution sample used.
Conventional lab based gel electrophoresis was utilized to verify the size of the resulting amplification product as about 700 bp, as shown in
Results
As evident from either of the above amplification experiments, there is a drop in efficiency (i.e. implied from the amplification factor), as the concentration of initial sample increases. In an ideal assay where theoretical limitations factors are negligible, an exponential amplification should be expected. However, given the limitations with factors such as (1) loss of enzyme efficiency after repeated cycling, (2) lack of sufficient dNTPs and primer set, (3) adsorption factor (adversely enhanced by surface-to-volume ratios on-chip) inhibiting or causing poor retrieval of amplified DNA, the theoretical level of amplification may be difficult to achieve. Nevertheless, as noted in the second set of experiments, a detectable amplification with as few as about twelve starting cells in an uncontaminated input sample is achieved.
Demonstration of Amplification, Quantification of HIV-1
Unlike PCR machines currently marketed for viral load studies, a system according to an embodiment of the invention does not require any offline sample preparation and processing steps are self-contained within the customized nanochip. Biological fluids are applied directly onto the nanochip contained within the device.
A system according to an embodiment of the invention is quantitative for cDNA, DNA or RNA over a very wide dynamic range. For example, in assaying inactivated HIV-1 cDNA, the higher the HIV-1 titer of a specimen, the earlier the detection signal rises above the baseline level. The lower the HIV-1 titer of a sample, the greater number of amplification cycles is required to produce a detectable amount of HIV-1 material. The appearance of detector signal is reported as a critical threshold value (Ct). The Ct is defined as the fractional cycle number where detector signal exceeds a predetermined threshold and starts an exponential growth phase. A higher Ct value indicates a lower titer of initial HIV-1 target material.
It has been demonstrated that a device in accordance with an embodiment of the invention produces standard curves for quantitation starting from armored HIV-1 RNA virus reference samples, which contain a precisely quantified copy number of our HIV-1 RNA virus sequence targets. Armored RNA controls have become the industry standard in a wide range of diagnostic tests, including most commercial HIV viral load tests.
Head-to-Head Comparison with FDA-Approved Stratagene PCR Machine
We have further demonstrated feasibility data on a system in accordance with an embodiment of the invention by benchmarking prototypes against a gold-standard quantitative PCR machine, the Stratagene MX4000.
In
Detection of Bacterial Load with Precision Quantification
The common bacterial pathogen E. Coli was tested in a system in accordance with an embodiment of the invention, demonstrating a dynamic range of detection from 1000 copies to 10,000,000 of E. Coli DNA/ul (
The teachings of all patents, published applications and references cited herein are incorporated by reference in their entirety.
While this invention has been particularly shown and described with references to example embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.
The present application is a continuation of, and claims benefit under 35 USC 120 to, U.S. application Ser. No. 14/777,194, filed Sep. 15, 2015, which claims priority under 35 USC 120 to, international application PCT/US2014/029008, filed Mar. 14, 2014, which claims the benefit of U.S. Provisional Application No. 61/951,084, filed on Mar. 11, 2014; and claims the benefit of U.S. Provisional Application No. 61/875,661, filed on Sep. 9, 2013; and claims the benefit of U.S. Provisional Application No. 61/790,354, filed on Mar. 15, 2013. The entire teachings of the above applications are incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
61951084 | Mar 2014 | US | |
61875661 | Sep 2013 | US | |
61790354 | Mar 2013 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 14777194 | Sep 2015 | US |
Child | 18138017 | US |