Patent Application
20180259501
Many diseases are difficult to be detected by a single approach or methodology. In particular, many serious diseases with high morbidity and mortality, including cancer and heart diseases, are difficult to diagnose at an early stage with high sensitively, specificity and efficiency, by using one detection equipment. Current disease diagnosis devices typically detect and rely on a single type of macroscopic data and information such as body temperature, blood pressure, or scanned images of the body. For example, to detect serious diseases such as cancer, each of the diagnosis apparatus commonly used today is based on one imaging technology, such as x-ray, CT scan, or nuclear magnetic resonance (NMR). While used in combination, these diagnosis apparatus provide various degrees of usefulness in disease diagnosis. However, each of them alone cannot provide accurate, conclusive, efficient, and cost-effective diagnosis of such serious diseases as cancer at an early stage. Further, many of the existing diagnosis apparatus have a large size and are invasive with large footprint, such as x-ray, CT scan, or nuclear magnetic resonance (NMR).
Even the newly emerged technologies such as those deployed in DNA tests usually rely on a single diagnosis technology and cannot provide a comprehensive, reliable, accurate, conclusive, and cost-effective detection for a serious disease. In recent years, there have been some efforts in using nano technologies for various biological applications, with most of the work focused on one type of gene mapping and moderate developments in the field of disease detection. For instance, Pantel et al. discussed the use of a MicroEelectroMechanical Systems (MEMS) sensor for detecting cancer cells in blood and bone marrow in vitro (see, e.g., Klaus Pantel et al., Nature Reviews, 2008, 8, 329); Kubena et al. disclose in U.S. Pat. No. 6,922,118 the deployment of MEMS for detecting biological agents; and Weissman et al. disclose in U.S. Pat. No. 6,330,885 utilizing MEMS sensor for detecting accretion of biological matter.
In sum, to date, most of above described technologies have been limited to isolated diagnosis technology for sensing, using systems of relatively simple constructions and large dimensions but often with limited functions, and lack sensitivities and specificities. Further, the existing technologies require multiple times detection by multiple apparatus. This will increase costs and affect achieved degree of sensitivity and specificity as well.
These drawbacks call for novel solutions that provide reliable and flexible diagnosis apparatus using multiple diverse technologies and bring improved accuracy, sensitivity, specificity, efficiency, non-invasiveness, practicality, conclusive, and speed in early-stage disease detection at reduced costs.
The present invention in general relates to a novel technology for detecting disease, in which a number of different classifications of biological information are collected in a device and processes or analyzed.
In traditional technology, typically only one level of biological information is collected (one dimensional), while in this novel technology, at least two levels (classifications) of information can be collected (seven dimensional, or seven factor interactions). Compared with traditional technology which typically focuses on one parameter or one level (for example, bio-marker at protein level), signal and information collected in this novel technology can be collected in a number of forms, and non-linearly amplified. There are additional 2-factor and three-factor interactions which can be collected and analyzed, which maybe missing in other technologies, since they typically only measure one type of biological information.
This novel technology can be used for cancer screening, assisting in diagnosis, prognosis, and follow-up tests with improved sensitivity and specificity, ability to detect cancer early, ability to detect over 10 types of cancer, cost effective, and no side effects.
The novel technology offers several advantages that cannot be achieved by the traditional technology: (1) Ability to detect over 10 cancer types in one test, including some cancer types which cannot be detected by other in vitro tests (e.g., esophageal cancer, cerebral cancer), covering over 80% of all cancer incidences; (2) capable of early stage cancer detection; (3) high sensitivity and specificity (75%˜90% on over 10 types of cancer); (4) no side effects; (5) high speed, fully automated operations without human intervention; (6) statistical difference between cancer group and non-cancer disease group including inflammation—significantly lower false positives (higher specificity) ; (7) easy process, no difference between fasting blood testing and non-fasting blood testing, and (8) highly cost effective.
Accordingly, one aspect of this invention provides an apparatus for detecting presence or monitoring progression of a disease in a biological subject. The biological subject can be a blood sample, a urine sample, or a sweat sample of a mammal. The apparatus comprises a chamber in which the biological subject passes through, and at least one detection transducer placed partially or completely in the chamber; wherein at least two types of information about the biological subject selected from the group consisting of chemical composition, cellular classification, molecular classification, and any combination thereof, are detected by the detection transducer and collected for analysis to determine whether the disease is likely to be present with the biological subject or to determine the status of the disease, therefore providing the ability to continuously determine or monitor progression of the disease.
In some embodiments, the detection transducer detects at least one selected from the group consisting of a chemical composition, a cellular classification, a molecular classification, and any combination thereof; and the detected information is collected for analysis to as to whether the disease is likely to be present with the biological subject.
An example of the chemical composition includes protein (such as a sugar based protein, an embryonic protein, a protein-based antigen, and a carbohydrate antigen). Examples of the molecular classification include DNA, RNA, or a biomarker.
As used herein, the term “biomarker” means a measurable indicator of the severity or presence of some disease state, but more generally a biomarker is anything that can be used as an indicator of a particular disease state or some other physiological state of an organism. A biomarker can be a substance that is introduced into an organism as a means to examine organ function or other aspects of health. For example, rubidium chloride is used in isotopic labeling to evaluate perfusion of heart muscle. It can also be a substance whose detection indicates a particular disease state, for example, the presence of an antibody may indicate an infection. More specifically, a biomarker indicates a change in expression or state of a protein that correlates with the risk or progression of a disease, or with the susceptibility of the disease to a given treatment. Biomarkers can be specific cells, molecules, or genes, gene products, enzymes, or hormones.
Examples of the cellular classification include circulating tumor cells, cell surface properties, cell signaling properties, and cell geometrical properties.
In some embodiments, the chemical composition, cellular classification, or molecular classification includes a property of the biological subject at microscope level selected from the group consisting of a thermal, optical, acoustical, biological, chemical, physical-chemical, electro-mechanical, electro-chemical, electro-chemical-mechanical, bio-physical, bio-chemical, bio-mechanical, bio-electrical, bio-physical-chemical, bio-electro-physical, bio-electro-mechanical, bio-electro-chemical, bio-chemical-mechanical, bio-electro-physical-chemical, bio-electro-physical-mechanical, bio-electro-chemical-mechanical, physical, an electric, magnetic, electro-magnetic, and mechanical property. The thermal property can be temperature or vibrational frequency; the optical property is optical absorption, optical transmission, optical reflection, optical-electrical property, brightness, or fluorescent emission; the radiation property is radiation emission, signal triggered by radioactive material, or information probed by radioactive material; the chemical property is pH value, chemical reaction, bio-chemical reaction, bio-electro-chemical reaction, reaction speed, reaction energy, speed of reaction, oxygen concentration, oxygen consumption rate, ionic strength, catalytic behavior, chemical additives to trigger enhanced signal response, bio-chemical additives to trigger enhanced signal response, biological additives to trigger enhanced signal response, chemicals to enhance detection sensitivity, bio-chemicals to enhance detection sensitivity, biological additives to enhance detection sensitivity, or bonding strength; the physical property is density, shape, volume, or surface area; the electrical property is surface charge, surface potential, resting potential, electrical current, electrical field distribution, surface charge distribution, cell electronic properties, cell surface electronic properties, dynamic changes in electronic properties, dynamic changes in cell electronic properties, dynamic changes in cell surface electronic properties, dynamic changes in surface electronic properties, electronic properties of cell membranes, dynamic changes in electronic properties of membrane surface, dynamic changes in electronic properties of cell membranes, electrical dipole, electrical quadruple, oscillation in electrical signal, electrical current, capacitance, three-dimensional electrical or charge cloud distribution, electrical properties at telomere of DNA and chromosome, capacitance, or impedance; the biological property is surface shape, surface area, surface charge, surface biological property, surface chemical property, pH, electrolyte, ionic strength, resistivity, cell concentration, or biological, electrical, physical or chemical property of solution; the acoustic property is frequency, speed of acoustic waves, acoustic frequency and intensity spectrum distribution, acoustic intensity, acoustical absorption, or acoustical resonance; the mechanical property is internal pressure, hardness, flow rate, viscosity, fluid mechanical properties, shear strength, elongation strength, fracture stress, adhesion, mechanical resonance frequency, elasticity, plasticity, or compressibility.
The disease that can be detected or monitor for progress can be a cancer, an inflammatory disease, diabetes, a lung disease, a heart disease, a liver disease, a gastric disease, a biliary disease, or a cardiovascular disease. Examples of cancer comprise breast cancer, lung cancer, esophageal cancer, intestine cancer, cancer related to blood, liver cancer, stomach cancer, cervical cancer, ovarian cancer, rectum cancer, colon cancer, nasopharyngeal cancer, cardiac carcinoma, uterine cancer, oophoroma, pancreatic cancer, prostate cancer, brain tumor, and circulating tumor cells; examples of the inflammatory disease include acne vulgaris, asthma, autoimmune diseases, autoinflammatory diseases, celiac disease, chronic prostatitis, diverticulitis, glomerulonephritis, hidradenitis suppurativa, hypersensitivities, inflammatory bowel diseases, interstitial cystitis, otitis, pelvic inflammatory disease, reperfusion injury, rheumatic fever, rheumatoid arthritis, sarcoidosis, transplant rejection, and tasculitis; examples of the lung disease include asthma, chronic obstructive pulmonary disease, chronic bronchitis, emphysema, acute bronchitis, cystic fibrosis, pneumonia, tuberculosis, pulmonary edema, acute respiratory distress syndrome, pneumoconiosis, interstitial lung disease, pulmonary embolism, and pulmonary hypertension; examples of the diabetes include Type 1 diabetes, Type 2 diabetes, and gestational diabetes; examples of the heart disease include coronary artery disease, enlarged heart (cardiomegaly), heart attack, irregular heart rhythm, atrial fibrillation, heart rhythm disorders, heart valve disease, sudden cardiac death, congenital heart disease, heart muscle disease (cardiomyopathy), dilated cardiomyopathy, hypertrophic cardiomyopathy, restrictive cardiomyopathy, pericarditis, pericardial effusion, marfan syndrome, and heart murmurs; examples of the liver disease include fascioliasis, hepatitis, alcoholic liver disease, fatty liver disease (hepatic steatosis), hereditary diseases, Gilbert's syndrome, cirrhosis, primary biliary cirrhosis, primary sclerosing cholangitis, and Budd-Chiari syndrome; examples of the gastric disease include gastritis, gastric polyp, gastric ulcer, benign tumor of stomach, acute gastric mucosa lesion, antral gastritis, and gastric stromal tumors; examples of the biliary disease include calculus of bile duct, cholecystolithiasis, cholecystitis, cholangiectasis, cholangitis, and gallbladder polyps; the cardiovascular disease comprises coronary artery disease, peripheral arterial disease, cerebrovascular disease, renal artery stenosis, aortic aneurysm, cardiomyopathy, hypertensive heart disease, heart failure, pulmonary heart disease, cardiac dysrhythmias, endocarditis, inflammatory cardiomegaly, myocarditis, valvular heart disease, congenital heart disease, rheumatic heart disease, coronary artery disease, peripheral arterial disease, cerebrovascular disease, and renal artery stenosis.
In some other embodiments, the apparatus can further include a sensor positioned to be partially inside the chamber and capable of detecting a property of the biological subject at the microscopic level.
In some other embodiments, the apparatus can further include a read-out circuitry which is connected to at least one sensor and transfers data from the sensor to a recording device.
The connection between the read-out circuit and the sensor can be digital, analog, optical, thermal, piezo-electrical, piezo-photronic, piezo-electrical photronic, opto-electrical, electro-thermal, opto-thermal, electric, electromagnetic, electromechanical, or mechanical.
The sensor can be positioned on the interior surface of the chamber.
In some other embodiments, each sensor is independently a thermal sensor, optical sensor, acoustical sensor, biological sensor, chemical sensor, electro-mechanical sensor, electro-chemical sensor, electro-optical sensor, electro-thermal sensor, electro-chemical-mechanical sensor, bio-chemical sensor, bio-mechanical sensor, bio-optical sensor, electro-optical sensor, bio-electro-optical sensor, bio-thermal optical sensor, electro-chemical optical sensor, bio-thermal sensor, bio-physical sensor, bio-electro-mechanical sensor, bio-electro-chemical sensor, bio-electro-optical sensor, bio-electro-thermal sensor, bio-mechanical-optical sensor, bio-mechanical thermal sensor, bio-thermal-optical sensor, bio-electro-chemical-optical sensor, bio-electro-mechanical optical sensor, bio-electro-thermal-optical sensor, bio-electro-chemical-mechanical sensor, physical sensor, mechanical sensor, piezo-electrical sensor, piezo-electro photronic sensor, piezo-photronic sensor, piezo-electro optical sensor, bio-electrical sensor, bio-marker sensor, electrical sensor, magnetic sensor, electromagnetic sensor, image sensor, or radiation sensor. For example, the thermal sensor comprises a resistive temperature micro-sensor, a micro-thermocouple, a thermo-diode and thermo-transistor, and a surface acoustic wave (SAW) temperature sensor; the image sensor comprises a charge coupled device (CCD) or a CMOS image sensor (CIS); the radiation sensor comprises a photoconductive device, a photovoltaic device, a pyro-electrical device, or a micro-antenna; the mechanical sensor comprises a pressure micro-sensor, micro-accelerometer, flow meter, viscosity measurement tool, micro-gyrometer, or micro flow-sensor; the magnetic sensor comprises a magneto-galvanic micro-sensor, a magneto-resistive sensor, a magneto diode, or magneto-transistor; the biochemical sensor comprises a conductimetric device, a bio-marker, a bio-marker attached to a probe structure, or a potentiometric device.
In some other embodiments, at least one sensor is a probing sensor and applies a probing or disturbing signal to the biological subject.
In some other embodiments, at least another sensor, different from the probing sensor, is a detection sensor and detects a response from the biological subject upon which the probing or disturbing signal is applied.
The chamber can have a length ranging from 1 micron to 50,000 microns, from 1 micron to 15,000 micron, from 1 micron to 10,000 microns, from 1.5 microns to 5,000 microns, or from 3 microns to 1,000 microns. On the other hand, the chamber can have a width or height ranging from 0.1 micron to 100 microns; from 0.1 micron to 25 microns, from 1 micron to 15 microns, or from 1.2 micron to 10 micron.
In some other embodiments, the apparatus comprises at least four sensors which are located on one side, two opposite sides, or four sides of the interior surface of the chamber. For example, the two sensors in the micro-cylinder can be apart by a distance ranging from 0.1 micron to 500 micron, from 0.1 micron to 50 micron, form 1 micron to 100 micron, from 2.5 microns to 100 micron, or from 5 micron to 250 micron; at least one of the panels comprises at least two sensors that are arranged in at least two arrays each separated by at least a micro sensor in a cylinder; or at least one array of the sensors in the panel comprises two or more sensors.
In some other embodiments, the sorting unit or the detection unit further comprises an application specific integrated circuit chip which is internally bonded to or integrated into one of the panels or a micro-cylinder.
In still some other embodiments, the sorting unit or the detection unit further comprises a memory unit, a logic processing unit, an optical device, imaging device, camera, viewing station, acoustic detector, piezo-electrical detector, piezo-photronic detector, piezo-electro photronic detector, electro-optical detector, electro-thermal detector, bio-electrical detector, bio-marker detector, bio-chemical detector, chemical sensor, thermal detector, ion emission detector, photo-detector, x-ray detector, radiation material detector, electrical detector, or thermal recorder, each of which is integrated into the a panel or a micro cylinder.
In some other embodiments, one signal contains information related to the disease's location or where the disease is present in the source of the biological subject.
In still some other embodiments, one signal contains information related to the occurrence or type of the disease.
The apparatus of this invention is able to detect the presence of at least two different diseases at the same time or to determine the status or progression of a disease.
In another aspect, the present invention provides a method for detecting the presence or progression of a disease in a biological subject, comprising detecting at least two types of information selected from the group consisting of chemical composition, cellular classification, molecular classification and any combination thereof of the biological subject, and analyzing the collected information to determine if the likely presence or progression of the status of the disease with the biological subject. Examples of the disease include cancer, an inflammatory disease, diabetes, lung diseases, liver diseases, gastric diseases, biliary diseases, or a cardiovascular disease. Specifically, the cancer can be breast cancer, lung cancer, esophageal cancer, intestine cancer, cancer related to blood, liver cancer, stomach cancer, cervical cancer, ovarian cancer, rectum cancer, colon cancer, nasopharyngeal cancer, cardiac carcinoma, uterine cancer, oophoroma, pancreatic cancer, prostate cancer, brain tumor, or circulating tumor cells; the inflammatory disease can be acne vulgaris, asthma, autoimmune diseases, autoinflammatory diseases, celiac disease, chronic prostatitis, diverticulitis, glomerulonephritis, hidradenitis suppurativa, hypersensitivities, inflammatory bowel diseases, interstitial cystitis, otitis, pelvic inflammatory disease, reperfusion injury, rheumatic fever, rheumatoid arthritis, sarcoidosis, transplant rejection, or tasculitis; the cardiovascular disease can be coronary artery disease, peripheral arterial disease, cerebrovascular disease, renal artery stenosis, aortic aneurysm, cardiomyopathy, hypertensive heart disease, heart failure, pulmonary heart disease, cardiac dysrhythmias, endocarditis, inflammatory cardiomegaly, myocarditis, valvular heart disease, congenital heart disease, rheumatic heart disease, coronary artery disease, peripheral arterial disease, cerebrovascular disease, or renal artery stenosis.
The biological subject can be cells, a sample of an organ or tissue, DNA, RNA, virus, or protein. For example, the cells are circulating tumor cells or cancer cells, e.g., breast cancer, lung cancer, esophageal cancer, cervical cancer, ovarian cancer, rectum cancer, colon cancer, nasopharyngeal cancer, cardiac carcinoma, uterine cancer, oophoroma, pancreatic cancer, prostate cancer, brain tumor, intestine cancer, cancer related to blood, liver cancer, stomach cancer, or circulating tumor cells. In some other embodiments, the biological subject is contained in a media and transported into the first intra-unit channel.
In yet another aspect, the invention provides a method for detecting presence or progression of a disease in a biological subject, which includes testing at least two types of information in the biological subject, with one of the at least two types of information indicating the disease's presence or progression in status and the other type of information indicating the disease's location.
In some embodiments, the two levels of information each comprise protein level information, molecular level information, cellular level information, genetic-level information, or any combination thereof.
In yet another aspect, the invention provides a method for detecting presence or progression of a disease in a biological subject, which comprising measuring at least one parameter correlated to a property at the protein, cellular, molecular, or genetic level.
For instance, the property is a thermal, optical, acoustical, biological, chemical, physical-chemical, electro-mechanical, electro-chemical, electro-chemical-mechanical, bio-physical, bio-chemical, bio-mechanical, bio-electrical, bio-physical-chemical, bio-electro-physical, bio-electro-mechanical, bio-electro-chemical, bio-chemical-mechanical, bio-electro-physical-chemical, bio-electro-physical-mechanical, bio-electro-chemical-mechanical, physical, an electric, magnetic, electro-magnetic, or mechanical property of the biologic subject. Specifically, for example, the thermal property is temperature or vibrational frequency; the optical property is optical absorption, optical transmission, optical reflection, optical-electrical property, brightness, or fluorescent emission; the radiation property is radiation emission, signal triggered by radioactive material, or information probed by radioactive material; the chemical property is pH value, chemical reaction, bio-chemical reaction, bio-electro-chemical reaction, reaction speed, reaction energy, speed of reaction, oxygen concentration, oxygen consumption rate, ionic strength, catalytic behavior, chemical additives to trigger enhanced signal response, bio-chemical additives to trigger enhanced signal response, biological additives to trigger enhanced signal response, chemicals to enhance detection sensitivity, bio-chemicals to enhance detection sensitivity, biological additives to enhance detection sensitivity, or bonding strength; the physical property is density, shape, volume, or surface area; the electrical property is surface charge, surface potential, resting potential, electrical current, electrical field distribution, surface charge distribution, cell electronic properties, cell surface electronic properties, dynamic changes in electronic properties, dynamic changes in cell electronic properties, dynamic changes in cell surface electronic properties, dynamic changes in surface electronic properties, electronic properties of cell membranes, dynamic changes in electronic properties of membrane surface, dynamic changes in electronic properties of cell membranes, electrical dipole, electrical quadruple, oscillation in electrical signal, electrical current, capacitance, three-dimensional electrical or charge cloud distribution, electrical properties at telomere of DNA and chromosome, capacitance, or impedance; the biological property is surface shape, surface area, surface charge, surface biological property, surface chemical property, pH, electrolyte, ionic strength, resistivity, cell concentration, or biological, electrical, physical or chemical property of solution; the acoustic property is frequency, speed of acoustic waves, acoustic frequency and intensity spectrum distribution, acoustic intensity, acoustical absorption, or acoustical resonance; the mechanical property is internal pressure, hardness, flow rate, viscosity, fluid mechanical properties, shear strength, elongation strength, fracture stress, adhesion, mechanical resonance frequency, elasticity, plasticity, or compressibility.
In some other embodiments, the parameter can be simultaneously correlated to at least two levels of information each independently selected from the group consisting of chemical composition, cellular classification, molecular classification, genetic classification, and any combination thereof.
For example, the parameter is a function of at least two levels of information each independently selected from the group consisting of chemical composition, cellular classification, molecular classification, genetic classification, and any combination thereof.
In some other embodiments, the at least two levels of information interact with each other to amplify the measured parameter of the biological subject.
For instance, the measured parameter can include a property at the protein level, cellular level, molecular level, or genetic level.
In yet still another aspect of this invention is a method for detecting presence or monitoring progression of a disease in a biological subject, comprising testing at least two parameters of the biological subject for at least two different levels of information, processing the at least two different levels of information to result in a new parameter that has a stronger signal intensity than the sum of the signal intensities of the at least two levels of information.
In some embodiments, the at least two levels parameters comprise information selected from the group consisting of chemical composition, cellular classification, molecular classification, and any combination thereof of the biological subject. For example, one testing parameter contains two biological levels of information, and its signal intensity is greater than the sum of the two signal intensities of the testing parameters with each containing one of the two biological levels. For another example, one signal has information related to the disease's location or where the disease is present in the biological subject. For still another example, one signal contains information related to the presence or type of the disease.
The invention also provide a method for detecting presence or monitoring progression of a disease in a biological subject, which comprises tested one parameter containing at least two levels of signal, wherein the tested parameter's signal intensity is greater than the sum of the intensity of the at least two levels of signal.
In some embodiments, the at least two levels of signal comprise information selected from the group consisting of chemical composition, cellular classification, molecular classification, and any combination thereof of the biological subject.
As used herein, the term “or” is meant to include both “and” and “or”. It may be interchanged with “and/or.”
As used herein, a singular noun is meant to include its plural meaning. For instance, a micro device can mean either a single micro device or multiple micro-devices.
As used herein, the term “patterning” means shaping a material into a certain physical form or pattern, including a plane (in which case “patterning” would also mean “planarization”).
As used herein, the term “a biocompatible material” refers to a material that is intended to interface with a living organism or a living tissue and can function in intimate contact therewith. When used as a coating, it reduces the adverse reaction a living organism or a living tissue has against the material to be coated, e.g., reducing the severity or even eliminating the rejection reaction by the living organism or living tissue. As used herein, it encompasses both synthetic materials and naturally occurring materials. Synthetic materials usually include biocompatible polymers, made either from synthetic or natural starting materials, whereas naturally occurring biocompatible materials include, e.g., proteins or tissues.
As used herein, the term “a biological subject” or “a biological sample” for analysis or test or diagnosis refers to the subject to be analyzed by a disease detection apparatus. It can be a single cell, a single biological molecular (e.g., DNA, RNA, or protein), a single biological subject (e.g., a single cell or virus), any other sufficiently small unit or fundamental biological composition, or a sample of a subject's organ or tissue that may having a disease or disorder.
As used herein, the term “disease” is interchangeable with the term “disorder” and generally refers to any abnormal microscopic property or condition (e.g., a physical condition) of a biological subject (e.g., a mammal or biological species).
As used herein, the term “subject” generally refers to a mammal, e.g., a human person.
As used herein, the term “microscopic level” refers to the subject being analyzed by the disease detection apparatus of this invention is of a microscopic nature and can be a single cell, a single biological molecular (e.g., DNA, RNA, or protein), a single biological subject (e.g., a single cell or virus), and other sufficiently small unit or fundamental biological composition.
As used herein, an “apparatus” or a “micro-device” or “micro device” can be any of a wide range of materials, properties, shapes, and degree of complexity and integration. The term has a general meaning for an application from a single material to a very complex device comprising multiple materials with multiple sub units and multiple functions. The complexity contemplated in the present invention ranges from a very small, single particle with a set of desired properties to a fairly complicated, integrated unit with various functional units contained therein. For example, a simple micro-device could be a single spherical article of manufacture of a diameter as small as 100 angstroms with a desired hardness, a desired surface charge, or a desired organic chemistry absorbed on its surface. A more complex micro device could be a 1 millimeter device with a sensor, a simple calculator, a memory unit, a logic unit, and a cutter all integrated onto it. In the former case, the particle can be formed via a fumed or colloidal precipitation process, while the device with various components integrated onto it can be fabricated using various integrated circuit manufacturing processes. In some places, a micro-device or micro device represents a sub-equipment unit.
As used herein, the term “parameter” refers to a particular detection target (e.g., a property of microscopic level, physical property such as hardness, viscosity, current, or voltage, or chemical property such as pH value) of the biological subject to be detected, and can include micro-level property.
As used herein, the term “level” refers to chemical composition (including biochemical composition such as protein, genetic materials, e.g., DNA and RNA), cellular classification, or molecular classification of the biological subject to be detected.
As used herein, the term “component” refers a lower division or building block of a level described above. For instance, a protein level can include such components as alpha-feto protein or sugar protein; and the level of a cellular classification can include such components as surface voltage and membrane composition.
As used herein, if not specifically defined, a “channel” or “chamber” can be either an inter-unit channel or an intra-unit channel.
Biological subjects that can be detected by the apparatus include, e.g., blood, urine, saliva, tear, and sweat. The detection results can indicate the possible occurrence or presence of a disease (e.g., one in its early stage) in the biological subject.
As used herein, the term “absorption” typically means a physical bonding between the surface and the material attached to it (absorbed onto it, in this case). On the other hand, the word “adsorption” generally means a stronger, chemical bonding between the two. These properties are very important for the present invention as they can be effectively used for targeted attachment by desired micro devices for measurement at the microscopic level.
As used herein, the term “contact” (as in “the first micro-device contacts a biologic entity”) is meant to include both “direct” (or physical) contact and “non-direct” (or indirect or non-physical) contact. When two subjects are in “direct” contact, there is generally no measurable space or distance between the contact points of these two subjects; whereas when they are in “indirect” contact, there is a measurable space or distance between the contact points of these two subjects.
As used herein, the term “probe” or “probing,” in addition to its dictionary meaning, could mean applying a signal (e.g., an acoustic, optical, magnetic, chemical, electrical, electro-magnetic, bio-chemical, bio-physical, or thermal signal) to a subject and thereby stimulating the subject and causing it to have some kind of intrinsic response.
As used herein, the term “thermal property” refers to temperature, freezing point, melting point, evaporation temperature, glass transition temperature, or thermal conductivity.
As used herein, the term “optical property” refers to reflection, optical absorption, optical scattering, wave length dependent properties, color, luster, brilliance, scintillation, or dispersion.
As used herein, the term “electrical property” refers to surface charge, surface potential, electrical field, charge distribution, electrical field distribution, resting potential, action potential, or impedance of a biological subject to be analyzed.
As used herein, the term “magnetic property” refers to diamagnetic, paramagnetic, or ferromagnetic.
As used herein, the term “electromagnetic property” refers to property that has both electrical and magnetic dimensions.
As used herein, the term “acoustical property” refers to the characteristics found within a structure that determine the quality of sound in its relevance to hearing. It can generally be measured by the acoustic absorption coefficient. See, e.g., U.S. Pat. No. 3,915,016, for means and methods for determining an acoustical property of a material; T. J. Cox et al., Acoustic Absorbers and Diffusers, 2004, Spon Press.
As used herein, the term “biological property” is meant to generally include chemical and physical properties of a biological subject.
As used herein, the term “chemical property” refers to pH value, ionic strength, or bonding strength within the biological sample.
As used herein, the term “physical property” refers to any measurable property the value of which describes a physical system's state at any given moment in time. The physical properties of a biological sample may include, but are not limited to absorption, albedo, area, brittleness, boiling point, capacitance, color, concentration, density, dielectrical, electrical charge, electrical conductivity, electrical impedance, electrical field, electrical potential, emission, flow rate, fluidity, frequency, inductance, intrinsic impedance, intensity, irradiance, luminance, luster, malleability, magnetic field, magnetic flux, mass, melting point, momentum, permeability, permittivity, pressure, radiance, solubility, specific heat, strength, temperature, tension, thermal conductivity, flow rate, velocity, viscosity, volume, surface area, shape, and wave impedance.
As used herein, the term “mechanical property” refers to strength, hardness, flow rate, viscosity, toughness, elasticity, plasticity, brittleness, ductility, shear strength, elongation strength, fracture stress, or adhesion of the biological sample.
As used herein, the term “disturbing signal” has the same meaning as “probing signal” and “stimulating signal.”
As used herein, the term “disturbing unit” has the same meaning as “probing unit” and “stimulating unit.”
As used herein, the term “conductive material” (or its equivalent “electrical conductor”) is a material which contains movable electrical charges. A conductive material can be a metal (e.g., copper, silver, or gold) or non-metallic (e.g., graphite, solutions of salts, plasmas, or conductive polymers). In metallic conductors, such as copper or aluminum, the movable charged particles are electrons (see electrical conduction). Positive charges may also be mobile in the form of atoms in a lattice that are missing electrons (known as holes), or in the form of ions, such as in the electrolyte of a battery.
As used herein, the term “electrically insulating material” (also known as “insulator” or “dielectric”) refers to a material that resists the flow of electrical current. An insulating material has atoms with tightly bonded valence electrons. Examples of electrically insulating materials include glass or organic polymers (e.g., rubber, plastics, or Teflon).
As used herein, the term “semiconductor” (also known as “semiconducting material”) refers to a material with electrical conductivity due to electron flow (as opposed to ionic conductivity) intermediate in magnitude between that of a conductor and an insulator. Examples of inorganic semiconductors include silicon, silicon-based materials, and germanium. Examples of organic semiconductors include such aromatic hydrocarbons as the polycyclic aromatic compounds pentacene, anthracene, and rubrene; and polymeric organic semiconductors such as poly(3-hexylthiophene), poly(p-phenylene vinylene), polyacetylene and its derivatives. Semiconducting materials can be crystalline solids (e.g., silicon), amorphous (e.g., hydrogenated amorphous silicon and mixtures of arsenic, selenium and tellurium in a variety of proportions), or even liquid.
As used herein, the term “biological material” has the same meaning of “biomaterial” as understood by a person skilled in the art. Without limiting its meaning, biological materials or biomaterials can generally be produced either in nature or synthesized in the laboratory using a variety of chemical approaches utilizing organic compounds (e.g., small organic molecules or polymers) or inorganic compounds (e.g., metallic components or ceramics). They generally can be used or adapted for a medical application, and thus comprise whole or part of a living structure or biomedical device which performs, augments, or replaces a natural function. Such functions may be benign, like being used for a heart valve, or may be bioactive with a more interactive functionality such as hydroxyl-apatite coated hip implants. Biomaterials can also be used every day in dental applications, surgery, and drug delivery. For instance, a construct with impregnated pharmaceutical products can be placed into the body, which permits the prolonged release of a drug over an extended period of time. A biomaterial may also be an autograft, allograft, or xenograft which can be used as a transplant material. All these materials that have found applications in other medical or biomedical fields can also be used in the present invention.
As used herein, the term “microelectronic technology or process” generally encompasses the technologies or processes used for fabricating micro-electronic and optical-electronic components. Examples include lithography, etching (e.g., wet etching, dry etching, or vapor etching), oxidation, diffusion, implantation, annealing, film deposition, cleaning, direct-writing, polishing, planarization (e.g., by chemical mechanical polishing), epitaxial growth, metallization, process integration, simulation, or any combinations thereof. Additional descriptions on microelectronic technologies or processes can be found in, e.g., Jaeger, Introduction to Microelectronic Fabrication, 2nd Ed., Prentice Hall, 2002; Ralph E. Williams, Modern GaAs Processing Methods, 2nd Ed., Artech House, 1990; Robert F. Pierret, Advanced Semiconductor Fundamentals, 2nd Ed., Prentice Hall, 2002; S. Campbell, The Science and Engineering of Microelectronic Fabrication, 2nd Ed., Oxford University Press, 2001, the contents of all of which are incorporated herein by reference in their entireties.
As used herein, the term “selective” as included in, e.g., “patterning material B using a microelectronics process selective to material A”, means that the microelectronics process is effective on material B but not on material A, or is substantially more effective on material B than on material B (e.g., resulting in a much higher removal rate on material B than on material A and thus removing much more material B than material A).
As used herein, the term “carbon nano-tube” generally refers to as allotropes of carbon with a cylindrical nanostructure. See, e.g., Carbon Nanotube Science, by P. J. F. Harris, Cambridge University Press, 2009, for more details about carbon nano-tubes.
Through the use of a single micro-device or a combination of micro-devices integrated into a disease detection apparatus, the disease detection capabilities can be significantly improved in terms of sensitivity, specificity, speed, cost, apparatus size, functionality, and ease of use, along with reduced invasiveness and side-effects. A large number of micro-device types capable of measuring a wide range of microscopic properties of biological sample for disease detection can be integrated and fabricated into a single detection apparatus using micro-fabrication technologies and novel process flows disclosed herein. While for the purposes of demonstration and illustration, a few novel, detailed examples have been shown herein on how microelectronics or nano-fabrication techniques and associated process flows can be utilized to fabricate highly sensitive, multi-functional, and miniaturized detection devices, the principle and general approaches of employing microelectronics and nano-fabrication technologies in the design and fabrication of high performance detection devices have been contemplated and taught, which can and should be expanded to various combination of fabrication processes including but not limited to thin film deposition, patterning (lithography and etch), planarization (including chemical mechanical polishing), ion implantation, diffusion, cleaning, various materials, and various process sequences and flows and combinations thereof.
One aspect of the present invention relates to apparatus for detecting a disease in a biological subject in vivo or in vitro (e.g., human being, an organ, a tissue, or cells in a culture). Each apparatus comprises a delivery system, at least two sub-equipment units, and optionally a central control system. Each sub-equipment is capable of measuring at least a microscopic property of a biological sample. Accordingly, the apparatus of this invention can detect different parameters of the biological subject and provide accuracy, sensitivity, specificity, efficiency, non-invasiveness, practicality, conclusive, and speed in early-stage disease detection at reduced costs. In addition, the apparatus of this invention have some major advantages, such as reducing effective foot print (e.g., defined as function per unit space), reducing space for the medical devices, reducing overall cost, and providing conclusive and effective diagnosis by one device.
The delivery system can be a fluid delivery system. By the constant pressure fluid delivery system, microscopic biological subjects can be delivered onto or into one or more desired sub-equipment units of the apparatus.
As a key component of the apparatus, the micro-device should include means to perform at least the function of addressing, controlling, forcing, receiving, amplifying, or storing information from each probing address. As an example, the apparatus can further include a central control system for controlling the biological subject matter to be transported to one or more desired sub-equipment units and reading and analyzing a detected data from each sub-equipment unit. The central control system includes a controlling circuitry, an addressing unit, an amplifier circuitry, a logic processing circuitry, a memory unit, an application specific chip, a signal transmitter, a signal receiver, or a sensor.
In some embodiments, the fluid delivering system comprises a pressure generator, a pressure regulator, a throttle valve, a pressure gauge, and distributing kits. As examples of these embodiments, the pressure generator can include a motor piston system and a bin containing compressed gas; the pressure regulator (which can consist of multiple regulators) can down-regulate or up-regulate the pressure to a desired value; the pressure gauge feeds back the measured value to the throttle valve which then regulates the pressure to approach the target value.
The biological fluid to be delivered can be a sample of a biological entity to be detected for disease or something not necessarily to be detected for disease. In some embodiments, the fluid to be delivered is liquid (e.g., a blood sample or a lymph sample). The pressure regulator can be a single pressure regulator or multiple pressure regulators which are placed in succession to either down-regulate or up-regulate the pressure to a desired level, particularly when the initial pressure is either too high or too low for a single regulator to adjust to the desired level or a level that is acceptable for an end device or target.
Optionally, the apparatus includes additional features and structures to deliver a second liquid solution containing at least an enzyme, protein, oxidant, reducing agent, catalyst, radio-active component, optical emitting component, or ionic component. This second liquid solution can be added to the sample to be measured before or during sorting of the biological subject sample to be measured, or before or during the measurement (i.e., detection) of the biological subject sample, for the purposes of further enhancing the apparatus' measurement sensitivity.
In some other embodiments, the system controller includes a pre-amplifier, a lock-in amplifier, an electrical meter, a thermal meter, a switching matrix, a system bus, a nonvolatile storage device, a random access memory, a processor, or a user interface. The interface can include a sensor which can be a thermal sensor, a flow meter, an optical sensor, an acoustic detector, a current meter, an electrical sensor, a magnetic sensor, an electro-magnetic sensor, a pH meter, a hardness measurement sensor, an imaging device, a camera, a piezo-electrical sensor, a piezo-photronic sensor, a piezo-electro photronic sensor, an electro-optical sensor, an electro-thermal sensor, a bio-electrical sensor, a bio-marker sensor, a bio-chemical sensor, a chemical sensor, an ion emission sensor, a photo-detector, an x-ray sensor, a radiation material sensor, an electrical sensor, a voltage meter, a thermal sensor, a flow meter, or a piezo-meter.
In still some other embodiments, apparatus of this invention further include a biological interface, a system controller, a system for reclaiming or treatment medical waste. The reclaiming and treatment of medical waste can be performed by the same system or two different systems.
Another aspect of this invention provides apparatus for interacting with a cell, which include a device for sending a signal to the cell and optionally receiving a response to the signal from the cell.
In some embodiments, the interaction with the cell can be probing, detecting, sorting, communicating with, treating, or modifying with a coded signal that can be a thermal, optical, acoustical, biological, chemical, electro-mechanical, electro-chemical, electro-optical, bio-electro-optical, bio-thermal optical, electro-chemical optical, electro-chemical-mechanical, bio-chemical, bio-mechanical, bio-electro-mechanical, bio-electro-chemical, bio-electro-chemical-mechanical, electric, magnetic, electro-magnetic, physical, or mechanical signal, or a combination thereof.
In some other embodiments, the device or the sub-equipment unit contained in the apparatus can include multiple surfaces coated with one or more elements or combinations of elements, and a control system for releasing the elements. In some instances, the control system can cause release of the elements from the device surface via an energy including but not limited to thermal energy, optical energy, acoustic energy, electrical energy, electro-magnetic energy, magnetic energy, radiation energy, or mechanical energy in a controlled manner. The energy can be in the pulsed form at desired frequencies.
In some other embodiments, the device or the sub-equipment unit contained in the apparatus includes a first component for storing or releasing one element or a combination of elements onto the surface of the cell or into the cell; and a second component for controlling the release of the elements (e.g., a circuitry for controlling the release of the elements). The elements can be a biological component, a chemical compound, ions, catalysts, Ca, C, Cl, Co, Cu, H, I, Fe, Mg, Mn, N, O, P, F, K, Na, S, Zn, or a combination thereof. The signal, pulsed or constant, can be in the form of a released element or combination of elements, and it can be carried in a liquid solution, gas, or a combination thereof. In some instances, the signal can be at a frequency ranging from about 1×10−4 Hz to about 100 MHz or ranging from about 1×10−4 Hz to about 10 Hz, or at an oscillation concentration ranging from about 1.0 nmol/L to about 10.0 mmol/L. Also, the signal comprises the oscillation of a biological component, a chemical compound, Ca, C, Cl, Co, Cu, H, I, Fe, Mg, Mn, N, O, P, F, K, Na, S, Zn, or a combination thereof, e.g., at desired oscillating frequencies.
In some embodiments, the signal to be sent to the cell can be in the form of oscillating element, compound, or an oscillating density of a biological component, and a response to the signal from the cell is in the form of oscillating element, compound, or an oscillating density of a biological component.
In some embodiments, the device or the sub-equipment unit can be coated with a biological film, e.g., to enhance compatibility between the device and the cell.
In some other embodiments, the device or the sub-equipment unit can include components for generating a signal to be sent to the cell, receiving a response to the signal from the cell, analyzing the response, processing the response, and interfacing between the device and the cell.
Still another aspect of this invention provides devices or sub-equipment units each including a micro-filter, a shutter, a cell counter, a selector, a micro-surgical kit, a timer, and a data processing circuitry. The micro-filter can discriminate abnormal cells by a physical property (e.g., dimension, shape, or velocity), mechanical property, electric property, magnetic property, electro-magnetic, thermal property (e.g., temperature), optical property, acoustical property, biological property, chemical property, electro-chemical property, bio-chemical property, bio-electro-chemical property, bio-electro-mechanical property, or electro-mechanical property. The devices each can also include one or more micro-filters. Each of these micro-filters can be integrated with two cell counters, one of which is installed at the entrance of each filter well, while the other is installed at the exit of each filter well. The shape of the micro-filter's well is rectangle, ellipse, circle, or polygon; and the micro-filter's dimension ranges from about 0.1 μm to about 500 μm or from about 5 um to about 200 um. As used herein, the term “dimension” means the physical or feature size of the filter opening, e.g., diameter, length, width, or height. The filter can be coated with a biological or bio-compatible film, e.g., to enhance compatibility between the device and the cell.
In addition to separation of biological entity by its size and other physical features, the filter can also contain additional features and functions to perform biological entity separation via other properties, which comprise of mechanical property, electric property, magnetic property, electro-magnetic, thermal property (e.g., temperature), optical property, acoustical property, biological property, chemical property, electro-chemical property, bio-chemical property, bio-electro-chemical property, bio-electro-mechanical property, and electro-mechanical property.
In some embodiments of these devices, the shutter sandwiched by two filter membranes can be controlled by a timer (thus time shutter). The timer can be triggered by the cell counter. For instance, when a cell passes through the cell counter of the filter entrance, the clock is triggered to reset the shutter to default position, and moves at a preset speed towards the cell pathway, and the timer records the time as the cell passes through the cell counter at the exit.
Still a further aspect of this invention provides methods for fabricating a micro-device with micro-trench and probe embedded in the micro-trench's sidewalls. A micro-trench is an unclosed tunnel (see, e.g.,
In some embodiments, the method further includes coupling two devices or sub-equipment units that are thus fabricated and symmetric (i.e., a flipped mirror) to form a detecting device with channels. The entrance of each channel can be optionally bell-mouthed, e.g., such that the size of channel's opening end (the entrance) is larger than the channel's body, thereby making it easier for a cell to enter the channel. The shape of each channel's cross-section can be rectangle, ellipse, circle, or polygon. The micro-trenches of the coupled two micro-devices can be aligned by the module of alignment marks designed on the layout of the micro-device. The dimension of the micro-trench can range from about 0.1 um to about 500 um.
Alternatively, the method can also include covering the micro-trench of the micro-device with a flat panel. Such a panel can comprise or be made with silicon, SiGe, SiO2, Al2O3, quartz, low optical loss glasses, or other optical materials. Examples of other potentially suitable optical materials include acrylate polymer, AgInSbTe, synthetic alexandrite, arsenic triselenide, arsenic trisulfide, barium fluoride, CR-39, cadmium selenide, caesium cadmium chloride, calcite, calcium fluoride, chalcogenide glass, gallium phosphide, GeSbTe, germanium, germanium dioxide, glass code, hydrogen silsesquioxane, Iceland spar, liquid crystal, lithium fluoride, lumicera, METATOY, magnesium fluoride, agnesium oxide, negative index metamaterials, neutron supermirror, phosphor, picarin, poly(methyl methacrylate), polycarbonate, potassium bromide, sapphire, scotophor, spectralon, speculum metal, split-ring resonator, strontium fluoride, yttrium aluminum garnet, yttrium lithium fluoride, yttrium orthovanadate, ZBLAN, zinc selenide, and zinc sulfide.
In other embodiments, the method can further include integrating three or more sub-equipment units or devices thus fabricated to yield an enhanced device with an array of the channels.
Another aspect of this invention relates to a set of novel process flows for fabricating micro-devices (including micro-probes and micro-indentation probes) for their applications in disease detection by measuring microscopic properties of a biological sample. The micro-devices can be integrated into detection apparatus of this invention as sub-equipment units to measure one or more properties at microscopic levels. For example, a cancerous cell may have a different hardness (harder), density (denser), and elasticity than a normal cell.
Another aspect of this invention is to involve in cellular communications and regulate cellular decision or response (such as differentiation, dedifferentiation, cell division and cell death) with fabricated signals generated by the micro-devices disclosed herein. This could be further employed to detect and treat diseases.
Another aspect of the current application is that the inventive method or measured parameter in the method is a function of at least two levels F (level 1, level 2), where level 1 can be a biological entity such as protein and level 2 can be another biological entity such as genetics, where the measured signal strength of F (level 1, level 2) is greater than the sum of the signal containing only level 1 information f (level 1) and the signal containing only level 2 information f (level 2):
Signal strength of F (level 1, level 2)>signal strength off (level 1)+signal strength off (level 2)
The above novel feature and property can be extended to a measured parameter which is a function containing many levels F (level 1, level 2, level 3 level n). One novel and unobvious feature of this innovation is that the measured signal in a parameter containing multiple biological levels is synergistically enhanced over the measured signals with each signal containing a single biological level only. With this approach, the typically weak detection signal in disease detection such as cancer detection (especially in early stage cancer detection) can be effectively enhanced or magnified, making early disease detection possible and more effective.
To further enhance measurement capabilities, multiple micro-devices can be implemented into a piece of detection apparatus as sub-equipment units employing the time of flight technique, in which at least one probing micro-device and one sensing micro-device placed at a preset, known distance. The probing micro-device can apply a signal (e.g., a voltage, a charge, an electrical field, a laser beam, a thermal pulse, a train of ions, or an acoustic wave) to the biological sample to be measured, and the detection (sensing) micro-device can measure response from or of the biological sample after the sample has traveled a known distance and a desired period of time. For instance, a probing micro-device can apply an electrical charge to a cell first, and then a detection (sensing) micro-device subsequently measures the surface charge after a desired period of time (T) has lapsed and the cell has traveled a certain distance (L).
The micro-devices or the sub-equipment units contained in the apparatus of this invention can have a wide range of designs, structures, functionalities, flexibilities, and applications due to their diverse properties, high degree of flexibilities, and ability of integration, miniaturization, and manufacturing scalability. They include, e.g., a voltage comparator, a four point probe, a calculator, a logic circuitry, a memory unit, a micro cutter, a micro hammer, a micro shield, a micro dye, a micro pin, a micro knife, a micro needle, a micro thread holder, micro tweezers, a micro laser, a micro optical absorber, a micro mirror, a micro wheeler, a micro filter, a micro chopper, a micro shredder, micro pumps, a micro absorber, a micro signal detector, a micro driller, a micro sucker, a micro tester, a micro container, a signal transmitter, a signal generator, a friction sensor, an electrical charge sensor, a temperature sensor, a hardness detector, an acoustic wave generator, an optical wave generator, a heat generator, a micro refrigerator and a charge generator.
Further, it should be noted that advancements in manufacturing technologies have now made fabrications of a wide range of micro-devices and integration of various functions onto the same device highly feasible and cost effective. The typical human cell size is about 10 micron. Using state-of-the-art integrated circuit fabrication techniques, the minimum feature size defined on a micro-device can be as small as 0.1 micron or below. Thus, it is ideal to utilize the disclosed micro-devices for biological applications.
In terms of materials for the micro-devices in the apparatus of this invention, the general principle or consideration is the material's compatibility with a biological entity. Since the time in which a micro-device is in contact with a biological sample (e.g., a cell) may vary, depending on its intended application, a different material or a different combination of materials may be used to make the micro-device. In some special cases, the materials may dissolve in a given pH in a controlled manner and thus may be selected as an appropriate material. Other considerations include cost, simplicity, ease of use and practicality. With the significant advancements in micro fabrication technologies such as integrated circuit manufacturing technology, highly integrated devices with minimum feature size as small as 0.1 micron can now be made cost-effectively and commercially. One good example is the design and fabrication of micro electro mechanical devices (MEMS), which now are being used in a wide variety of applications in the electronics industry and beyond.
Good disease (cancer and non-cancer) detection results in terms of measurement sensitivity and specificity have been obtained on multiple types of cancer tested, demonstrating validity of the apparatus of this invention for improved ability to detect diseases (e.g., cancers), particularly in their early stages. The experimental results have also shown that multiple cancer types can be detected using the disclosed apparatus, which itself is an improvement over many existing detection apparatus.
Specifically, studies utilizing the apparatus of this invention have been carried out on multiple types of cancer and non-cancer diseases (including an inflammatory disease, diabetes, a lung disease, a heart disease, a liver disease, a gastric disease, a biliary disease, or a cardiovascular disease). In these studies, whole blood samples were used within 5 days after being obtained and/or properly transported/stored in a 0.5-20° C. refrigerated environment. The samples of the control group were obtained from healthy people confirmed by physical examinations with normal AFP and CEA values (in normal ranges).
CDA value is obtained from an algorithm using calculation based on tested values from the studies. CDA value increases with risks of diseases. In other words, the higher the CDA values, the higher the risks of diseases.
As the above tables show, the CDA values are higher for various diseases (mid 40s) than those of control (healthy) group (around 36). Statistical analysis of CDA values for those two groups shows that there was a statistically significant difference in CDA values between those two groups. Accordingly, the studies above show that the apparatus and methods of this invention were able to distinguish some major diseases from control group, with sensitivity and specificity likely higher than existing technologies.
Set forth below are several illustrations or examples of apparatus of this invention containing a class of innovative micro-devices that are integrated as sub-equipment units.
To enhance detection speed and sensitivity, a large number of micro-devices can be integrated into a single apparatus of this invention. Each micro-device can be a independent sub-equipment unit in the apparatus. To achieve the above requirements, the detection apparatus should be optimized with its surface area maximized to contact the biological sample and with large number of micro-devices integrated on the maximized surface.
Instead of measuring a single property of a biological subject for disease diagnosis, various micro-devices can be integrated into a detection apparatus to detect multiple properties. Various micro-devices can constitute different sub-equipment units.
As illustrated herein, it is desirable to optimize the detection apparatus design to maximize measurement surface area, since the greater the surface area, the greater number of micro-devices that can be placed on the detection apparatus to simultaneously measure the sample, thereby increasing detection speed and also minimizing the amount of sample needed for the test.
Yet another aspect of this invention relates to a set of novel fabrication process flows for making micro-devices or sub-equipment units for disease detection purposes. Thus, a micro-device with two probes capable of measuring a range of properties (including mechanical and electrical properties) of biological samples is fabricated, using the above novel fabrication process flow.
Detection apparatus integrated with micro-devices disclosed in this application is fully capable of detecting pre-chosen properties on a single cell, a single DNA, a single RNA, or an individual, small sized biological matter level. In another further aspect, the invention provides the design, integration, and fabrication process flow of micro-devices capable of making highly sensitive and advanced measurements on very weak signals in biological systems for disease detection under complicated environment with very weak signal and relatively high noise background. Those novel capabilities using the class of micro-devices disclosed in this invention for disease detection include but not limited to making dynamic measurements, real time measurements (such as time of flight measurements, and combination of using probe signal and detecting response signal), phase lock-in technique to reduce background noise, and 4-point probe techniques to measure very weak signals, and unique and novel probes to measure various electronic, electromagnetic and magnetic properties of biological samples at the single cell (e.g., a telomere of DNA or chromosome), single molecule (e.g., DNA, RNA, or protein), single biological subject (e.g., virus) level.
For example, in a time of flight approach to obtain dynamic information on the biological sample (e.g., a cell, a substructure of a cell, a DNA, a RNA, or a virus), a first micro-device is first used to send a signal to perturb the biological subject to be diagnosed, and then a second micro-device is employed to accurately measure the response from the biological subject. In one embodiment, the first micro-device and the second micro-device are positioned with a desired or pre-determined distance L apart, with a biological subject to be measured flowing from the first micro-device towards the second micro-device. When the biological subject passes the first micro-device, the first micro-device sends a signal to the passing biological subject, and then the second micro-device detects the response or retention of the perturbation signal on the biological subject. From the distance between the two micro-devices, time interval, the nature of perturbation by the first micro-device, and measured changes on the biological subject during the time of flight, microscopic and dynamic properties of the biological subject can be obtained. In another embodiment, a first micro-device is used to probe the biological subject by applying a signal (e.g., an electronic charge) and the response from the biological subject is detected by a second micro-device as a function of time.
To further increase detection sensitivity, a novel detection process for disease detection is used, in which time of flight technique is employed.
The utilization of micro-devices (e.g., made by using the fabrication process flows of this invention) as discussed above and illustrated in
In addition to the above examples in measuring electrical properties (e.g., charge, electronic states, electronic charge, electronic cloud distribution, electrical field, current, and electrical potential, and impedance), mechanical properties (e.g., hardness, density, shear strength, and fracture strength) and chemical properties (e.g., pH) in a single cell, and in
One of the key aspects of this invention is the design and fabrication process flows of micro-devices and methods of use the micro-devices for catching and/or measuring biological subjects (e.g., cells, cell substructures, DNA, and RNA) at microscopic levels and in three dimensional space, in which the micro-devices have micro-probes arranged in three dimensional manner with feature sizes as small as a cell, DNA, or RNA, and capable of trapping, sorting, probing, measuring, and modifying biological subjects. Such micro-devices can be fabricated using state-of-the-art microelectronics processing techniques such as those used in fabricating integrated circuits. Using thin film deposition technologies such as molecular epitaxy beam (MEB) and atomic layer deposition (ALD), film thickness as thin as a few monolayers can be achieved (e.g., 4 A to 10 A). Further, using electron beam or x-ray lithography, device feature size on the order of nanometers can be obtained, making micro-device capable of trapping, probing, measuring, and modifying a biological subject (e.g., a single cell, a single DNA or RNA molecule) possible.
Another aspect of this invention relates to micro-indentation probes and micro-probes for measuring a range of physical properties (such as mechanical properties) of biological subjects. Examples of the mechanical properties include hardness, shear strength, elongation strength, fracture stress, and other properties related to cell membrane which is believed to be a critical component in disease diagnosis.
Another novel approach provided by this invention is the use of phase lock-in measurement for disease detection, which reduces background noise and effectively enhances signal to noise ratio. Generally, in this measurement approach, a periodic signal is used to probe the biological sample and response coherent to the frequency of this periodic probe signal is detected and amplified, while other signals not coherent to the frequency of the probe signal is filtered out, which thereby effectively reduces background noise. In one of the embodiments in this invention, a probing micro-device can send a periodic probe signal (e.g., a pulsed laser team, a pulsed thermal wave, or an alternating electrical field) to a biological subject, response to the probe signal by the biological subject can be detected by a detecting micro-device. The phase lock-in technique can be used to filter out unwanted noise and enhance the response signal which is synchronized to the frequency of the probe signal. The following two examples illustrate the novel features of time of flight detection arrangement in combination with phase lock-in detection technique to enhance weak signal and therefore detection sensitivity in disease detection measurements.
To illustrate how a micro-device can be used to simulate an intracellular signal, calcium oscillation is taken as an example mechanism. First, a Ca2+-release-activated channel (CRAC) has to be opened to its maximal extent, which could be achieved by various approaches. In an example of the applicable approaches, a biochemical material (e.g., thapsigargin) stored in the cartridge 924 is released by an injector 925 to the cell, and the CRAC will open at the stimulus of the biological subject. In another example of the applicable approaches, the injector 924 forces a specific voltage on cell membrane, which causes the CRAC to open as well.
The Ca2+ concentration of a solution in the injector 928 can be regulated as it is a desirable combination of a Ca2+-containing solution 926, and a Ca2+ free solution 927. While the injector 930 contains a Ca2+ free solution, then injectors 928 and 930 are alternately switched on and off at a desired frequency. As such, the Ca2+ oscillation is achieved and the content inside the cell membrane are then exposed to a Ca2+ oscillation. Consequently, the cell's activities or fate is being manipulated by the regulated signal generated by the apparatus.
Meanwhile, the cell's response (e.g., in the form of a thermal, optical, acoustical, mechanical, electrical, magnetic, electromagnetic property, or a combination thereof) can be monitored and recorded by the probes integrated in this apparatus.
As surface charge will affect the shape of a biological subject, by using novel and multiple plates, information on the shape and charge distribution of biological subjects can be obtained. The general principle and design of the micro-device can be extended to a broader scope, thereby making it possible to obtain other information on the biological subject via separation by applying other parameters such as ion gradient, thermal gradient, optical beam, or another form of energy.
Alternatively, a probe 1020 can be designed to trigger optical emission such as florescence light emission 1043 in the targeted biological subject such as diseased cells, which can then be detected by an optical probe 1032 as illustrated in
The channel included in the apparatus of this invention can have a width of, e.g., from 1 nm to 1 mm. The apparatus should have at least one inlet channel and at least two outlet channels.
The biological subject 2501 flows in the x direction from the entrance channel 2510 to the accelerating chamber 2530. A bio-compatible fluid 2502 flows from disturbing fluid channel 2520 to the accelerating chamber 2530, it then accelerates the biological subject 2501 in the y-direction. The acceleration correlates with the radius of the biological subject and the larger ones are less accelerated than the smaller ones. Then, the larger and smaller subjects are separated into different selecting channels. Meanwhile, probes can be optionally assembled on the sidewalls of the channels 2510, 2520, 2530, 2540, and 2550. The probes could detect, at the microscopic level, electrical, magnetic, electromagnetic, thermal, optical, acoustical, biological, chemical, biochemical, electro-mechanical, electro-chemical, electro-chemical-mechanical, physical, mechanical properties, or combinations thereof.
Probe 3112 is a fine probing device which is coated by a piezo-electrical material. There is a distance ΔL between probe 3111 and probe 3112.
When the biological subjects are tested when getting through 3111, if the entity is identified to be a suspected abnormal one, the system would trigger the piezo-electrical probe 3112 to stretch into the channel and probe particular properties after a time delay of Δt. And probe 3112 retracts after the suspected entity passed through.
The probing device is capable of measuring at the microscopic level an electrical, magnetic, electromagnetic, thermal, optical, acoustical, biological, chemical, electro-mechanical, electro-chemical, electro-chemical-mechanical, bio-chemical, bio-mechanical, bio-electro-mechanical, bio-electro-chemical, bio-electro-chemical-mechanical, physical or mechanical property, or a combination thereof, of the biological subject.
The width of the micro-channel can range from about 1 nm to about 1 mm.
When a biological subject is tested while getting through 3211, if it is normal, the valve 3221 of the flush channel is open, while the detection channel valve 3222 is closed, the biological subject is flushed out without a time-consuming fine detection.
When the biological subject is tested while getting through 3211, if it is suspected to be abnormal or diseased, the valve 3221 of the flush channel is closed, while the detection channel valve 3222 is open, the biological subject is conducted to the detection channel for a more particular probing.
The width of the micro-channel can range from about 1 nm to about 1 mm.
The probing device is capable of measuring at the microscopic level an electrical, magnetic, electromagnetic, thermal, optical, acoustical, biological, chemical, electro-mechanical, electro-chemical, electro-chemical-mechanical, bio-chemical, bio-mechanical, bio-electro-mechanical, bio-electro-chemical, bio-electro-chemical-mechanical, physical or mechanical property, or a combination thereof, of the biological subject.
The probing device is capable of measuring at the microscopic level an electrical, magnetic, electromagnetic, thermal, optical, acoustical, biological, chemical, electro-mechanical, electro-chemical, electro-chemical-mechanical, bio-chemical, bio-mechanical, bio-electro-mechanical, bio-electro-chemical, bio-electro-chemical-mechanical, physical or mechanical property, or a combination thereof, of the biological subject.
As illustrated in
In
Like
To effectively sorting, separating, screening, probing, or detecting of diseased biological entities, a chamber (or chambers) integrated with various channels can be deployed as shown
To significantly speed up the sorting, screening, probing and detection operations using the disclosed device and process, a high number of desired structures such as those discussed in
Tests were carried out in the laboratory with the apparatus of this invention on certain cancerous tissue samples (with multiple samples for each type of cancer) although the apparatus of this invention can be used for detection of other types of cancer or other types of treatment. In the tests, healthy control samples were obtained from animals with no known cancer disease at the time of collection and no history of malignant disease. Both cancerous samples and healthy control samples were collected and cultured in the same type of culture solution. The cultured samples were then mixed with a dilution buffer and diluted to the same concentration. The diluted samples were maintained at the room temperature for different time intervals and processed within a maximum of 6 hours after being recovered. The diluted samples were tested at the room temperature (2023° C.) and in the humidity of 30%-40%. The samples were tested with an apparatus of this invention under the same conditions and stimulated by the same pulse signal.
The tests show that, in general, the control groups' tested (measured) values (i.e., measured values in relative units for the testing parameter) were lower than the cancerous or diseased groups. Under the same stimulation (in terms of stimulation type and level) with a stimulating or probing signal applied by a probing unit of the tested apparatus of this invention, the difference shown in the measured values between the control groups and the cancerous groups became much more significant, e.g., ranging from 1.5 times to almost 8 times in terms of level of increase in such difference, compared with that without simulation. In other words, the cancerous groups' response to the stimulating signal was much higher than that of the control groups. Thus, the apparatus of this invention have been proven to be able to significantly enhance the relative sensitivity and specificity in the detection and measurement of diseased cells, in comparison to the control or healthy cells.
Further, the test results show that in terms of the novel parameter utilized by the apparatus of this invention, the cancerous group and the control group showed significantly different response. Such difference is significantly greater than the measurement noise. There was a large window to separate the control groups from the cancerous groups, showing a high degree of sensitivity of the novel measurement method and apparatus.
Compared with the traditional technology, signal and information collected by the apparatus and methods of this invention is linearly and can even be non-linearly amplified; and additional two-factor and three-factor (or higher order) interactions between various levels (cellular, protein, molecular or other levels) and components/parameters (exemplified in the following table) are not just novel, unique, but also exhibited unexpected reliable and sensitive results when compared to the traditional technology.
Studies were also undertaken to examine the effect of adding molecular level reaction triggering agent on the efficacy of the apparatus and methods for detecting disease of this invention. The results provided in
The apparatus and methods of this invention has been used in test of more than 20 different types of cancer in all stages of development and showed expectedly high sensitivity and specificity.
While for the purposes of demonstration and illustration, the above cited novel, detailed examples show how microelectronics and/or nano-fabrication techniques and associated process flows can be utilized to fabricate highly sensitive, multi-functional, powerful, and miniaturized detection devices, the principle and general approaches of employing microelectronics and nano-fabrication technologies in the design and fabrication of high performance detection devices have been contemplated and taught, which can and should be expanded to various combination of fabrication processes including but not limited to thin film deposition, patterning (lithography and etch), planarization (including chemical mechanical polishing), ion implantation, diffusion, cleaning, various materials, combination of processes and steps, and various process sequences and flows. For example, in alternative detection device design and fabrication process flows, the number of materials involved can be fewer than or exceed four materials (which have been utilized in the above example), and the number of process steps can be fewer or more than those demonstrated process sequences, depending on specific needs and performance targets. For example, in some disease detection applications, a fifth material such as a biomaterial-based thin film can be used to coat a metal detection tip to enhance contact between the detection tip and a biological subject being measured, thereby improving measurement sensitivity.
Applications for the detection apparatus and methods of this invention include detection of diseases (e.g., in their early stage), particularly for serious diseases like cancer. Since cancer cell and normal cell differ in a number of ways including differences in possible microscopic properties such as electrical potential, surface charge, density, adhesion, and pH, novel micro-devices disclosed herein are capable of detecting these differences and therefore applicable for enhanced capability to detect diseases (e.g., for cancer), particularly in their early stage. In addition micro-devices for measuring electrical potential and electrical charge parameters, micro-devices capable of carrying out mechanical property measurements (e.g., density) can also be fabricated and used as disclosed herein. In mechanical property measurement for early stage disease detection, the focus will be on the mechanical properties that likely differentiate disease or cancerous cells from normal cell. As an example, one can differentiate cancerous cells from normal cells by using a detection apparatus of this invention that is integrated with micro-devices capable of carrying out micro-indentation measurements.
Although specific embodiments of this invention have been illustrated herein, it will be appreciated by those skilled in the art that any modifications and variations can be made without departing from the spirit of the invention. The examples and illustrations above are not intended to limit the scope of this invention. Any combination of detection apparatus, micro-devices, fabrication processes, and applications of this invention, along with any obvious their extension or analogs, are within the scope of this invention. Further, it is intended that this invention encompass any arrangement, which is calculated to achieve that same purpose, and all such variations and modifications as fall within the scope of the appended claims.
All publications or patent applications referred to above are incorporated herein by reference in their entireties. All the features disclosed in this specification (including any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example of a generic series of equivalent or similar features.
This application claims priority to U.S. Application No. 62/470,181, filed on Mar. 10, 2017, U.S. Application No. 62/627,481, filed on Feb. 7, 2018, and U.S. Application No. 62/635,866, filed Feb. 27, 2018, the contents of which are incorporated by reference in their entirety.
| Number | Date | Country | |
|---|---|---|---|
| 62635866 | Feb 2018 | US | |
| 62627481 | Feb 2018 | US | |
| 62470181 | Mar 2017 | US |
