The present disclosure is directed to a detection kiosk that provides fast and accurate pathogen identification obtained from human samples to allow for rapid results. Such identification information can be used in a variety of environments for public health safety decision-making about the subject being tested. The detection kiosk can be linked to public health databases and, through adaptive learning such databases can analyze the received information to provide immediate enhanced test results that can be used, for example, at airport and border security locations so that processing times for such populations are not disrupted. The kiosk system addresses the need for enhanced, rapid, and accurate health screening.
Medical imaging technology and diagnostic systems continue to improve with the goal of providing health-safety solutions to the public. The public health benefits derived from these technical and analytical software advancements are very beneficial, potentially saving significant amounts of time and money, and can add efficiencies to large scale examination and testing protocols. However, along with these advancements have come additional challenges, including the reliability of results, the speed of reporting and the uniformity of the created data, all of which are exacerbated by the complexity and the degree of inter-connection among the public safety, medical, and health-care industry systems.
The pandemic of 2020 has brought to the fore the question of how to protect the health of nations without restricting free movement of healthy individuals, but with the security and surety of a uniform, rapid and accurate testing and reporting system. The collection of “good data” has been cited as a matter of concern within the medical community; the quality of collected data is of primary importance in making informed decisions about public health policy and border security.
Current industry solutions tend to rely on conventional methods that typically employ imperfect testing kits and laboratory analysis, where the results can often be incorrect in as high as 60% of the test results. A Rutgers University press release of May 2020 repots that saliva tests are being touted as a solution for mass screenings.
The Gold Standard test for SARS viruses is not a rapid test and requires a laboratory to carry testing out. It is a highly technical process that requires the right machine, facilities and a proper safety infrastructure, such as may be found in a biosafety-level laboratory. An alternative method disease diagnosis and screening, using imaging for a rapid diagnosis, led by Pratik Shah et al of MIT and reported in an online press release in 2020, applies adaptive learning algorithms for medical imaging. Adaptive learning and image capture are being used with much success in China and the United States in the radiology, pathology, and ophthalmology fields, among others.
Test kits for pathogens are only one step of a health passport concept, and they are cumbersome, can be contaminated, misused, or expired, and can create labor intensive situations, especially in high-volume environments, such as homeland security venues and for use in the travel and airline industries. The results must be manually entered into a database and recorded by TSA or other reliable personnel, other than the person being tested.
Current industry methods and standards for border security do not include solutions for the need of secure big data capture of virus and other pathogen screenings in real time and the logistics for mass screenings, especially when airports, border checkpoints and other portals are operating at high capacity.
Current Industry standards for virus analysis and screening are mostly limited to a specific virus test, using chemical analysis and/or imaging after sample preparation. Recent advancements with nanotechnology promise more rapid analysis and more rugged platforms for virus testing.
An example embodiment provides a free-standing apparatus for acquisition and analysis of a biological sample from an individual. The apparatus includes: means for receipt of identifying data of the individual; means for receiving the biological sample for the individual; means for providing a unique identifier for the biological sample and association with the individual; and means for conducting an analysis of the biological sample and generating a report of analysis results; wherein all of the foregoing means are under control of a microprocessor located in the apparatus.
Another example embodiment provides a method for acquisition and analysis of a biological sample from an individual. The method includes operations of: receiving identifying data of the individual; receiving the biological sample for the individual; providing a unique identifier for the biological sample and association with the individual; and conducting an analysis of the biological sample and generating a report of analysis results.
Aspects of the present disclosure may be appreciated upon consideration of the following description of exemplary embodiments when taken in conjunction with the accompanying drawings.
The present disclosure is directed to a self-serve automated apparatus, including devices and kiosk embodiments, that can be employed in a variety of settings, such as airports, for testing individuals prior to immigration or boarding; in hospitals in conjunction with both patient admitting and visitor clearance; as well as in schools and other facilities requiring fast and accurate pathogen screenings for large numbers of people. Using adaptive learning and a remote database, the present disclosure can quickly analyze a sample and provide a real time report, allowing the individual being tested to receive an accurate and complete health check while the results of the test are stored in the database for subsequent authorized use and retrieval as may be needed.
The present disclosure provides an apparatus which may be in the form of a free-standing kiosk, allowing fast processing of samples. Such kiosks may be located in high traffic environments, such as airports or entertainment venues, where the analysis of many samples must be performed rapidly. The apparatus and method have high-assurance for tracking and indexing.
The present disclosure comprises a kiosk collection apparatus that is intended to provide onsite accurate pathogen testing by the analysis of human-derived samples, and includes means for identifying and documenting the individual to be tested; means for drawing samples pursuant to a collection protocol including sample verification; and on-site analysis of the sample. The analysis can be performed through microprocessor control at the kiosk or the raw data can be forwarded to an off-site recipient for analysis and return of results.
The kiosk may also include a self-contained cleaning system to sterilize the sample collection chamber in the kiosk after a sample is collected, permitting the next test to commence within minutes. Collection means for the sample, such as an internal bin, may be provided to collect the tested samples with safety, and may include appropriate waste sterilization compartments.
To prevent unauthorized operation of the kiosk, the operator is provided with an access or identification card, which must be inserted into the card slot 4 to operate the kiosk. This ensures that a test is performed only by an authorized agent. In alternate embodiments, the kiosk can integrate various commercially-available mechanisms for recording and confirming the identity of the agent. The agent can also be validated through use of the biometric interfaces.
In contemplated alternative embodiments, the system can establish the identify of an individual physically present in proximity to the kiosk by scanning the individual's passport or other official identification through a reader/scanner, either as a separate interface (not shown) or incorporating such functionality into the video camera 2. Further confirmation of the individual's identity as matching the individual on scanned document may be performed through other biometric characteristics. The kiosk can provide audio instructions by audio output and video instructions, prompted on touch-screen display 1, and can provide the individual with instructions as needed. All such functions may be under the control of the system kiosk's main microprocessor, suitably programmed as known in the art. The individual can also enter information through the touch-screen.
With the identity of the individual being confirmed, a microprocessor-controlled analysis system in the kiosk analyzes the sample. The analysis system may include a high definition microscopy component camera system with analytical software for imaging analysis and labeling. The kiosk bundles the analysis results with both the identification on the authorized agent and the individual tested and transmits the data to a remote electronic data storage facility. The data processing modules employed provide for encoding and privatization of all data. Such data processing modules may provide random research identifiers and encode private individual data into private electronic data storage encrypted at multiple levels. In some instances, the data delivered into remote data storage, which may be cloud-based, can be de-identified and privatized so that the results of the analysis, but not the individual associated with the results, is stored. This may allow bulk analysis of results, such as to measure trends and identify potential “hot spot” areas, without endangering the privacy of the tested individuals. After the analysis at the kiosk and transmission of the data to the remote server(s), the data is automatically purged from the kiosk's memory; it never remains on the kiosk device.
Depending on the nature of the pathogen to be identified and the sophistication of the analysis software, the analysis may be conducted at the kiosk under microprocessor control, with communication to remote databases as needed. Alternatively, the raw test data may be transmitted to a remote facility for analysis, with the results transmitted back to the kiosk. In either case, upon completion of the analysis a report is provided to the kiosk operator and, if proper, shared with the individual tested. Depending on the results, the individual may be cleared for passage or otherwise advised or directed to seek treatment or other processing.
As presented in
The actual samples to be analyzed may be received by individual cartridges arrayed in a multi-cartridge feeder or carrier at 208. A single cartridge receives a specific sample, and delivers it into the sterilized transfer chamber at 210. An electronic record is created of the sample identification and other information to create an appropriate chain-of-custody record at 212.
The sample material received from the individual is placed on a media cartridge at 214. The cartridge subsequently passes into a plurality of chambers, where it is exposed to various fixing and analysis procedures as appropriate to the analysis desired illustrated at 216-220. Such procedures may also include sample sterilization and de-contamination.
Other techniques for analysis of the specimen on the capture material may include fluorescent photographic electronic sensors, optionally with magnifying and filtering lenses. Such sensors can record colors, heat, intensity, and size variations produced by the chemical reactions within the media substrate material, providing additional data to assist the sample analysis.
The specimen capture media may advantageously be of a translucent media to facilitate the acquisition of microphotographic recordings, allowing multiple captures are performed as an analysis is performed. Such captures may employ variations in the applied light spectrum to capture unique multiple chromatic recordings of the media. As may be appropriate, temperature adjustment may be performed while recording, whereby the temperature variations are recorded and combined with resulting visual recording.
As illustrated, a media cartridge is loaded for sample receipt at 500. It is assigned an individual identifier at 502 and a reference photograph of the cartridge is taken at 504 and associated with the identification data set assigned at 506. The sample to be received by the cartridge is received and verified at 508, and is transferred to the cartridge at 510. A photographic record of the transfer cartridge is created for audit tracking and recording at 512.
The cartridge with sample then proceeds to an acquisition chamber for commencement of the analysis procedure at 514, during which analysis photographic and other records are created to document the analysis at 516, along with a timestamp and other data to document the cartridge location and analysis performed at 518.
Elf the validation is successful the individual is prompted for a face photograph at 612, and the photo is taken and acquired by the system at 614. Again, the photo is compared to another photograph of the individual, such as a passport photo, and with verification success confirmed at 616, recording of the identification procedure is authorized at 620 and recordation performed at 622, with the information added to the serialized record for the media cartridge to be used for sample collection. If the photographic validation fails, an exception issues at 618 for re-test or other appropriate action.
In some situations, some sensitive identifiers may remain in a scrubbed record, depending on the nature of the recipient for the information. For example, medical or hospital personnel having a relationship with the individual tested may be granted access by the individual to receive the results of a test for entry into the individual's personal medical record. Information regarding such authorized access by be provided by the individual during an initial “interview” when the individual's identity is entered into and recorded by the kiosk.
The present system allows integration of sample analysis and data collection by a kiosk or other testing station to be both maintained by the kiosk as well as passed to other facilities for review and correlation with data for the tested individual obtained from other authorized sources, as well as with a virus library or libraries with adaptive learning capabilities such that an accurate result of the test can be determined and the libraries themselves can be updated with the results of the test. The results of the analysis can is transmitted back to the kiosk for use by the agent and individual being tested.
With adaptive learning and predictive analysis matched against the libraries, the kiosk can differentiate among a negative pathogen sample test; a positive pathogen sample test; and an unknown pathogen sample. The latter two results can provide grounds for further examinations and potential refusal of passage and isolation.
In addition to use at airports and similar travel locations and hospitals, the kiosk system can be used in a variety of venues where a large number of people needed to be checked quickly and accurately, such as sports venues and large social gatherings.
Similar to the above free-standing apparatus for acquisition and analysis of a biological sample from an individual, the present disclosure also provides a method for acquisition and analysis of a biological sample from an individual. The method may include operations of: receiving identifying data of the individual; receiving the biological sample for the individual; providing a unique identifier for the biological sample and association with the individual; and conducting an analysis of the biological sample and generating a report of analysis results.
In some embodiment, all of the foregoing operations are under control of a microprocessor located in a free-standing apparatus.
In some embodiment, the operation of receiving identifying data uses at least one of a camera, a scanner, a monitor and a speaker/microphone combination.
In some embodiment, the method further includes an operation of verifying the identity of an operator so that the operator can control of the free-standing apparatus with respect to an acquisition of the biological sample.
In some embodiment, the operation of receiving identifying data uses: an interface for prompting name and identification information of the individual; with user interfaces in plurality; verbal guidance means for general instructions to the individual; and means for visual guidance through a monitor.
In some embodiment, the method further includes an operation of storing the analysis report, whereby each report receives an individual and identification number.
In some embodiment, the method further includes an operation of sanitizing the biological sample after analysis.
In some embodiment, the method further includes an operation of editing the report to delete specifically-identified information, and an operation of transmitting both the report and the edited report to remote facilities, either for analysis or storage.
In some embodiment, the operation of conducting an analysis uses components located at least in the free-standing apparatus or at a remote location.
In some embodiment, the operation of receiving identifying data includes: establishing contact with the individual by issuing a prompt for the individual's name; capturing the individual's response; concatenating with a datastore to validate the identity of the individual; prompting the individual for a face photograph to take and acquire the photograph; comparing the photograph to another photograph of the individual; authorizing recording of the identification procedure and performing recordation; and adding information to a serialized record for a media cartridge to be used for sample collection.
In some embodiment, the operation of receiving the biological sample includes: receiving a sample specimen on an input tray; moving the input tray into a transfer chamber; receiving actual samples to be analyzed by individual cartridges arrayed in a multi-cartridge feeder, wherein a single cartridge receives a specific sample, and delivers it into a sterilized transfer chamber; creating an electronic record of the sample identification and other information to create an appropriate chain-of-custody record; placing sample material received from the individual on a media cartridge, wherein the media cartridge subsequently passes into a plurality of chambers, where it is exposed to various fixing and analysis procedures as appropriate to the analysis desired.
In some embodiment, the operation of providing a unique identifier includes: loading a media cartridge for the sample; assigning an individual identifier or the media cartridge; taking a reference photograph of the media cartridge; associating the reference photograph with the identification data set; transferring the sample to the media cartridge; creating a photographic record of the transfer cartridge for audit tracking and recording; and proceeding the cartridge with sample to an acquisition chamber for commencement of the operation of conducting an analysis, during which analysis photographic and other records are created to document the analysis, along with a timestamp and other data to document the cartridge location and analysis.
Number | Date | Country | Kind |
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63088526 | Oct 2020 | US | national |
This application claims the benefit of U.S. application No. 63/088,526, filed on Oct. 7, 2020. The entire disclosure of the above-referenced application is incorporated herein by reference in entirety for all purpose.
Number | Date | Country | |
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Parent | PCT/IB2021/059155 | Oct 2021 | US |
Child | 18296384 | US |