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358 results on '"Voldman, Joel"'

1. Learning and DiSentangling Patient Static Information from Time-series Electronic HEalth Record (STEER)

Author

Liao, Wei and Voldman, Joel

Subjects
Computer Science - Machine Learning, Computer Science - Computers and Society
Abstract

Recent work in machine learning for healthcare has raised concerns about patient privacy and algorithmic fairness. For example, previous work has shown that patient self-reported race can be predicted from medical data that does not explicitly contain racial information. However, the extent of data identification is unknown, and we lack ways to develop models whose outcomes are minimally affected by such information. Here we systematically investigated the ability of time-series electronic health record data to predict patient static information. We found that not only the raw time-series data, but also learned representations from machine learning models, can be trained to predict a variety of static information with area under the receiver operating characteristic curve as high as 0.851 for biological sex, 0.869 for binarized age and 0.810 for self-reported race. Such high predictive performance can be extended to a wide range of comorbidity factors and exists even when the model was trained for different tasks, using different cohorts, using different model architectures and databases. Given the privacy and fairness concerns these findings pose, we develop a variational autoencoder-based approach that learns a structured latent space to disentangle patient-sensitive attributes from time-series data. Our work thoroughly investigates the ability of machine learning models to encode patient static information from time-series electronic health records and introduces a general approach to protect patient-sensitive attribute information for downstream tasks.

Published
2023

3. A Multidatabase ExTRaction PipEline (METRE) for Facile Cross Validation in Critical Care Research

Author

Liao, Wei and Voldman, Joel

Subjects
Computer Science - Databases
Abstract

Transforming raw EHR data into machine learning model-ready inputs requires considerable effort. One widely used EHR database is Medical Information Mart for Intensive Care (MIMIC). Prior work on MIMIC-III cannot query the updated and improved MIMIC-IV version. Besides, the need to use multicenter datasets further highlights the challenge of EHR data extraction. Therefore, we developed an extraction pipeline that works on both MIMIC-IV and eICU Collaborative Research Database and allows for model cross validation using these 2 databases. Under the default choices, the pipeline extracted 38766 and 126448 ICU records for MIMIC-IV and eICU, respectively. Using the extracted time-dependent variables, we compared the Area Under the Curve (AUC) performance with prior works on clinically relevant tasks such as in-hospital mortality prediction. METRE achieved comparable performance with AUC 0.723- 0.888 across all tasks. Additionally, when we evaluated the model directly on MIMIC-IV data using a model trained on eICU, we observed that the AUC change can be as small as +0.019 or -0.015. Our open-source pipeline transforms MIMIC-IV and eICU into structured data frames and allows researchers to perform model training and testing using data collected from different institutions, which is of critical importance for model deployment under clinical contexts.

Published
2023
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6. Microfluidic tools for assaying immune cell function

Author

Voldman, Joel

Subjects
Physics - Fluid Dynamics, Quantitative Biology - Other Quantitative Biology
Abstract

Joel Voldman is a professor in the Electrical Engineering and Computer Science Department at MIT. Here he describes his labs efforts to develop microfluidic devices for cell manipulation and analysis., Comment: Nobel Symposium 162, Stockholm, Sweden, 2017 arXiv:1712.08369v1 report-id: Nobel162/2017/25

Published
2018

16. A sample-to-answer electrochemical biosensor system for biomarker detection

Author

Kikkeri, Kruthika, Wu, Dan, Voldman, Joel, Kikkeri, Kruthika, Wu, Dan, and Voldman, Joel

Abstract

We interfaced with a painless blood collection device and integrated on-chip blood-to-plasma separation with an electronic bead-based biomarker detection assay to enable true sample-to-answer detection of biomarkers.

Published
2022

17. A sample-to-answer electrochemical biosensor system for biomarker detection

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Kikkeri, Kruthika, Wu, Dan, Voldman, Joel, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Kikkeri, Kruthika, Wu, Dan, and Voldman, Joel

Abstract

We interfaced with a painless blood collection device and integrated on-chip blood-to-plasma separation with an electronic bead-based biomarker detection assay to enable true sample-to-answer detection of biomarkers.

Published
2022

19. Inflammation resolution circuits are uncoupled in acute sepsis and correlate with clinical severity

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Jundi, Bakr, Lee, Do-Hyun, Jeon, Hyungkook, Duvall, Melody G, Nijmeh, Julie, Abdulnour, Raja-Elie E, Pinilla-Vera, Mayra, Baron, Rebecca M, Han, Jongyoon, Voldman, Joel, Levy, Bruce D, Massachusetts Institute of Technology. Research Laboratory of Electronics, Jundi, Bakr, Lee, Do-Hyun, Jeon, Hyungkook, Duvall, Melody G, Nijmeh, Julie, Abdulnour, Raja-Elie E, Pinilla-Vera, Mayra, Baron, Rebecca M, Han, Jongyoon, Voldman, Joel, and Levy, Bruce D

Abstract

Sepsis is a critical illness characterized by dysregulated inflammatory responses lacking counter-regulation. Specialized proresolving mediators are agonists for antiinflammation and for promoting resolution, and they are protective in preclinical sepsis models. Here, in human sepsis, we mapped resolution circuits for the specialized proresolving mediators resolvin D1 and resolvin D2 in peripheral blood neutrophils and monocytes, their regulation of leukocyte activation and function ex vivo, and their relationships to measures of clinical severity. Neutrophils and monocytes were isolated from healthy subjects and patients with sepsis by inertial microfluidics and resolvin D1 and resolvin D2 receptor expression determined by flow cytometry. The impact of these resolvins on leukocyte activation was determined by isodielectric separation and leukocyte function by stimulated phagolysosome formation. Leukocyte proresolving receptor expression was significantly higher in sepsis. In nanomolar concentrations, resolvin D1 and resolvin D2 partially reversed sepsis-induced changes in leukocyte activation and function. Principal component analyses of leukocyte resolvin receptor expression and responses differentiated sepsis from health and were associated with measures of sepsis severity. These findings indicate that resolvin D1 and resolvin D2 signaling for antiinflammation and resolution are uncoupled from leukocyte activation in early sepsis and suggest that indicators of diminished resolution signaling correlate with clinical disease severity.

Published
2022

28. Particle Capture Devices and Methods of Use Thereof

Author

Voldman, Joel, Skelley, Alison M, Kirak, Oktay, and Jaenisch, Rudolf

Subjects
Instrumentation And Photography, Fluid Mechanics And Thermodynamics
Abstract

The present invention provides a device and methods of use thereof in microscale particle capturing and particle pairing. This invention provides particle patterning device, which mechanically traps individual particles within first chambers of capture units, transfer the particles to second chambers of opposing capture units, and traps a second type of particle in the same second chamber. The device and methods allow for high yield assaying of trapped cells, high yield fusion of trapped, paired cells, for controlled binding of particles to cells and for specific chemical reactions between particle interfaces and particle contents. The device and method provide means of identification of the particle population and a facile route to particle collection.

Published
2015

32. An integrated and automated electronic system for point-of-care protein testing

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Wu, Dan, Voldman, Joel, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Wu, Dan, and Voldman, Joel

Abstract

© 2019 IEEE. Protein testing in blood is important for clinical analysis. Traditional blood tests are performed in centralized laboratories and are slow to provide results. In contrast, point-of-care devices deliver rapid results in non-laboratory settings, allowing timely analysis and in turn reducing healthcare costs. Successful point-of-care platforms require seamless integration of chemical assays, fluid management and signal readout. In this regard, we present an integrated, compact and automated electronic system for point-of-care protein sensing. The system comprises of a microfluidics-based electrochemical biosensor, amperometry circuitry and automated microfluidic fluid handling circuitry. This platform utilizes magnetic microbeads to expedite an electronic enzyme-linked immunosorbent assay, and microfluidics to manage small volumes and automate assay operations. A commercial single-chip potentiostat is utilized for amperometry measurements and microfluidics control. Using this all-electrical system, we demonstrate an integrated and automated assay for human interleukin-6.

Published
2021

33. Multi-frequency dielectrophoretic characterization of single cells

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Jaffe, Alex, Voldman, Joel, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Jaffe, Alex, and Voldman, Joel

Abstract

© 2018, The Author(s). We explore the use of dielectrophoresis to discern the electrical properties of single cells by observing them at multiple frequencies. We first simulate experimental conditions to show that as we increase the number of measured frequencies, we are able to better discriminate among different cells. Furthermore, we use the simulation to find the optimal number and value of frequencies to use to best discriminate among different cells in general. We then fabricate a microfluidic device, calibrate it with polystyrene beads, and characterize it with BA/F3 cells. With this device, we test three different activation levels of HL60 cells treated with cytochalasin D using the optimal frequency sequence obtained in simulation to determine the differences in discrimination abilities depending on the number of frequencies used. We quantify the discrimination abilities of the optimal one, two, and three frequencies by minimizing 0-1 loss.

Published
2021

34. Microfluidics in structured multimaterial fibers

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Yuan, Rodger, Lee, Jaemyon, Su, Hao-Wei, Levy, Etgar Claude, Khudiyev, Tural, Voldman, Joel, Fink, Yoel, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Yuan, Rodger, Lee, Jaemyon, Su, Hao-Wei, Levy, Etgar Claude, Khudiyev, Tural, Voldman, Joel, and Fink, Yoel

Abstract

Traditional fabrication techniques for microfluidic devices utilize a planar chip format that possesses limited control over the geometry of and materials placement around microchannel cross-sections. This imposes restrictions on the design of flow fields and external forces (electric, magnetic, piezoelectric, etc.) that can be imposed onto fluids and particles. Here we report a method of fabricating microfluidic channels with complex cross-sections. A scaled-up version of a microchannel is dimensionally reduced through a thermal drawing process, enabling the fabrication of meters-long microfluidic fibers with nonrectangular cross-sectional shapes, such as crosses, five-pointed stars, and crescents. In addition, by codrawing compatible materials, conductive domains can be integrated at arbitrary locations along channel walls. We validate this technology by studying unexplored regimes in hydrodynamic flow and by designing a high-throughput cell separation device. By enabling these degrees of freedom in microfluidic device design, fiber microfluidics provides a method to create microchannel designs that are inaccessible using planar techniques. ©2018, NSF - Center for Materials Science and Engineering (DMR-0819762), NSF - Center for Materials Science and Engineering (DMR-1419807), US Army Research Lab. & the US Army Research Office through the Institute for Soldier Nanotechnologies (Contract W911NF-13-D-0001), NIH (Contract 1R21EB022729)., Defense Advanced Research Projects Agency (Contract N66001-11-1-4182), NIH (Contract (1U24AI118656), NIH (Contract 1R21EB022729)

Published
2020

36. Caring for cells in microsystems: principles and practices of cell-safe device design and operation

Author

Varma, Sarvesh and Voldman, Joel

Subjects
0301 basic medicine, Standardization, Computer science, Cells, Cytological Techniques, Biomedical Engineering, Bioengineering, Equipment Design, General Chemistry, Biochemistry, Chemistry, 03 medical and health sciences, Cell stress, 030104 developmental biology, Risk analysis (engineering), Microsystem, Humans, Microtechnology, Safety, Set (psychology)
Abstract

This review is geared towards device engineers, designers, and users who wish to establish “cell-friendly” technologies with utility to a broader scientific community., Microfluidic device designers and users continually question whether cells are ‘happy’ in a given microsystem or whether they are perturbed by micro-scale technologies. This issue is normally brought up by engineers building platforms, or by external reviewers (academic or commercial) comparing multiple technological approaches to a problem. Microsystems can apply combinations of biophysical and biochemical stimuli that, although essential to device operation, may damage cells in complex ways. However, assays to assess the impact of microsystems upon cells have been challenging to conduct and have led to subjective interpretation and evaluation of cell stressors, hampering development and adoption of microsystems. To this end, we introduce a framework that defines cell health, describes how device stimuli may stress cells, and contrasts approaches to measure cell stress. Importantly, we provide practical guidelines regarding device design and operation to minimize cell stress, and recommend a minimal set of quantitative assays that will enable standardization in the assessment of cell health in diverse devices. We anticipate that as microsystem designers, reviewers, and end-users enforce such guidelines, we as a community can create a set of essential principles that will further the adoption of such technologies in clinical, translational and commercial applications.

Published
2018

37. High-throughput positive-dielectrophoretic bioparticle microconcentrator

Author

Gadish, Nitzan and Voldman, Joel

Subjects
Particle accelerators -- Analysis, Chemistry
Abstract

We introduce a new dielectrophoretic particle microconcentrator that combines interdigitated electrodes with a chaotic mixer to achieve high-throughput (> 100 [micro]L/min) particle concentration. The interdigitated electrodes use positive dielectrophoresis to attract particles to the surface, while the chaotic mixer circulates the particles to increase the number brought in proximity with the surface. We have used this microconcentrator to concentrate both beads and B. subtilis spores and have developed a microvolume concentration measurement method to determine the delivered off-chip concentration enhancement of the output sample. The resulting microconcentrator is sufficiently high throughput to serve as an interface between macroscale sample collectors and micro- or nanoscale detectors.

Published
2006

38. A scalable addressable positive-dielectrophoretic cell-sorting array

Author

Taff, Brian M. and Voldman, Joel

Subjects
Electrophoretic deposition -- Methods, Electrodes -- Design and construction, Chemistry
Abstract

We present the first known implementation of a passive, scalable architecture for trapping, imaging, and sorting individual microparticles, including cells, using a positive dielectrophoretic (p-DEP) trapping array. Our array-based technology enables 'active coverslips' where, when scaled, many individually held cells can be sorted based upon imaged spatial or temporally variant characteristics. Our design incorporates a unique 'ring-dot' p-DEP trap geometry organized in a row/column array format. This trap design, implemented in a two-level metal process, provides strong and highly spatially localized holding fields enabling single-cell capture for all traps in the array. We release individual trapped microparticles during sorting using a passive transistor-independent approach where we electrically ground the row and column electrodes associated with specific traps in the array. The demand for chip-to-world electrical connections in our arrays scales proportionally with the square root of the number of traps in a given array, delivering a substantial improvement over prior designs. We demonstrate capture, holding, and release operations with both beads and cells in small arrays of this new architecture.

Published
2005

41. A microfabrication-based dynamic array cytometer

Author

Voldman, Joel, Gray, Martha L., Toner, Mehmet, and Schmidt, Martin A.

Subjects
Chemistry, Analytic -- Equipment and supplies, Chemistry
Abstract

We have developed a microfabricated device for use in parallel luminescent single-cell assays that can sort populations upon the basis of dynamic functional responses to stimuli. This device is composed of a regular array of noncontact single-cell traps. These traps use dielectrophoresis to stably confine cells and hold them against disrupting fluid flows. Using quantitative modeling, we have designed traps with a novel asymmetric extruded-quadrupole geometry. This new trap can be physically arrayed and electrically addressed, enabling our cytometer. Situating an array of these traps in a microchannel, we have introduced cells into the array and demonstrated observation of fluorescent dynamic responses followed by sorting. Such a device has potential for use in investigating functional processes, as revealed by temporal behavior, in large numbers of single cells.

Published
2002

44. Automation and integration of computer vision analysis for immunotherapy research with on-chip cell trapping

Author

Tostado, Chris, Heng, Joel, Ong, Lucas, Voldman, Joel, DasGupta, Ramanuj, Ton, Yi Chin, Tostado, Chris, Heng, Joel, Ong, Lucas, Voldman, Joel, DasGupta, Ramanuj, and Ton, Yi Chin

Abstract

A population of fluorescently labeled patient-derived head-neck carcinoma metastatic cell lines (HN137M and HN120M) were trapped together with fluorescently labeled NK cells (NK92MI) in a hydrodynamic cell trapping device with a high throughput matrix of cell trapping structures to observe interactions at different pairing ratios. Human counting and a computer vision algorithm were used to count, track, and label cells and categorize traps by their cell-pairing ratios and cell death occurrence longitudinally. Kaplan-Meier survivability curves were plotted to determine patient-specific susceptibility to immune-mediated tumor killing. The algorithm was more effective than the human at identifying implicit trends and determining susceptible cell lines.

Published
2019

45. Monitoring sepsis using electrical cell profiling

Author

Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Prieto Tejedor, Javier, Su, Hao-wei, Hou, Han Wei, Vera, Miguel Pinilla, Levy, Bruce D., Baron, Rebecca M., Han, Jongyoon, Voldman, Joel, han, jongyoon, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Prieto Tejedor, Javier, Su, Hao-wei, Hou, Han Wei, Vera, Miguel Pinilla, Levy, Bruce D., Baron, Rebecca M., Han, Jongyoon, Voldman, Joel, and han, jongyoon

Abstract

Sepsis is a potentially lethal condition that might benefit from early monitoring of circulating activated leukocytes for faster stratification of severity of illness and improved administration of targeted treatment. Characterization of the intrinsic electrical properties of leukocytes is lable-free and can provide a quick way to quantify the number of activated cells as sepsis progresses. Isodielectric separation (IDS) uses dielectrophoresis (DEP) to characterize the electrical signatures of cells. Here we use IDS to show that activated and non-activated leukocytes have different electrical properties. We then present a double-sided version of the IDS platform to increase throughput to characterize thousands of cells. This new platform is less prone to cell fouling and allows faster characterization. Using peripheral blood samples from a cecal-ligation and puncture (CLP) model of polymicrobial sepsis in mice, we estimate the number of activated leukocytes by looking into differences in the electrical properties of cells. We show for the first time using animal models that electrical cell profiling correlates with flow cytometry (FC) results and that IDS is therefore a good candidate to provide rapid monitoring of sepsis by quantifying the number of circulating activated leukocytes., National Institutes of Health (U.S.) (U24AI118656), Space and Naval Warfare Systems Center San Diego (U.S.) (N66001-11-1-4182)

Published
2019

46. Multiparameter cell-tracking intrinsic cytometry for single-cell characterization

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Apichitsopa, Nicha, Jaffe, Alexander S., Voldman, Joel, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Apichitsopa, Nicha, Jaffe, Alexander S., and Voldman, Joel

Abstract

An abundance of label-free microfluidic techniques for measuring cell intrinsic markers exists, yet these techniques are seldom combined because of integration complexity such as restricted physical space and incompatible modes of operation. We introduce a multiparameter intrinsic cytometry approach for the characterization of single cells that combines ≥2 label-free measurement techniques onto the same platform and uses cell tracking to associate the measured properties to cells. Our proof-of-concept implementation can measure up to five intrinsic properties including size, deformability, and polarizability at three frequencies. Each measurement module along with the integrated platform were validated and evaluated in the context of chemically induced changes in the actin cytoskeleton of cells. viSNE and machine learning classification were used to determine the orthogonality between and the contribution of the measured intrinsic markers for cell classification.

Published
2018

47. Caring for cells in microsystems: principles and practices of cell-safe device design and operation

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Varma, Sarvesh, Voldman, Joel, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Varma, Sarvesh, and Voldman, Joel

Abstract

Microfluidic device designers and users continually question whether cells are 'happy' in a given microsystem or whether they are perturbed by micro-scale technologies. This issue is normally brought up by engineers building platforms, or by external reviewers (academic or commercial) comparing multiple technological approaches to a problem. Microsystems can apply combinations of biophysical and biochemical stimuli that, although essential to device operation, may damage cells in complex ways. However, assays to assess the impact of microsystems upon cells have been challenging to conduct and have led to subjective interpretation and evaluation of cell stressors, hampering development and adoption of microsystems. To this end, we introduce a framework that defines cell health, describes how device stimuli may stress cells, and contrasts approaches to measure cell stress. Importantly, we provide practical guidelines regarding device design and operation to minimize cell stress, and recommend a minimal set of quantitative assays that will enable standardization in the assessment of cell health in diverse devices. We anticipate that as microsystem designers, reviewers, and end-users enforce such guidelines, we as a community can create a set of essential principles that will further the adoption of such technologies in clinical, translational and commercial applications., National Institutes of Health (U.S.) (Grant GM090194)

Published
2018

50. Spatially and temporally controlled immune cell interactions using microscale tools

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Research Laboratory of Electronics, Voldman, Joel, Dura, Burak, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Research Laboratory of Electronics, Voldman, Joel, and Dura, Burak

Abstract

Many critical immunological responses are mediated by cell–cell interactions. Despite their capabilities, traditional techniques that rely on snapshot analysis or ensemble measurements can only provide a fragmentary picture of the complexity of these interactions. Emerging classes of new and versatile microscale tools hold great potential for enabling detailed investigation of these interactions with precise control in space and time, multiplexed measurement capability and high-throughput single-cell analysis. These features allow new ways of examining immune cell interactions that are not possible with traditional methods, improve the extent of information extracted from experiments, and reveal new findings. Here, we review recent developments in microscale tools that are paving the way for comprehensive analyses of cell–cell interactions in the immune system., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science (Frank Quick Faculty Research Innovation Fellowship)

Published
2017

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