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“A MEMS differential scanning calorimeter for thermodynamic characterization of biomolecules” Micro Electro Mechanical Systems Conference.

“Demonstration of MEMS-based differential scanning calorimetry for determining thermodynamic properties of biomolecules” Sensors and Actuators B: Chemical.

The Technology: Cost-effective MEMS DSC device to examine biomolecular thermodynamics.

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“A MEMS differential scanning calorimeter for thermodynamic characterization of biomolecules” Micro Electro Mechanical Systems Conference.

“Demonstration of MEMS-based differential scanning calorimetry for determining thermodynamic properties of biomolecules” Sensors and Actuators B: Chemical.

The Technology: Cost-effective MEMS DSC device to examine biomolecular thermodynamics.

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The Technology: Microneedle array device for reduced invasiveness of blood collection.

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This technology has been validated with calculations and simulations, and the device is currently being 3D printed for testing.

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The Technology: Microfluidic device for enhancing temporal accuracy of time-resolved cryo-EM.

This technology is a microfluidic device that enables a reaction sample to flow in a co-flowing concentric buffer, resulting in a narrow distribution of reaction times for time-resolved cryo-electron microscopy (TR cryo-EM).

This technology has been validated with calculations and simulations, and the device is currently being 3D printed for testing.

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Publications:\tA MEMS affinity glucose sensor using a biocompatible glucose-responsive polymer, Xian Huang, Siqi Li, Jerome S. Schultz, Qian Wang, and Qiao Lin,Sensors and Actuators B: Chemical, Volume 140, Issue 2, 16 July 2.

Lead Inventors:\tQiao Lin, Xian Huang, Quian Wang, Jerome S. Schultz\r \rSTV Reference:\tIR M09-070, M09-071, M09-072.

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Publications:\tA MEMS affinity glucose sensor using a biocompatible glucose-responsive polymer, Xian Huang, Siqi Li, Jerome S. Schultz, Qian Wang, and Qiao Lin,Sensors and Actuators B: Chemical, Volume 140, Issue 2, 16 July 2.

Lead Inventors:\tQiao Lin, Xian Huang, Quian Wang, Jerome S. Schultz\r \rSTV Reference:\tIR M09-070, M09-071, M09-072.

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Publications: A MEMS affinity glucose sensor using a biocompatible glucose-responsive polymer, Xian Huang, Siqi Li, Jerome S. Schultz, Qian Wang, and Qiao Lin,Sensors and Actuators B: Chemical, Volume 140, Issue 2, 16 July 2.

Lead Inventors: Qiao Lin, Xian Huang, Quian Wang, Jerome S. Schultz\r\rSTV Reference: IR M09-070, M09-071, M09-072.

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Publications: A MEMS affinity glucose sensor using a biocompatible glucose-responsive polymer, Xian Huang, Siqi Li, Jerome S. Schultz, Qian Wang, and Qiao Lin,Sensors and Actuators B: Chemical, Volume 140, Issue 2, 16 July 2.

Lead Inventors: Qiao Lin, Xian Huang, Quian Wang, Jerome S. Schultz\r\rSTV Reference: IR M09-070, M09-071, M09-072.

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This technology is a thin-film bulk acoustic resonator (FBAR) that can be used for mass-based biomolecular and chemical detection.

Current methods for biomolecular and chemical detection rely primarily on chemical or fluorescent labeling, which require complex protocols and can impact assay sensitivity.

The Technology: Mass sensing device for label-free, multiplexed, high-sensitivity molecular analysis.

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This technology is a thin-film bulk acoustic resonator (FBAR) that can be used for mass-based biomolecular and chemical detection.

Current methods for biomolecular and chemical detection rely primarily on chemical or fluorescent labeling, which require complex protocols and can impact assay sensitivity.

The Technology: Mass sensing device for label-free, multiplexed, high-sensitivity molecular analysis.

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Detection device for chemical and drug assays.

Feng X, Fu Z, Kaledhonkar S, Jia Y, Shah B, Jin A, Liu Z, Sun M, Chen B, Grassucci RA, Ren Y, Jiang, H, Frank J, Lin Q.

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Low-cost PDMS microfluidic TR cryo-EM chip enables affordable, modular time-resolved protein studies with rapid spray-plunge vitrification.

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Detection device for chemical and drug assays.

Feng X, Fu Z, Kaledhonkar S, Jia Y, Shah B, Jin A, Liu Z, Sun M, Chen B, Grassucci RA, Ren Y, Jiang, H, Frank J, Lin Q.

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This device-to-device variation leads to workflow inefficiencies, inconsistent results, and increased operational costs, limiting the widespread adoption of advanced biosensors in settings where rapid and reliable measurements are critical.

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Calibration-free graphene FET biosensor uses aptamer kinetics for rapid, device-wide reproducible biomarker detection without per-sensor calibration.

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Current biosensor platforms for detecting protein biomarkers—especially those used in point-of-care and clinical diagnostics—require time-consuming and labor-intensive individual calibration of each sensor device due to variability introduced during manufacturing and surface preparation.

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This device-to-device variation leads to workflow inefficiencies, inconsistent results, and increased operational costs, limiting the widespread adoption of advanced biosensors in settings where rapid and reliable measurements are critical.

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This technology consists of a portable microfluidic device that integrates cell capture, fluid flow, and temperature control to isolate one cell type with high specificity.

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Minimizing the size of the device enables cost-efficiency and precise control of cell immobilization.

This technology consists of a portable microfluidic device that integrates cell capture, fluid flow, and temperature control to isolate one cell type with high specificity.

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Advantages:\n\r\r\n\r\nDevice can be embedded onto a contact lens or thin flexible film.

Lead Inventor:\n\r\r\nQiao Lin, Ph.D.\n\r\r\nPatent Information:\n\r\r\nPatent Pending (WO/2015/192064.

Zhu Y, Hao Y, Adogla EA, Yan J, Li D, Xu K, Wang Q, Hone J, Lin Q.

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Advantages:\n\r\r\n\r\nDevice can be embedded onto a contact lens or thin flexible film.

Lead Inventor:\n\r\r\nQiao Lin, Ph.D.\n\r\r\nPatent Information:\n\r\r\nPatent Pending (WO/2015/192064.

Zhu Y, Hao Y, Adogla EA, Yan J, Li D, Xu K, Wang Q, Hone J, Lin Q.

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This technology is a microfluidic device that generates aptamers for individualized detection of minimal residual disease (MRD).

This technology generates aptamers for individual patients using an integrated microfluidic device.

Patient-specific aptamers against minimal residual disease biomarkers (M-proteins) are produced automatically within the device, which can then be isolated and used after treatment to monitor M-protein levels in blood.

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This technology is a microfluidic device that generates aptamers for individualized detection of minimal residual disease (MRD).

This technology generates aptamers for individual patients using an integrated microfluidic device.

Patient-specific aptamers against minimal residual disease biomarkers (M-proteins) are produced automatically within the device, which can then be isolated and used after treatment to monitor M-protein levels in blood.

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Feng X, Fu Z, Kaledhonkar S, Jia Y, Shah B, Jin A, Liu Z, Sun M, Chen B, Grassucci RA, Ren Y, Jiang H, Frank J, Lin Q.

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PDMS microfluidic chip automates rapid sample prep and loading for time-resolved cryo-EM, enabling intermediate-structure capture.

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Feng X, Fu Z, Kaledhonkar S, Jia Y, Shah B, Jin A, Liu Z, Sun M, Chen B, Grassucci RA, Ren Y, Jiang H, Frank J, Lin Q.

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Laboratory experiments that require high spatial resolution temperature measurements, such as MEMS or lab-on-a-chip applications.

Temperature profile measurements of integrated circuits, cells, and MEMS structures.

This technology has measured temperatures across devices and can achieve a temperature resolution of 0.1 degrees Celsius and a spatial resolution of 3.

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DNA-based high-resolution thermometer uses fluorescence in DNA strands for real-time, spatial temperature mapping with 0.

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Laboratory experiments that require high spatial resolution temperature measurements, such as MEMS or lab-on-a-chip applications.

Temperature profile measurements of integrated circuits, cells, and MEMS structures.

This technology has measured temperatures across devices and can achieve a temperature resolution of 0.1 degrees Celsius and a spatial resolution of 3.

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This technology uses chemically modified Tm3+-doped avalanching nanoparticles to remotely measure forces with high sensitivity and spatial resolution across a wide dynamic range, from piconewton to micronewton levels.

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Remote near-infrared nanoscale force sensors (Tm3+-doped) detect pico-to-micronewton forces non-invasively with high photostability.

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This technology uses chemically modified Tm3+-doped avalanching nanoparticles to remotely measure forces with high sensitivity and spatial resolution across a wide dynamic range, from piconewton to micronewton levels.

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Microdevice for small-scale calorimetric measurement