Abstract: Provided are devices and methods of preparing a population of cardiomyocytes by aligning undifferentiated pluripotent cells on a nanosacale textured surface.

Abstract: This disclosure provides a monolithic mold including a plurality of lens forming features that can be used to simultaneously form a plurality of lenses with different sizes and shapes. The mold can be formed by disposing a polymeric material around a plurality of physical objects with different shapes and sized. A method of forming the mold includes providing a substrate that has a surface with regions of low and high wettability. Water is deposited on the surface such that water droplets are formed with different contact angles. The mold is formed around the droplets.

Abstract: A mobile medical device for monitoring a respiratory condition in a subject, the medical device including: a sensor configured to be adhered to the skin of a patient, the sensor configured to yield a resistance signal that is modulated by movements of a chest of a patient during respiration; a sensor attachment module configured to receive the signal from the sensor and to output data to a mobile electronic device an indication of an adverse respiratory event. Also disclosed is a server for integrating data collected from a plurality of the mobile medical devices and a crowd-sourced respiration advisory system including a plurality of the mobile medical devices and a server for integrating data collected by the mobile medical devices.

Abstract: A sensor including a flexible substrate, a conductor disposed on the flexible substrate, and a hydrophilic surface coating disposed on the conductor. The flexible substrate and the conductor form wrinkle as a result of the substrate being shrunk. The hydrophilic surface coating is disposed in, e.g., fills, the wrinkles or covers surface areas of the conductor within invaginations of the wrinkles. Also disclosed are methods of preparing the sensor and methods of detecting an amount of an analyte in an aqueous solution. Methods of detecting an amount of analyte can include contacting the sensor with an aqueous solution, and detecting an electrical signal with the sensor, wherein the electrical signal is indicative of the amount of the analyte.

Abstract: Disclosed are hydroxyl radial generating devices, comprising: a substrate layer; and a pyrite layer configured to produce hydroxyl radicals. Another aspect relates to a method for producing a hydroxyl radical generating device, comprising: providing a polymeric substrate layer; placing a layer of pyrite on a surface of the polymeric substrate layer to form a multi-layer structure; and applying heat to the multi-layer structure such that at least the surface of the polymeric substrate layer contracts; wherein the layer of pyrite contracts to a lesser extent than the surface of the polymeric substrate layer providing a textured surface comprising the pyrite layer. Also disclosed is a method of analysis, comprising: placing a solution comprising a biological substance on a sample site of a hydroxyl generating device comprising a surface of pyrite; incubating the solution; and analyzing a sample including proteolytic fragments of the biological substance.

Abstract: Provided are methods of preparing a sample for detection by placing the sample on a shrinkable scaffold and then shrinking the scaffold. An exemplary shrinkable scaffold is a thermoplastic substrate.

Abstract: An apparatus comprising a wearable device comprising a supporting structure, a sensor and an electronics module, wherein the supporting structure is configured to press the sensor against a skin surface of a subject, wherein the sensor is configured to detect a biological metric of the subject, and wherein the electronics module is configured to quantify and/or transmit one or more signal(s) corresponding to the biological metric. Some aspects relate to a method of monitoring a biological metric in a subject comprising: adorning a subject with the wearable device; and detecting the biological metric over a period of time in the subject with the wearable device. Other aspects relate to a method of treating a disease in a subject comprising: monitoring a biological metric in the subject over a period of time, and treating the subject with a therapeutic protocol, and monitoring the biological metric in the subject to assess treatment efficacy.

Abstract: This disclosure provides a diagnostic system including a detection zone adapted to receive a volume of biological fluid. The detection zone includes a plurality of micro-scale and nano-scale features that render the detection zone superhydrophobic. Analytes (e.g., proteins and/or other molecules) are concentrated when the volume of biological fluid is allowed to evaporate on the detection zone. Concentrating the analytes in the detection zone by evaporation can advantageously increase the sensitivity of detection of the analyte. In various implementations, microfluidic channels can be integrated with the diagnostic system to convey the volume of biological fluid to the detection zone. In various implementations, the microfluidic channels can have a lower hydrophobic characteristic than the surrounding to realize self-driven microfluidic channels that convey the biological fluid to the detection zone without using any external devices.

Abstract: Described are fabrication methods of highly wrinkled metal thin films for applications in electronics such as wearable devices, strain sensors, and capacitive sensors.

Abstract: A sensor apparatus including a flexible substrate and a wrinkled conductor disposed on the flexible substrate. In some embodiments, the conductor includes micro-scale invaginations. Also disclosed are methods of making a sensor apparatus, including: placing a mask over a polymeric sheet, wherein the mask is configured to block regions of the polymeric sheet, depositing a conductive structure on the polymeric sheet at regions exposed through the mask, shrinking the polymeric sheet with conductive structure patterned on its surface by heating, and transferring the conductive structure to a flexible substrate. Also disclosed are methods of sensing a health condition of a user or patient. The methods include coupling a sensor apparatus to a surface of a user or patient overlying structures to be monitored. The sensor apparatus may include a crumpled conductor capable of detecting strain.

Abstract: Methods of forming a microfluidic device include: combining a volume of uncured liquid silicone based polymer with a volume of adhesive polymer to provide a flowable material; applying the flowable material to a mold and curing the flowable material on the mold to form a microfluidic device layer comprising an exposed face with at least one channel or chamber; and contacting the exposed face of the microfluidic device layer to a substrate to adhere the microfluidic device layer to the substrate to enclose the at least one channel or chamber to form a microfluidic device.

Abstract: A method is provided to prepare one or more microfluidic channels on a receptive material by applying an image-forming material to a heat sensitive thermoplastic receptive material in a designed pattern and heating the material under conditions that reduce the size of the thermoplastic receptive material by at least about 60%. In an alternative aspect, the microfluidic channels on receptive material are prepared by etching a designed pattern into a heat sensitive thermoplastic material support and then heating the material under conditions that reduce the size of the thermoplastic receptive material by at least about 60%.

Abstract: Provided are methods of preparing a plurality of extrusions, comprising (a) shrinking a transparent first thermoplastic material comprising a plurality of non-transparent marks, (b) lithographically transferring the pattern of the shrunk non-transparent marks to a layer of photoresist deposited on a second thermoplastic material, and (c) shrinking the second thermoplastic material, thereby generating a plurality of extrusions on the shrunk second thermoplastic material.

Abstract: A wearable sensor apparatus is disclosed that includes a flexible substrate adapted to be coupled with a skin surface of an expectant mother. A conductor is disposed on the flexible substrate. The conductor can include micron-scale invaginations. The conductor can be capable of repeatable variation in resistance when subject to a strain. Also disclosed is a system for monitoring the health of a fetus in utero that includes a wearable sensor apparatus. The wearable sensor apparatus is configured to output a signal responsive to an electrical input. The system includes a computing system with one or more hardware processors. The computing system is programmed to implement a signal processing module configured to access the output signal from the wearable strain gauge and generate an output indicative of health of the baby in utero.

Abstract: A method is provided to prepare one or more microfluidic channels on a receptive material by applying an image-forming material to a heat sensitive thermoplastic receptive material in a designed pattern and heating the material under conditions that reduce the size of the thermoplastic receptive material by at least about 60%. In an alternative aspect, the microfluidic channels on receptive material are prepared by etching a designed pattern into a heat sensitive thermoplastic material support and then heating the material under conditions that reduce the size of the thermoplastic receptive material by at least about 60%.

Abstract: Provided are methods of preparing a biocompatible textured surface on a thermoplastic material comprising treating the material with a plasma and subsequently shrinking the substrate to induce formation of textures. The textured surfaces are useful in one aspect, to align cells such as stem cells.

Abstract: Disclosed are hydroxyl radial generating devices, comprising: a substrate layer; and a pyrite layer configured to produce hydroxyl radicals. Another aspect relates to a method for producing a hydroxyl radical generating device, comprising: providing a polymeric substrate layer; placing a layer of pyrite on a surface of the polymeric substrate layer to form a multi-layer structure; and applying heat to the multi-layer structure such that at least the surface of the polymeric substrate layer contracts; wherein the layer of pyrite contracts to a lesser extent than the surface of the polymeric substrate layer providing a textured surface comprising the pyrite layer. Also disclosed is a method of analysis, comprising: placing a solution comprising a biological substance on a sample site of a hydroxyl generating device comprising a surface of pyrite; incubating the solution; and analyzing a sample including proteolytic fragments of the biological substance.

Abstract: The disclosure relates to methods and devices for measuring samples, such as biological samples, especially those at low abundance, with high sensitivity and at low cost. A sample is disposed on a shrinkable scaffold and the shrinkable scaffold is shrunk, reducing the area where the sample is distributed, so as to effectively concentrate the sample on the surface of the scaffold. In the event that a biological sample is covalently attached to a scaffold having a silica structure, the increase in signal enhancement is also due to optical effects stemming from covalent linkage of the biological sample onto the silica structure of the scaffold. Silica (SiO2) may be deposited onto a surface of a polymer film by functionalizing the surface of the polymer film to bind silica from a sol-gel solution, and coating the film with a sol-gel solution containing silica precursors, wherein solid silica from the sol-gel solution is deposited onto the surface of the polymer film.

Abstract: This disclosure provides a diagnostic system including a detection zone adapted to receive a volume of biological fluid. The detection zone includes a plurality of micro-scale and nano-scale features that render the detection zone superhydrophobic. Analytes (e.g., proteins and/or other molecules) are concentrated when the volume of biological fluid is allowed to evaporate on the detection zone. Concentrating the analytes in the detection zone by evaporation can advantageously increase the sensitivity of detection of the analyte. In various implementations, microfluidic channels can be integrated with the diagnostic system to convey the volume of biological fluid to the detection zone. In various implementations, the microfluidic channels can have a lower hydrophobic characteristic than the surrounding to realize self-driven microfluidic channels that convey the biological fluid to the detection zone without using any external devices.

Abstract: Apparatus and methods are provided for analysis of individual particles in a microfluidic device. The methods involve the immobilization of an array of particles in suspension and the application of experimental compounds. Such methods can also include electrophysiology studies including patch clamp recording, electroporation, or both in the same microfluidic device. The apparatus provided includes a microfluidic device coupled to a multi-well structure and an interface for controlling the flow of media within the microchannel device.