A method of protecting an in-vivo sensor includes forming a sensing surface on a surface of the in-vivo sensor, the sensing surface including a functionalized monolayer that will bind to an analyte of interest; and coating the sensing surface of the sensor with a bioabsorbable polymeric coating including a bioabsorbable polymer; wherein the bioabsorbable polymeric coating is configured to protect the in-vivo sensor until needed for implantation.

A pellet for testing distal colonic and anorectal function. In one embodiment the pellet comprises a bag comprising the exterior of the pellet wherein the bag is comprised of a polymer that is reactive with a catalyst to form a more solid-like substance. In another embodiment, the pellet may comprise one of a grapheme layer, a wavelength transducer, or a magnetically attractive element. In another embodiment the pellet may comprise a telescopic extender and further comprise a telescope bad coupled to the telescopic extender.

The disclosure relates to two methods to modify microneedles and needles to transform them as electrochemical sensors for ions and biomolecules. The methods focus on microneedles and needles made of any material through an external and internal modification methods to provide the function as electrodes: the working electrode, (pseudo)counter electrode and/or (pseudo)reference electrode depending on the electrochemical readout. With the external modification method, any solid microneedle and needle can be individually transformed in either of the said electrodes. With the internal modification method, any hollow microneedle and needle can be individually transformed in either of the electrodes. The working electrode, (pseudo)counter electrode and or (pseudo)reference electrode can be simultaneously integrated into the same hollow microneedle or needle by internal compartmentation. Two different biofluids can be simultaneously targeted by microneedles and needles of different sizes, structures and fabricated by one or both methods when integrated in the same skin patch.

An antenna includes a controllable conductive material that is used to form transmit and/or receive antennas in different, controllable shapes. The controllable conductive material can be manipulated by an actuation control to form a continuous shape from one electrode to another to form the antenna. The controllable conductive material can be formed into multiple antennae each having a continuous shape extending between different electrodes. The antenna can be used for transmitting and receiving electromagnetic signals for determining the presence and/or amount of one or more analytes.

A material, article, system and method include a probe composition that includes a hydrophobic portion, a hydrophilic portion, an analyte-binding portion and a fluorophore portion. The analyte-binding portion is configured to bind to an analyte in an aqueous solution. The fluorophore portion is configured to change an optical property of fluorescent light emitted in response to incident excitation light when the probe composition changes between a first state in which the analyte is not bound to the analyte-binding portion and a second state in which the analyte binds to the analyte-binding portion. A material includes the probe composition and a silicone hydrogel substrate having a hydrogel network that allows flow of aqueous solution through the solution and a silicone network that occupies interstices of the hydrogel network. A contact lens having the material enables remote detection of glucose concentration in tear fluid of a subject.

Disclosed herein is a urinary detection system including a plurality of sensors configured to detect a urine sample and one or more analytes within the urine sample, the plurality of sensors selected from the group consisting of a moisture sensor, a pH sensor, a blood sensor, a bacteria sensor, and combinations thereof. The system further includes a console in communication with the plurality of sensors, the console including one or more processors, an energy source, non-transitory computer readable medium and a plurality of logic modules.

A method for medical detection implemented in a medical detection device, includes a detection instruction being received by the device, the device detecting a temperature of a test strip and determining a measurement error rate corresponding to the actual temperature of the test strip, a relationship having been established between temperatures and measurement error rates for test strip temperatures. When the medical detection device receives the test strip that carries blood of a user, at least one physiological parameter based on the blood on the test strip is measured, and a measurement value of the at least one physiological parameter is obtained. And the measurement value is compensated according to the measurement error rate, and a correction value of the physiological parameter is thus obtained.

The present disclosure provides a baffle for a shell-and-tube heat exchanger. The baffle comprises a flat plate with a region comprising a plurality of annular elements designed for receiving the tubes of the shell-and-tube heat exchanger, arranged in at least two rows, wherein a row is staggered with respect to an adjacent row, wherein the outer diameter of the annular element is less than 130% of the inner diameter of the annular element, and wherein each annular element is joined with all of its adjacent annular elements by a bridging structure in the plane of the plate, oriented along a line connecting the centers of two adjacent annular elements, thereby defining a plurality of openings in the plate. The present disclosure also provides a shell- and-tube heat exchanger, a method for heating a liquid composition, a method for stripping a liquid composition comprising urea, carbamate, ammonia and water, and a method for producing a solid, particulate, urea-based composition.

A sensor includes a working electrode in contact with an analyte solution; an amplifier including: a source terminal; a drain terminal; a back gate terminal; and nanowires, each nanowire electrically connecting the source terminal to the drain terminal; and an insulator having a first side and a second side. The working electrode is positioned to the first side of the insulator. The source terminal, the drain terminal, and the nanowires are positioned to the second side of the insulator. The insulator prevents direct electrical contact between the working electrode, the analyte solution and either the source terminal, the drain terminal, or the nanowires. The working electrode is configured such that, when a chemical species is present in the analyte solution, a variation in an electrical field at a location of the nanowires is induced, inducing a corresponding variation in an electrical current between the source terminal and the drain terminal.

Various embodiments of systems, devices and methods for improving the accuracy of an analyte sensor and for detecting sensor fault conditions are disclosed. According to some embodiments, these systems, devices, and methods can utilize a first data collected by a glucose sensor and a second data collected by a secondary sensing element. In some embodiments, the secondary sensing element can be one of a lactate sensing element, a ketone sensing element, or a heart rate monitor, among others.