A probe, such as a spectroscopic probe, for enabling a fluid or tissue sample to be tested in situ. The probe includes a conduit, such as a hypodermic needle, that can be inserted into a test subject and a wave coupling arranged to direct electromagnetic radiation, such as light, from an energy source to the sample and/or from the sample to a receiver for analysis. The receiver may comprise a Raman spectroscope. The probe may include a carriage that can be used to move at least some of the optical coupling towards and away from the insertion tip of the conduit. The probe may include a pressure modifier that can be used to draw fluid into or expel fluid from the conduit.

An ingestible electronic capsule for the collection of samples along a gastric intestinal tract and methods relating thereto are provided. The ingestible electronic capsule includes a housing and a cap that form an interior chamber. The cap includes a sampling port and one or more sample collection chambers are disposed within the interior chamber. A motor is also disposed within the interior chamber and is configured to rotate one of the cap and the one or more sample collection chambers so to align one or the one or more sample collection chambers and the sampling port of the cap so to allow for sample collection. A microcontroller is also disposed within the interior chamber and is in communication with at least the motor. The microcontroller is configured to control the selective alignment of the sampling port and one of the one or more sample collection chambers and induce gastric intestinal fluid sampling.

Methods and kits for sampling mucous from within a sinus to determine if a single sample includes one or more bacterial types indicating a bacterial infection, such as bacterial sinusitis, and one or more viruses indicating a viral infection, such as influenza.

A device to collect a biological sample may generally include an elongated rod having a handle and terminating in a tip; and a core and a plurality of projections extending in a radial direction from a surface of the core. The projections may have curved geometric pattern, such as a sinusoidal pattern, a circular arc pattern, and/or a helical pattern, for example. The device may include a layer of fibers disposed on a surface of the projections by flocking. Method of making and using the device are also described.

A test device is provided, including: a test member, including a receive portion and a first connection portion, the receive portion including a receive groove and a wall portion formed the receive groove; a moving member, inserted into the receive groove, being rotatable and movable in an axial direction to the test member, including a second connection portion; a sample collection member, formed of deformed absorption material, disposed on the moving member and disposed within the receive groove; wherein when the moving member is rotated relatively to the test member, the at least one protruding structure is moved along the at least one spiral guiding slot to move the sample collection member to rotatably axially squeeze the wall portion.

Provided are a bodily fluid-collecting device that is capable of collecting a fixed amount of bodily fluid while minimizing damage to a living body, a method for collecting a bodily fluid using the device, and a method for collecting an aqueous humor using the device A bodily fluid-collecting device 1 comprises a needle part 2 having a needle tube 3 with a needle tip 32, and a capillary 5 removably connected to a base end part 33 of the needle tube 3 in its longitudinal direction on a side opposite to the needle tip 32.

Disclosed are kits for at least partly liquefying tissue. The kit may include a liquefaction promoting medium (LPM). The LPM may include a non-ionic surfactant; a zwitterionic surfactant; and an abrasive material. The kit may include instructions. The instructions may direct a user to treat a tissue of a living subject by: applying the LPM together with the abrasive material to the tissue of the living subject; and transmitting energy to the tissue of the living subject through the abrasive material in the presence of the LPM effective to cause at least partial dissolution of one or more components of the tissue of the living subject.

A mask-based diagnostic apparatus is provided for detecting a biomarker contained in exhaled breath of a test subject. An exhaled breath condensate (EBC) collector converts breath vapor received from the lungs and airways of the test subject into a fluid biosample. The EBC collector including a thermal mass, a condensate-forming surface and a fluid conductor disposed on the condensate-forming surface. A fluid transfer system receives the fluid biosample from the EBC collector. A biomarker testing unit receives the fluid biosample from the fluid transfer system and tests the fluid biosample for a target biomarker. A testing system support is provided for supporting the EBC collector, the fluid transfer system and the biomarker testing unit. The testing system support is configured and dimensioned to fit inside a face mask. A face mask is provided forming an exhaled breath vapor containment volume to hold the exhaled breath vapor in proximity to the EBC collector to enable the condensate-forming surface cooled by the thermal mass to coalesce the exhaled breath vapor into the fluid biosample.

An implantable device is for the selective removal of molecules from tissues or fluids so as to allow the selective removal of a particular molecule of interest (target molecule) from any type of fluid solution or tissue, including biological tissues or fluids. The device operates through the complementary action of specific-binding molecules (antibodies) directed against the target molecule inside the device. The device includes a nanoperforated membrane having pores larger than the target molecule but smaller than the antibodies, such that the fluid can be removed through a second catheter with a lower concentration of target molecules.

A specimen collection device and a method of using the specimen collection device are disclosed herein. In some aspects, the specimen collection device allows for the individual collection of specimens via a removable specimen tray that can easily be swapped during a procedure. The specimen collection device includes a flexible sealing element for the continual use of suction during the procedure even when the specimen tray is not inserted.