The disclosed apparatus, systems and methods relate to devices, systems and methods for the collection of bodily fluids. The collector can make use of microfluidic networks connected to collection sites on the skin of a subject to gather and shuttle blood into a removable cartridge. The collected fluid is supplied to substrate for drying, storage and transport.

A fluidic device (1) comprises a flow chamber (2) for accommodating a biological specimen on a carrier portion (3) and at least one flow channel (4a, 4b, 4c, 4d) fluidly connected to the flow chamber (2), the fluidic device (1) having a layered structure comprising a bottom plate (5), a cover plate (6) and an insert (7) in between, the insert (7) comprising the carrier portion (3) and a frame portion surrounding the carrier portion (3), and being elastomeric in order to be able to clamp a biological specimen between an incision in the carrier portion (3).

A biopsy apparatus includes a piercing module having a probe drive slider coupled to a probe carrier body of a biopsy probe assembly, and has a primed position and a fired position. A nut housing has a home position and an extended position. A drive spindle is drivably coupled to a motor driveshaft, and is coupled to the nut housing. A firing spring is interposed between a motor housing and the probe drive slider. A release arm is pivotably coupled to a piercing module frame. When the probe drive slider is in the primed position and the release arm is in a latch position, the release arm is positioned to engage the probe drive slider to hold the probe drive slider in the primed position. A release slider releases the release arm from the latch position when the nut housing is moved from the home position to the extended position.

In one aspect, a sample collection device for collecting a biological sample is disclosed, which comprises a sample-receiving cup having a body that extends from a proximal opening to a distal opening, where the proximal opening is configured for receiving a biological sample. The sample collection device further includes a sensor comprising at least one sensing unit, where the sensor is sealingly connected to the distal opening of the sample-receiving cup such that the sensing unit is exposed to the distal opening. A reservoir for storing one or more sample-processing reagents is provided in the fluid-receiving cup such that the sensing unit is in fluid contact with the reagent(s) stored in the reservoir. A frangible membrane separates the reservoir from the proximal opening.

A semen storage container which can store semen in a favorable state, into which semen is easily put and out of which semen is easily taken, is provided. A semen storage container includes an outer case having an open upper end, an inner case, the inner case having an opening portion at an upper end and being provided on an inner side of the outer case to close an opening of the outer case, and a removable lid laid over an upper end portion of the outer case to close the opening portion. The inner case includes a semen guide which communicates with the opening portion at the upper end and has an inner circumferential surface provided as an inclined surface which spreads upward and a cylindrical semen pool which communicates with an opening portion at a lower end of the semen guide and includes a tapered bottom portion.

A sample container for use in imaging includes a bottom portion and a wall portion extending upwardly from the bottom portion. The lid overlies the cavity when in the closed position, and a plurality of latches are coupled to the lid and extend substantially orthogonally from the lid. A plurality of recesses are coupled to the wall portion, each recess of the plurality of recesses being adapted and configured to receive one of the plurality of latches. A first alignment structure is within the cavity and is adapted and configured to align a sample lengthwise and widthwise within the cavity such that the sample is aligned relative to an imaging system when the sample container is engaged with the imaging system. A second alignment structure is at least partially within the cavity, and is adapted and configured to align the sample height wise within the cavity.

A sexual assault evidence collection kit that may be used by the victim or other non-professionals. The kit may be simplified compared to kits for professional use, and may be usable with no specialized training. Victims may therefore be able to collect evidence themselves after an assault, instead of searching for a facility with personnel trained in forensic evidence collection, and enduring a long, intrusive examination. Embodiments may include a package (for example a clear bag) and the following components inside the package: gloves, swabs, swab containers, water, evidence collection bags, evidence bag sealing tape, evidence collection tape, a permanent marker, and instructions on how to identify, collect, seal, document, and store evidence.

A sampling device includes a container having a body defining a chamber and an opening to the chamber. A septum is bonded to the container to cover the opening and hermetically seal the chamber. The septum has an adherent layer with a first thickness and including a material configured to adhere to a rim of the container to provide a hermetic seal with the container. A metallic foil layer having a second thickness is coupled to the adherent layer. An elastomeric layer having a third thickness is coupled to the metallic foil layer to position the metallic foil layer between the adherent layer and the elastomeric layer. The third thickness is greater than the sum of the first thickness and the second thickness.

An apparatus includes a transfer adapter, a puncture member, a disinfection member, and a fluid reservoir. The transfer adapter has a proximal end portion and a distal end portion, and defines an inner volume configured to receive the puncture member. The transfer adapter is coupled to the disinfection member. The distal end portion of the transfer adapter includes a port fluidically coupled to the puncture member and configured to be placed in fluid communication with a bodily-fluid of a patient. The proximal end portion is configured to receive a portion of the fluid reservoir to allow the fluid reservoir to be moved within the inner volume between a first position, in which a surface of the fluid reservoir is placed in contact with the disinfection member, and a second position, in which the puncture member punctures the surface to place the puncture member in fluid communication with the fluid reservoir.

Various systems, devices, components, and methods are disclosed for measuring the concentration of an analyte, such as acetone, in a breath sample. The disclosed devices include a breath sample analysis device having a mouthpiece configured to facilitate engagement with a user's mouth to receive a breath sample. The disclosed devices also include a breath sample capture cartridge containing an interactant that extracts the analyte from a breath sample passed through the cartridge. Also disclosed are devices for routing the breath sample through the cartridge during exhalation, and for analyzing a reaction in the cartridge to measure a concentration of the analyte.