A lancing device including a latch that pivots between a non-blocking position allowing a lancet carrier and a lancet to advance and retract through a first forward and reverse lancing stroke and a blocking position preventing further/excess/secondary oscillation of the lancet carrier and lancet. The pivotal latch can pivot about an axis perpendicular (e.g., for an L-shaped latch) or parallel/coaxial (e.g., for a sleeve latch) to the advancement and retraction motion of the lancet carrier and lancet.

An automated method of evaluating a collected fluid sample includes: filling a sample cavity with the collected fluid sample; adding a buffer solution; separating the collected fluid sample into a first portion and a second portion; mixing the second portion with tagged antibodies; removing leftover tagged antibodies; and measuring a difference between the first portion and the second portion. A sample collection and testing device includes: a reference cavity comprising a reference fluid sample; a test cavity comprising a test fluid sample; a reference measurement element associated with the reference cavity; and a test measurement element associated with the test cavity. A method of evaluating a collected fluid sample including: separating the sample; pumping a first portion to a first measurement cavity; adding a solution to a second portion and pumping the mixture to a second measurement cavity; and measuring a charge difference between the first and second measurement cavities.

An optical fluid measurement element includes: an emitter that generates an optical output; an absorber that measures an optical input; and a fluid flow pathway, where the optical output of the emitter passes through the fluid flow pathway and is received as the optical input to the absorber after passing through the portion of the fluid flow pathway. An automated method of measuring fluid volume using an optical fluid measurement element includes: activating an emitter; capturing data from an optical sensor; detecting a leading edge of fluid travelling along a flow pathway; starting a counter when the leading edge is detected; and calculating a volume based on a value of the counter. An automated method of measuring fluid attributes along a flow pathway. The method includes: activating an optical emitter; receiving a signal from an optical sensor; and processing the received signal to determine at least one fluid attribute.

A sampling element (110) for generating a sample of a body fluid is disclosed. The sampling element (110) comprises a housing (114), the) housing having a chamber (122) with at least one puncture element (112) stored therein. A tip (132) of the puncture element (112) is movable through at least one puncture opening (124) of the housing (114) in order to perforate a skin portion of a user. The sampling element (110) further comprises at least one compression element (150), which is adapted to increase a pressure of the body fluid within a body tissue of the user in a region of puncturing when pressed onto the skin portion of the user. The compression element (150) is movably mounted to the housing (114). The sampling element (110) comprises at least one locking mechanism (168) for releasably locking the compression element (150) in at least two positions. The at least two positions comprise a first position (170) and a second position (172), the second position (172) being offset from the first position (170). In a further aspect of the invention, an analytical device (204) is disclosed, the analytical device (204) being adapted for using the sampling element (110) of the invention.

An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices.

An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices.

Devices are provided to automatically inject drugs or other payloads into or beneath skin. These devices include an injector configured to drive a hollow needle into the skin and subsequently to deliver the payload through the hollow needle. Applied suction acts to draw blood from the puncture formed in the skin through the hollow needle, into the device, and to a sensor, blood storage element, or other payload. In some examples, the blood is drawn through the hollow needle when the hollow needle is penetrating the skin. In some examples, these devices are additionally configured to retract the hollow needle from the skin and/or to perform some other functions. These devices can be wearable and configured to automatically access blood or deliver a payload into skin, for example, to operate at one or more points in time while a wearer of a device is sleeping.

A lancing device with rear adjustment of penetration depth includes a cap, cap holder, ejection pin and shell, wherein: the lancing device has an external and medium depth adjusting sleeve. The ejection pin is located in the medium sleeve and the external depth adjusting sleeve is sleeved outside the medium sleeve; the external sleeve connects axially and circumferentially to the shell, and a rotary locating mechanism is between the external sleeve and the shell; the medium sleeve is connected circumferentially and axially in a sliding way, and a rotary moving mechanism is between the medium the external sleeve, and the medium includes a passive impact face relative to the active impact face of the ejection pin; the external sleeve includes a manual adjusting ring outside the lancing device at the middle and rear part, and rotates to drive the medium sleeve to move axially, changing the needle tip penetration depth.

A blood collecting device collects blood in a short time after puncture without scattering the blood into the open air other than a container for collecting the blood. One of representative blood collecting devices has a container unit that includes a screw portion, a holder that holds the container unit serving as a system whose one end is closed, a puncture unit that can be attached to the container or the holder, a through-hole of the puncture unit, and a puncture unit protection member that protects the puncture unit and the container unit.

There is provided an injector having an improvement in a linear launching profile. The injector of the present invention is used for launching a lancet to provide a pricking. The injector of the present invention comprises a plunger capable of launching the lancet in a pricking direction, an injector housing which surrounds the plunger, and an injector cap capable of being attached and detached with respect to the injector housing. In particular, an inner face of the injector cap is provided with a rib, and the rib and the plunger moving for the pricking are capable of contacting with each other.