Improvements in and relating to blood sampling devices A blood sampling device includes a housing and a lancet supporting a lancet needle or tip, the lancet and needle being urged or urgeable in a pricking direction. A trigger mechanism is moveable to a fire position for releasing the lancet to travel in the pricking direction. A removable safety cap initially covers the lancet needle. The lancet has an initial position in which movement of the trigger mechanism to its fire position is blocked and an intermediate position in which the trigger mechanism may be moved to its fire position. The intermediate position is obtainable only on removal of the safety cap.

Methods and systems for collecting and analyzing blood are provided. The methods and systems generally operate by collecting a blood sample on a portion of a lancet and subjecting the blood sample to optical spectroscopy.

The biological test kit is a device for drawing and, optionally, testing biological samples. The biological test kit is an array of lancets set in wells in a rigid base. Each lancet well is covered by a protective cover which when deformed permits the lancet to puncture a user or other patient. In one embodiment the biological test kit employs distinct covers for each lancet and in another the covers are formed from sheet material formed into blisters which cover the lancet.

A system, mixing-enhanced microfluidic container, and methods for small volume sample collection and/or analysis is disclosed. Namely, the invention is directed to a small volume sample collection system that includes a mixing-enhanced microfluidic container and a durable reusable actuation chuck. The mixing-enhanced microfluidic container is used to collect small volumes of sample fluid and includes a means for mixing the sample fluid with reagents disposed within the microfluidic container. The mixing means utilize an array of surface-attached structures (e.g., a micropost array). The application of an “actuation force,” such as a magnetic or electric field, actuates the surface-attached structures into movement, wherein the actuation chuck in close proximity to the mixing-enhanced microfluidic container provides the “actuation force.”

This invention is in the field of medical devices. Specifically, the present invention provides portable medical devices that allow real-time detection of analytes from a biological fluid. The methods and devices are particularly useful for providing point-of-care testing for a variety of medical applications.

A method of measuring body fluid content, the method comprising computer executed steps, the steps comprising: receiving a value of a temperature of a body part of a subject, and generating corrective data based on the received measured temperature value and on previously gathered data, the corrective data being usable for correcting a measurement of content of a fluid sample taken from the body part.

This invention is in the field of medical devices. Specifically, the present invention provides fluidic systems having a plurality of reaction sites surrounded by optical barriers to reduce the amount of optical cross-talk between signals detected from various reaction sites. The invention also provides a method of manufacturing fluidic systems and methods of using the systems.

Devices, systems, and methods for storing and/or transporting bodily fluid samples are disclosed herein. In some embodiments, a device for storing and/or transporting a sample of bodily fluid is configured to receive a collection cartridge including a housing and a sample tray removably coupled to the housing. The device can include a base and a cover pivotally coupled to the base. The cover is movable relative to the base between.an open position in which the jig portion is accessible and a closed position in which the jig portion is inaccessible. The base can include a jig portion configured to (a) receive the collection cartridge and (b) decouple the sample tray from a housing of the collection cartridge.

A system, mixing-enhanced microfluidic container, and methods for small volume sample collection and/or analysis is disclosed. Namely, the invention is directed to a small volume sample collection system that includes a mixing-enhanced microfluidic container and a durable reusable actuation chuck. The mixing-enhanced microfluidic container is used to collect small volumes of sample fluid and includes a means for mixing the sample fluid with reagents disposed within the microfluidic container. The mixing means utilize an array of surface-attached structures (e.g., a micropost array). The application of an “actuation force,” such as a magnetic or electric field, actuates the surface-attached structures into movement, wherein the actuation chuck in close proximity to the mixing-enhanced microfluidic container provides the “actuation force.”

The present disclosure relates to capillary blood sampling. In one aspect, the present disclosure provides a finger lancing device comprising a body having a chamber for receiving a finger and a lancing device comprising a lancing member actuator for actuating a lancing member to lance a finger received in the chamber.