A method and device for collecting a blood sample from a subject are provided. The handheld device comprises an actuator assembly and a body housing the actuator assembly and having a cavity configured to releasably receive a cartridge to couple to the actuator assembly. The cartridge is configured to capture the blood sample from the subject when used with the device. The blood sample is collected when the device determines that the cartridge is properly positioned over a vein or capillaries of the subject.

A body fluid sampling device (100) provides a user with the ability to sample and/or analyze a fluid in the body (body fluid) such as blood, puss or venom. The device (100) includes at least: a body fluid reservoir for containing the sampled body fluid and a fluid extraction mechanism including at least one conduit or needle connected to a conduit injection and retraction mechanism and a vacuum reservoir. After connecting the body fluid reservoir to the sampling device, a vacuum seal of the body fluid reservoir is adapted to be broken so as to cause the sucking of the body fluid into the body fluid reservoir. The sampling device (100) aids in executing a method (200) of the invention consisting of collecting body fluid such as capillary blood samples without the intervention of medically trained personnel. The sampling device (100) enables the user to: (a) sample a body fluid, optionally auto-sampling; (b) optionally, using one or more droplet(s) of the sampled body fluid, to immediately analyze the body fluid; and (c) provide a medical analysis tube (4000) meeting size and interface standards filled with the sampled body fluid for analysis in a point of care or medical lab. The sampling device includes a vacuum tube and an interface therefor. The vacuum tube provides the suction necessary to draw the body fluid from the user/patient and to fill the vacuum tube with the body fluid.

Devices associated with on-body analyte sensor units are disclosed. These devices include any of packaging and/or loading systems, applicators and elements of the on-body sensor units themselves. Also, various approaches to connecting electrochemical analyte sensors to and/or within associated on-body analyte sensor units are disclosed. The connector approaches variously involve the use of unique sensor and ancillary element arrangements to facilitate assembly of separate electronics assemblies and sensor elements that are kept apart until the end user brings them together.

Systems and methods for autonomous intravenous needle insertion are disclosed herein. In an embodiment, a system for autonomous intravenous insertion include a robot arm, one or more sensors pivotally attached to the robot arm for gathering information about potential insertion sites in a subject arm, a medical device pivotally attached to the robot arm, and a controller in communication with the sensors and the robot arm, wherein the controller receives the information from the sensors about potential insertion sites, and the controller selects a target insertion site and directs the robot arm to insert the medical device into the target insertion site.

A device and method are disclosed for intravenous cannulation. The device employs a spring to precisely and accurately control the force and velocity imparted to a piercing needle, with mechanical constraints built into the device to precisely and accurately control the distance through which the piercing needle travels. A sheathed-needle configuration is used with an outer, echogenic needle that can be seen via ultrasound; and an inner needle used to pierce the vein. The operator releases the piercing needle with a controlled velocity, controlled force, and controlled travel distance. The device reduces the human error and complications that have previously been associated with manually piercing a vein for cannulation.

A sample collection and testing device for analyzing blood is provided that includes a controller, a fluid flow pathway, a pump configured to move fluid through the fluid pathway, and an optical fluid measurement element configured to measure a light intensity of the fluid in the fluid flow pathway. The controller is configured to: start the pump to move a blood sample in the fluid flow pathway, receive a signal from the optical fluid measurement element indicating a detection of a leading edge of the blood in the fluid flow pathway, stop the pump to stop the moving of the blood in the pathway, receive a plurality of light intensity measurements from the optical measurement element, each light intensity measurement measured at a corresponding point of time, and provide a mapping of the light intensity measurements into an indication of a coagulation of the blood sample over a time period.

A wearable electronic device configured to be worn by a user while performing an invasive procedure for enhancing visualization of desired anatomical structures is provided. The wearable electronic device includes: a housing; at least one imaging sensor associated with the housing; and a visual display integrally formed with or associated with the housing. The device is configured to acquire an image of an invasive access site of a patient with the at least one imaging sensor, process the image to determine a location of a desired anatomical structure, and display a virtual trace of the location to the user via the visual display.

Embodiments of the present disclosure provide a device for determining a location of a blood vessel and a method thereof. The device includes a plurality of sensors, a processor, and an indicating device. The plurality of sensors may detect pressure values at a plurality of skin locations in contact with the plurality of sensors. The processor may determine the location of the blood vessel based on the pressure values. The pressure value at the skin location corresponding to the location of the blood vessel is greater than the pressure values at both sides of the skin location in a direction perpendicular to a direction of the blood vessel. The indicating device may indicate the location of the blood vessel.

An apparatus includes a catheter, an introducer, and an actuator. A distal end portion of the introducer is configured to couple to an indwelling peripheral intravenous line. The actuator is movably coupled to the introducer and is configured to move the catheter between a first position, in which the catheter is disposed within the introducer, and a second position, in which a distal end portion of the catheter is distal to the introducer. A first portion of the actuator is disposed outside of the introducer and in contact with an outer surface of the introducer such that (1) a longitudinal axis defined by a second portion of the actuator is nonparallel to a longitudinal axis defined by the introducer and (2) the second portion of the actuator exerts a force on a proximal end portion of the catheter operable to increase an internal stress with in a portion of the catheter.

This invention relates to a medical device (20, 40, 60) for use in aiding the successful placement of a needle tip in a blood vessel. The medical device comprises a resiliently deformable collapsible body (21) defining a pressure chamber therein. The body further comprises a port (29) for engagement of a hub of a needle, the port defining a fluid passageway from the exterior of the body to the interior of the pressure chamber. The device further comprises means to generate an audible noise (31, 41) upon expansion of the collapsible body from a collapsed configuration to an expanded configuration. In this way, as the tip of the needle enters the lumen of the blood vessel, the collapsible body is configured to transition from a contracted to an expanded configuration, thereby causing the auditory cue. This auditory cue indicates to the medical professional that the tip of the needle is in the lumen of the blood vessel.