Methods for performing endovascular procedures are described herein. The methods may comprise advancing an expandable member of a blood flow control device to a target location in a blood vessel of a patient, and rotating a circular gear positioned at least partially within a housing of a controller via the controller communicably coupled to the blood flow control device. Rotating the circular gear may translate a linear gear of a syringe pump fluidly coupled to the expandable member thereby adjusting a volume of the expandable member. Various blood flow control devices, control systems, and fluid delivery systems are also described herein. The fluid delivery systems may include a pump configured for manual or automated delivery of fluids, or configured to switch between automated and manual modes of delivery. The pump may be a syringe pump that utilizes a rack and pinion system, a motor, and a sensor to track the position and/or movement of a component of the syringe pump during fluid transfer. Alternatively, the pump may be a pressure differential pump that includes a flow restrictor and a pressure sensor that controls delivery of fluid from a fluid reservoir. Systems and methods including the syringe and pressure differential pumps are also described.

A fluid injector system includes a powered fluid injector, a connection port configured to receive a single-use disposable set having tubing connected to a fluid inlet port at a first end and connected to a waste outlet port at a second end, and a detector associated with the connection port and configured to generate a signal in response to a sonic, infrasonic, or ultrasonic wave emitted from the single-use disposable set during a priming operation of the single-use disposable set. In some examples, the detector is configured to generate a signal if the frequency of the wave emitted from the single-use disposable set is outside a predetermined range of frequencies corresponding to a predetermined range of frequencies of air expelled from the tubing. A method for detecting the multiple uses of a single-use disposable set connected to a fluid injector system is also provided.

A drug delivery device comprising a pumping system (4) and a liquid reservoir (7) fluidly connected to a delivery system outlet (12), the liquid reservoir comprising an elastic plunger (14) sealingly slidable within a container wall (13) of the liquid reservoir for expelling liquid out of the reservoir. The pumping system comprises a piston pump (5) comprising a plunger actuator arranged to displace the plunger (14), and a dosing unit (6) arranged downstream of the liquid reservoir (7) and fluidly connected to the liquid reservoir. The dosing unit (6) comprises a chamber portion (22) arranged between an inlet valve (24) and an outlet valve (26), the chamber portion (22) arranged to receive from the liquid reservoir a pump cycle volume of liquid under an operational pressure greater than ambient pressure generated by the piston pump, and to the deliver said pump cycle volume of liquid to the delivery system outlet, said pump cycle volume being dependent on the operational pressure.

A medicinal liquid supply control apparatus according to an embodiment of the present disclosure includes a reservoir located on a second channel to define an internal space that stores a medicinal liquid, an inlet hole and an outlet hole being formed in one portion of an outer surface of the reservoir and connected to the internal space, and a reservoir support part on which the one portion of the reservoir is fixed, an inlet connection hole connected to the inlet hole and an outlet connection hole connected to the outlet hole being formed at the reservoir support part.

A drug solution administration device includes: an injection unit configured to inject a drug solution in vivo; a container; a push-out mechanism configured to allow the drug solution stored inside the container to flow into the injection unit; a sealing member attached to the push-out mechanism and pressed against a wall surface of the containing space; a drive mechanism configured to generate a drive force for moving the push-out mechanism back and forth; and a control unit is configured such that, when a predetermined time has passed after the control unit controls the drive mechanism to stop operation of the drive mechanism, the control unit controls the drive mechanism to move the push-out mechanism and to shift a position of the sealing member relative to the wall surface of the containing space.

A filling aid device for filling a reservoir. The device includes a cover portion comprising a septum window; a slider beam comprising a septum cover; and a first filling aid tab attached to the slider beam, the first filling aid tab in slidable relation to the cover from a first position to a second position, wherein when the filling aid device is in an unlocked position, the septum cover is located below the septum window, wherein when the first filling aid tab is moved from the first position to the second position, the septum cover is moved from below the septum window, and the filling aid device is in the locked position.

Spring-based sensor devices are described. For example, a spring-based sensor system may include at least one spring associated with a mechanical element, the at least one spring operative to change from a first state to a second state based on a configuration of the mechanical element, sensing circuitry configured to determine an electrical property of the at least one spring, the electrical property to have a first value when the at least one spring is in the first state and a second value when the at least one spring is in the second state, and a logic device to determine a status of the mechanical element based on the electrical property. Other embodiments are described.

Systems and methods are provided for injecting one or more agents into tissue within a patient's body. In one embodiment, an injection device includes a substantially axially incompressible elongate member including a lumen extending between proximal and distal ends thereof. A distal stop is provided on the distal end and a needle tip extends distally beyond the distal stop, the needle tip having a cross-section smaller than the distal end. The needle tip includes a passage communicating between the lumen and an outlet in the distal tip that has having a cross-section smaller than the lumen. In an exemplary embodiment, the elongate member includes a coil extending between the proximal and distal ends, and a sleeve disposed within an interior region of the coil extending between the proximal and distal ends. The sleeve defines the lumen and may be free-floating within at least a portion of the coil.

The present invention provides an automatic drug delivery device. The automatic drug delivery device includes an enclosure and a first piston disposed in the enclosure. The first piston partitions the enclosure to a first drug delivery chamber and a first expansion chamber. A first through hole and a second through hole are formed in the wall of the enclosure, the first through-hole communicates with the first drug delivery chamber, and the second through-hole communicates with the first expansion chamber. A first targeted dissolution membrane covers the first through hole and the second through hole, and dissolves at a first targeted region. A drug is filled in the first drug delivery chamber, and an expandable material is included in the first expansion chamber. The expandable material in the first expansion chamber can expand after absorbing liquid.

A drive system for a drug delivery device is described. The drive system comprises an axial drive component configured to drive advancement of a stopper sealing a container; a variable rate drive drives advancement of the axial drive component and a controller controls the variable rate drive to deliver a first volume of medicament at a first rate, and a second volume of medicament at a second rate. The controller is configured to: optionally, identify a start point for delivery of medicament from the container, the start point being identified as completion of a predefined preparatory event; drive the variable rate drive at a first speed during a first phase from the identified start point to deliver the first volume of medicament at the first rate; drive the variable rate drive at a second speed during a second phase to deliver the second volume of medicament at the second rate.