A pinch clamp and mount are provided. The pinch clamp includes a first member and second member including rounded pinch surfaces. The second member is pivotably coupled to the first member at a first end. A threaded shaft is pivotably coupled to a second end of the first member. A second end of the second member includes a seat configured to receive the threaded shaft and a nut thereon. The seat includes protrusions at the second end that prevent the nut from sliding out of the seat. The mount includes a body having a flat bottom surface. An internal wall defines a through hole in the flat bottom surface. Two guide rails on a top surface of the body define a central slot configured to receive the clamp. A pair of keyed slots within the two guide rails are configured to receive a pair of keyed projections on the clamp.

This disclosure relates to symmetric tubing clamps for blood treatment systems and related systems and methods. In some aspects, a tubing clamp includes a resilient body that has symmetry with respect to a first plane with a normal along a longitudinal axis of the resilient body, the resilient body comprising a sidewall defining an opening such that a tubing is arrangeable through the opening along the longitudinal axis of the resilient body; first and second snap-fit features configured to engage with each other when the resilient body is compressed along a direction transverse to the longitudinal axis; and a protrusion configured to constrict the tubing when the resilient body is compressed along the direction transverse to the longitudinal axis.

Tissue access devices and methods of using the same are disclosed. The devices can have a sensor configured to occlude a flow path by deflecting a membrane into the flow path when the devices become dislodged from tissue. The sensor can be configured to partially or fully occlude the flow path. The sensor can have a spring. The spring can be biased to move the sensor from a sensor first configuration to a sensor second configuration when a force applied by the sensor first surface against a non-sensor surface changes from a first force to a second force less than the first force. The membrane can be deflected into the flow path when the sensor is in the sensor second configuration.

Tissue access devices and methods of using and making the same are disclosed. The devices can have a needle, a housing having wings, a tube having a flow channel, a tube first extension, and a tube second extension, and a torsion spring having a first coil and a second coil. The first coil can have a first coil first arm and a first coil second arm. The first coil first arm can be shorter than the first coil second arm. The second coil can have a second coil first arm and a second coil second arm. The second coil first arm can be shorter than the second coil second arm. The devices can have a sensor. More energy can stored in the torsion spring when the sensor is in a sensor closed configuration than when the sensor is in a sensor open configuration.

An apparatus, system and method for regulating fluid flow are disclosed. The apparatus includes a flow rate sensor and a valve. The flow rate sensor uses images to estimate flow through a drip chamber and then controls the valve based on the estimated flow rate. The valve comprises a rigid housing disposed around the tube in which fluid flow is being controlled. Increasing the pressure in the housing controls the size of the lumen within the tube by deforming the tube, therefore controlling flow through the tube.

The invention relates to a clamp (1), which is such that the clamp (1) can accommodate a fluid-carrying duct (L), that the clamp (1) in a resting state can compress the accommodated fluid-carrying channel (L), and that in a working state the clamp (1) can accommodate the fluid-carrying channel (L) so that the fluid-carrying channel (L) is not compressed, wherein the clamp (1) has a first permanent magnet (M1) and a second permanent magnet (M2), the permanent magnets (M1, M2) being arranged at a distance from one another, such that the permanent magnets (M1, M2) can be rotated at least about an angle relative to one another, the relative rotation of the permanent magnets (M1, M2) to one another resulting in a reduction in the distance (d), the resting state being made available at a first angle and the working state being made available at a second angle.

Pinch clamps are provided which generate positive displacement while also preventing rebound. To prevent rebound while providing positive displacement, the upper and lower clamping surfaces may be configured to form a pinch profile along which the tubing is compressed with the pinch point being formed at the distal end of the pinch profile. To further prevent rebound, the lower arm of the pinch clamp can include blocking ribs that interface with the upper clamping surface to prevent distal travelling of the pinch point even if the upper arm is forced into an over-engaged position.

In some examples, a conduit system includes a conduit defining a conduit lumen configured to provide a flow path for a fluid between a container and a medical machine. A flexible member secured to the conduit is configured to substantially occlude (e.g., close) the conduit lumen when deformed by a force acting on the flexible member toward the lumen. The conduit system includes a clamp head configured to pass through an opening defined by the conduit and exert the force on the flexible member, such that the flexible member occludes the conduit lumen. In examples, the conduit is substantially rigid conduit configured to provide a relatively constant geometry and/or flow path for the discharge of a nozzle.

A pinch clamp for use in occluding intravenous tubing or other similar tubing can include patient comfort features and/or lateral disengagement prevention features. These features can also be designed in a manner that allows the pinch clamps to be more easily manufactured. A pinch clamp can include a first arm that is coupled to a second arm by hinges. Each of the first and second arms can form a clamping surface that are aligned when the first arm is positioned overtop the second arm. The first arm can include opposing openings and the second arm can include opposing tabs which insert through the openings when the first arm is positioned overtop the second arm. The retaining tabs interface with the openings to prevent the first arm from separating from the second arm.

A pinch clamp device for a flexible tube is disclosed, the pinch clamp device comprising a first part (2) and a second part (3) that are movable with respect to each other, wherein the first part (2) comprises a first conduit (5) for housing a flexible tube and the second part (3) comprises a second conduit (6) for housing the same flexible tube, wherein the first part (2) and the second part (3) are arranged in an interacting manner such that the pinch clamp device can be present in a first position or in a second position, wherein a flow of a fluid within a flexible tube arranged inside the first conduit (5) and the second conduit (6) is enabled in the first position, and wherein a flow of a fluid within a flexible tube arranged inside the first conduit (5) and the second conduit (6) is prevented in the second position. According to an aspect of the invention, the first part (2) and the second part (3) are designed axisymmetrically. Furthermore, a pinch clamp arrangement comprising such a pinch clamp device is disclosed. Additionally pump arrangement comprising a pump and such a pinch clamp arrangement is disclosed.