A system for mounting a pump head to a pump assembly enclosure is provided. The system includes a mounting plate having an opening extending between a first side and a second side of the mounting plate, where the first side of the mounting plate is sized and configured for coupling to a pump head and the second side of the mounting plate is sized and configured for coupling to a pump assembly enclosure, and a cover plate configured to be disposed upon and coupled to the first side of the mounting plate, the cover plate including a tubing guide extending in a direction away from a first side of the cover plate and the first side of the mounting plate, the tubing guide including a guide channel extending through the tubing guide sized and configured to receive a pump tubing.

A peristaltic pump system includes a peristaltic pump having a roller assembly and a roller assembly housing. The roller assembly is disposed within the housing. The peristaltic pump defines a tubing maximum diameter and is configured for use with conventional tubing having a conventional tubing wall thickness less than half of the tubing maximum diameter. The system includes peristaltic pump tubing including mainline tubing and outer sleeve tubing. The outer sleeve tubing is co-axially disposed about the mainline tubing. The mainline tubing and the outer sleeve tubing extend into, through, and out of the peristaltic pump and are engaged with the roller assembly. The mainline tubing has a mainline wall thickness. The outer sleeve tubing has a sleeve wall thickness. The mainline wall thickness and the sleeve wall thickness together are approximately the same as the conventional tubing wall thickness. A method of using the pump system is provided.

A patch-sized fluid delivery device may include a reusable portion and a disposable portion. The disposable portion may include components that come into contact with the fluid, while the reusable portion may include only components that do not come into contact with the fluid. Redundant systems, such as redundant controllers, power sources, motor actuators, and alarms, may be provided. Alternatively or additionally, certain components can be multi-functional, such a microphones and loudspeakers that may be used for both acoustic volume sensing and for other functions and a coil that may be used as both an inductive coupler for a battery recharger and an antenna for a wireless transceiver. Various types of network interfaces may be provided in order to allow for remote control and monitoring of the device.

Drug delivery devices and related methods of assembly are disclosed. The drug delivery device may include a main housing having an interior surface defining an enclosed space, and an exterior surface releasably attachable to a patient. A container may be disposed in the enclosed space and include a reservoir containing a drug and a stopper. A drive assembly may also be disposed in the enclosed space and configured to move the stopper through the reservoir to expel the drug from the reservoir. The drive assembly may include a rotational power source and a gear module. The gear module may include a mounting plate and a plurality of gears rotatably connected to the mounting plate. Furthermore, the mounting plate may be separate from the main housing.

A device for aspirating body fluids and for supplying a substance to a human or animal body is defined. The device comprises a first pump (8) for the aspiration of the body fluids, and a second pump (3), or a coupling element (76′) for connecting a second pump (3′) in order to convey the substance to the body by means of the second pump (3, 3′). Moreover, the device comprises a drive (70, 70′) for driving the first pump (8). The same drive (70, 70′) which serves to drive the first pump (8) also serves to drive the second pump (3, 3′).

Peristaltic pump comprising a housing (100), containing an electric motor (130) and a reduction gear (120, 122, 124, 126) configured to be driven by the electric motor (130), and a head (200) configured to be removably coupled to the housing (100), the head (200) housing a tube comprising two accessible ends and a rotor provided with two or more squeezing elements configured to squeeze the tube, the rotor being provided with a hub configured to be mechanically connected to the reduction gear when the head (200) is coupled to the housing (100), wherein the housing (100) further houses one or more alignment plates (140, 150) for aligning the reduction gear (120, 122, 124, 126), said one or more alignment plates (140, 150) being coupled to the housing (100) through snap-fit connection means.

Peristaltic pump comprising un housing (100), containing an electric motor (130), and a head (200) configured to be coupled to the housing (100), the head (200) housing a tube comprising two accessible ends and a rotor provided with two or more squeezing elements configured to squeeze the tube, the rotor being configured to be driven by the electric motor (130) when the head (200) is coupled to the housing (100), wherein the housing (100) further contains a printed circuit board (160) configured to control the peristaltic pump and to supply power to the electric motor (130), the printed circuit board (160) being provided with two slots (161), configured to house two power supply terminals (131) of the electric motor (130) insertable into the two slots (161), and with two or more protruding male blade terminals (162), configured to be connected to external female blade terminals of an external power supply, the printed circuit board (160) being substantially triangular and configured to be obtained from a pair of printed circuit boards (160) identical to each other obtainable by separating two antisymmetric portions of a rectangular board (900) along a section line (930) that is antisymmetric with respect to or coincident with a diagonal of the rectangular board (900).

An ocular drainage system is provided for treating diseases that produce elevated intraocular pressures, such as glaucoma, wherein the system includes an implantable device and an external control unit, the implantable device includes a non-invasively adjustable valve featuring at least one deformable tube and a disk rotatably mounted within a housing, such that rotation of the disk using the external control unit causes the disk to apply a selected amount of compression to the deformable tube, thereby adjusting the fluidic resistance of the deformable tube and regulating the intraocular pressure.

A peristaltic pumphead comprising a pumphead housing accommodating a pumping tube, an end of the tube being provided with an end fitting having a through passage and an abutment shoulder and a threaded shank extending from the abutment shoulder into the tube the tube end abutting the abutment shoulder and being accommodated in an opening, in the pumphead housing, the abutment shoulder abutting the housing at the opening, and the end fitting being engaged by a retaining element to retain the abutment shoulder against the housing.

Pump heads for peristaltic pump assemblies are provided. For example, a pump head for a peristaltic pump comprises an occlusion bed, a rotor guide, a rotor assembly positioned between the occlusion bed and the rotor guide, and a pathway for tubing. The pathway comprises an inlet portion, an outlet portion, and a connecting portion that connects the inlet and outlet portions. The inlet portion is defined between the occlusion bed and the rotor guide, the outlet portion is defined between the occlusion bed and the rotor guide, and the connecting portion is defined between the occlusion bed and the rotor assembly. Further, the occlusion bed is movable with respect to the rotor guide and the rotor assembly. In exemplary embodiments, the pump head urges fluid flow through the tubing to supply a cooling fluid to a medical probe assembly for delivering energy to a patient's body.