A repeater system may control a pump by using a repeater and a user interface. An adhesive patch system may be used for affixing a pump or other object to a human body. Such an adhesive patch system may include two sets of adhesive members, each member including an adhesive material on at least one side so as to attach to the body. The members of the first set are spaced to allow the members of the second set to attach to the body in spaces provided between the members of the first set, and the members of the second set are spaced to allow members of the first set to detach from the body without detaching the members of the second set. Also, fill stations and base stations are provided for personal pump systems.

A system for supplying power transcutaneously to an implantable device implanted within a subject is provided. The system includes an external connector including one of a microneedle array and a microwire holder. The system further includes a power cable electrically coupled to the external connector and configured to supply power to the one of the microneedle array and the microwire holder, and an internal connector configured to be implanted within the subject and electrically coupled to the implantable device, the internal connector including the other of the microneedle array and the microwire holder. The microneedle array includes a plurality of electrically conductive microneedles, the microwire holder includes a plurality of electrical contacts, and the microwire holder is configured to engage the microneedle array such that the plurality of electrically conductive microneedles extend through the skin of the subject and electrically couple to the plurality of electrical contacts.

An implantable intracranial pulse pressure modulator for treating hydrocephalus in patients of all ages is disclosed as well as a system and method for use of the same. In one embodiment of the implantable intracranial pulse pressure modulator, two one-way valves are interposed in parallel, opposing orientations between a vestibule and a chamber. One of the one-way valves, in response to systole, provides fluid communication from the vestibule to the chamber such that a small aliquot of cerebrospinal fluid (CSF) is displaced from a cerebral ventricle into a ventricular catheter, thereby reducing intraventricular systolic pressure. The other one-way valve, in response to diastole, provides fluid communication from the chamber to the vestibule such that the same volume of CSF is reintroduced into a cerebral ventricle, thereby increasing intraventricular diastolic pressure. Together, both processes work synergistically to reduce intraventricular pulse pressure in order to treat hydrocephalus.

The invention relates to a device for detecting a malfunctioning of a valve/catheters assembly for shunting a cerebrospinal fluid or the like, characterized in that it comprises: a chamber (6) which is placed inside the said housing; a laminar canal (4), a sensor (7) for measuring a pressure in the said chamber; a flexible membrane (5) separating the sensor from the chamber (6); control and communications electronics (8,9) able to exchange with an external reader in order to transmit a measurement by the said sensor, the sensor (7) being attached to the flexible membrane (5) with which it is in contact.

An apparatus for treating a urinary retention of a patient by discharging urine from a mammal urinary bladder through a mammal urethra. The apparatus comprises an expandable member adapted to be implanted inside the urinary bladder of the patient, a control device adapted to control the volume of the expandable member for emptying the mammal urinary bladder, and an implantable restriction devices adapted to close each ureter of a patient when discharging urine from the urinary bladder.

Disclosed herein are medical device systems, and methods thereof. Exemplary medical devices can include intraosseous (IO) access device systems, or similar medical devices that include a motive force. Embodiments include replaceable and rechargeable batteries that are configured to store one or more performance characteristics of the medical device and transfer the performance characteristic to a base station when the battery is removed from the medical device and coupled with the base station for recharging. The base station can then store performance characteristics from one or more batteries and/or medical devices. The performance characteristics can be transferred from the base station to one or more external computing devices or networks.

An at least partly implantable system for injecting a substance into a patient's body. The system comprises at least one flexibly bendable infusion needle with a tip end of each of said at least one infusion needle arranged in at least one first housing for penetrating the first housing's outer wall in at least one penetration area and having the respective other end arranged in at least one second housing, the first and second housings being adapted for implantation inside the patient's body, wherein the at least one second housing is provided for implantation inside the patient's body remote from the at least one first housing and wherein the injection needle is sufficiently long to bridge the distance from the at least one second housing for remote implantation to the at least one first housing and further through the first housing up to the outer wall of the first housing. The system further comprises at least one drive unit adapted for being coupled to the at least one infusion needle and arranged at least for advancing the tip end of the at least one infusion needle so that the at least one infusion needle penetrates with the tip end or ends thereof said at least one first housing's outer wall in said at least one penetration area.

A system for stimulating body tissue may include a stimulation lead, sensors, and a control unit. The stimulation lead may include one or more energy sources. The control unit may include a processor and non-transitory computer readable medium, and an interface (e.g., touch screen interface) for receiving user inputs and communicating information to the user. The sensors may be configured to provide impedance measurements to the control unit. The control unit may calculate lung gas distributions and/or generate an image modeling lung gas distributions. Stimulation delivered by the stimulation may be adjusted based on the impedance measurements.

The present technology relates to interatrial shunting systems and methods. In some embodiments, the present technology includes a system for shunting blood between a left atrium and a right atrium of a patient. The system can include a shunt having a lumen extending therethrough. When the shunt is implanted in the patient, the lumen is configured to fluidly couple the left atrium and the right atrium. The system can also include a sensor configured to be implanted in the patient and operably coupled to the shunt. The sensor can be configured to measure one or more parameters corresponding to a physiological parameter of the patient and/or a characteristic of the shunt. The system can further include an external component wirelessly coupled to the sensor. The external component can be worn by or otherwise adhered to the patient.

An ambulatory medical device and a method of communication between medical devices are disclosed. In one embodiment, the medical device includes a module for communication with at least a second medical device wherein the module for communication is adapted to be activated by a value of a physiological parameter of an animal. In one embodiment, the method of the present invention involves a first medical device and at least a second medical device wherein the communication between said medical devices is activated by a value of a physiological parameter of an animal.