Systems and methods are described for providing power transfer between modular intraluminal devices. A system embodiment includes, but is not limited to, a first intraluminal device and a second intraluminal device; the first intraluminal device including a body structure, a sensor, a processor, a data transmitter, and an energy storage module configured to power at least one of the sensor, the processor, or the data transmitter; the second intraluminal device including a second body structure, an energy storage device, and a docking structure, where the energy storage device is configured to transfer energy when the first intraluminal device and the second intraluminal device are coupled via the docking structure, the docking structure further configured to automatically decouple the first intraluminal device and the second intraluminal device subsequent to transfer of the energy.

Systems and methods are disclosed that provide for regular, periodic or continuous monitoring of fluid volume based on direct measurement of an inferior vena cava (IVC) physical dimension using a wireless measurement sensor implanted in the IVC. By basing diagnostic decisions and treatments on changes in an IVC physical dimension, information on patient fluid state is available across the entire euvolemic range of fluid states, thus providing earlier warning of hypervolemia or hypovolemia and enabling the modulation of patient treatments to permit more stable long-term fluid management.

A tissue sensing device and a method for placing the device. The device including a first electrically conductive needle; a non-conductive sheath receiving the first needle therein and allowing exposure of a portion the first needle at a distal end thereof; a second electrically conductive needle; and electronics coupled to the first and second needle, the electronics providing for sensing of capacitance between the first and second needles so as to provide an indication of a tissue in which the exposed portion of the first needle is located.

The present invention provides a system and single or multi-functional element device that can be inserted and temporarily placed or implanted into a structure having a lumen or hollow space, such as a subject's abdominal cavity to provide therewith access to the site of interest in connection with minimally invasive surgical procedures. The insertable device may be configured such that the functional elements have various degrees of freedom of movement with respect to orienting the functional elements or elements to provide access to the site from multiple and different orientations/perspectives as the procedure dictates, e.g., to provide multiple selectable views of the site, and may provide a stereoscopic view of the site of interest.

An intracranial implant to position a fiber bundle to a specified region of a brain of an animal. The implant may include a base support to be fixed to a skull of the animal over an orifice drilled in the skull, a hollow conduit arranged through the base support to guide the fiber bundle to the brain of the animal through the drilled orifice and a first locking member arranged on the base support, to cooperate with a ferrule of the fiber bundle, the first locking member configured to lock the fiber bundle to the specified region of the brain of the animal.

A wireless sensor reader is provided to interface with a wireless sensor. The wireless sensor reader transmits an excitation pulse to cause the wireless sensor to generate a ring signal. The wireless sensor reader receives and amplifies the ring signal and sends the signal to a phase-locked loop. A voltage-controlled oscillator in the phase-locked loop locks onto the ring signal frequency and generates a count signal at a frequency related to the ring signal frequency. The voltage-controlled oscillator is placed into a hold mode where the control voltage is maintained constant to allow the count signal frequency to be determined.

Procedures, implantable wireless sensing devices, and sensor assemblies suitable for monitoring physiological parameters within living bodies. Such sensor assembly includes a sensing device and an anchor for securing the sensing device within a living body. The sensing device comprises a housing having at least one internal cavity and a transducer and electrical circuitry within the at least one internal cavity. The sensing device further comprises an antenna that is within the at least one internal cavity or outside the housing. The housing has at least one additional housing portion in which the transducer, the electrical circuitry, and the antenna are not located. The anchor has a metal portion that surrounds the at least one additional housing portion so as not to surround the transducer, the electrical circuitry, or the antenna.

Embodiments of device for monitoring pressure in the left atrium are provided. The device is delivered to the left atrium via the coronary sinus. A first portion of the device is deployed in the left atrium, the first portion of the device comprising a pressure sensor. A second portion of the device is deployed in the coronary sinus. Monitoring left atrial pressure via coronary sinus access can provide a safer, less invasive way to monitor a patient for heart failure.

A method of sensing a physiological parameter involves advancing a delivery catheter to a right atrium of a heart of a patient via a transcatheter access path, advancing the delivery catheter through an interatrial septum wall into a left atrium of the heart, deploying a distal anchor of a sensor implant device from the delivery catheter, anchoring the distal anchor of the sensor implant device to a first pulmonary vein, withdrawing the delivery catheter away from the first pulmonary vein, thereby exposing at least a portion of a sensor module of the sensor implant device in the left atrium, deploying a proximal anchor of the sensor implant device from the delivery system, anchoring the proximal anchor of the sensor implant device to a second pulmonary vein, and withdrawing the delivery catheter from the heart.

The invention relates to an implantable sensor for detecting an electrical excitation of muscle cells, in particular cardiac muscle cells, wherein it is provided that the sensor comprises a dielectric component and a contact point for contacting muscle cells, which is connected to the dielectric component, so that an electric field in the dielectric component, and correspondingly a capacitance of the dielectric component, change with an electrical excitation of the muscle cells. The invention furthermore relates to a system comprising a sensor and an implant.