The invention relates to a hybrid intracerebral electrode comprising a narrow, elongated body intended to be implanted in the brain of a patient in order to carry out at least one multi-scale electroencephalographic exploration. Said hybrid intracerebral electrode comprises, in its active part, a plurality of first electrical contact elements forming stationary macro-contacts, and a plurality of second electrical contact elements forming movable micro-contacts. The hybrid intracerebral electrode is characterised by control means which are built into the electrode in a coupling tip integral with the body. The control means are designed to move the second electrical contact elements between a passive position in which same are retracted inside the body and an active position in which same protrude outside the body, and simultaneously to adjust the controlled projection length thereof with respect to the body of the electrode.

An illustrative optical measurement system includes a light source configured to emit a light pulse directed at a target. The optical measurement system further includes a plurality of photodetectors configured to operate in accordance with an input bias voltage. The optical measurement system further includes a control circuit configured to identify a photodetector subset included in the plurality of photodetectors and that detects, while the input bias voltage has a first value, photons of the light pulse after the light pulse is scattered by the target. The control circuit is further configured to determine, based on the identifying of the photodetector subset, an overvoltage associated with the photodetector subset. The control circuit is further configured to update, based on the overvoltage, the input bias voltage for the plurality of photodetectors to have a second value.

Wireless intracranial monitors are provided. The wireless intracranial monitors comprise a main body, a wireless transceiver, a processing module, and a sensing module, in which the sensing module contains a catheter. On the catheter, a pressure sensor is configured to detect deformation of the catheter or a diaphragm connected to the pressure sensor. The detected deformation is then transmitted to the processing module through an in-catheter wire.

An implantable electrode array is provided, the electrode array comprising a substrate, the substrate having a front side and a back side, and a first number of first electrodes. The first electrodes are formed as contact pads, and are arranged on the front side. The substrate comprises a second number of prefabricated holes at predetermined positions, the holes extending from the front side through the substrate towards the back side, and being arranged such the holes may be penetrated by elongated electrodes placed at the predetermined positions.

An initial set of parameters for operating one or more detection tools is automatically derived and subsequently adjusted so that each detection tool is more or less sensitive to signal characteristics in a region of interest. Detection tool(s) may be applied to physiological signals sensed from a patient (such as EEG signals) and may be configured to run in an implanted medical device that is programmable with the parameters to look for rhythmic activity, spiking, and power changes in the sensed signals, etc. A detection tool may be selected and parameter values derived in a logical sequence and/or in pairs based on a graphical representation of an activity type which may be selected by a user, for example, by clicking and dragging on the graphic via a GUI. Displayed simulations allow a user to assess what will be detected with a derived parameter set and then to adjust the sensitivity of the set or start over as desired.

A medical lead with at least a distal portion thereof implantable in the brain of a patient is described, together with methods and systems for using the lead. The lead is provided with at least two sensing modalities (e.g., two or more sensing modalities for measurements of field potential measurements, neuronal single unit activity, neuronal multi unit activity, optical blood volume, optical blood oxygenation, voltammetry and rheoencephalography). Acquisition of measurements and the lead components and other components for accomplishing a measurement in each modality are also described as are various applications for the multimodal brain sensing lead.

A biomagnetism measurement device includes a tubular body, an inflatable portion inflatable upon supply of gas, and a magnetic sensor portion that detects a magnetic field from outside the tubular body. The inflatable portion is located at a required region of the tubular body, and the magnetic sensor portion is fixed to an inner wall of the inflatable portion. The tubular body and the inflatable portion include the same material, and the wall thickness of the inflatable portion is thinner than that of the tubular body.

A system and method for in-vivo monitoring for changes in body proteins over time includes an intelligent, implantable image capture system. An embedded processor controls activation of lighting for imaging proteins in surrounding tissue. A base image is captured and resulting data used in comparison with image data from one or more subsequent image captures to indicate progression of tissue changes, such as may occur with diseased tissue.

The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

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.