Abstract: The present invention relates to plant-based coacervate core-shell microcapsules, wherein the shell comprises a plant protein extract, as well as methods and uses of the same.

Abstract: An implantable cuff electrode and/or optrode (40) adapted to encircle a substantially cylindrical tissue (70), is provided that includes a support sheet (43) rolled about a longitudinal axis, forming a cuff of inner diameter, Dc, and extending over a length, L a central portion, extending over a length, lc, of at least 50% of the length, L, and having a mean central thickness, tc, and wherein the central portion is flanked on either side by, a first edge portion (43e) of mean edge thickness, te1, and a second edge portion (43e) of mean edge thickness, te2, at least a first electrode contact or a first optrode exposed at an inner surface of the cuff, and remote from an outer surface forming the exterior of the cuff, Characterized in that, the mean edge thicknesses, te1, te2, of the first and second edge portions are each lower than tc.

Abstract: A kit of parts and method for the control of a delivery of an electric or electromagnetic pulse to a vagus nerve by an implanted stimulating device is provided. The kit of parts includes an implantable stimulating device (10) that includes a cuff electrode/optrode for being coupled to a vagus nerve (Vn) of a patient to be treated, and an encapsulation unit (50) suitable for being subcutaneously implanted at a location separated from the vagus nerve coupling unit (60), and enclosing an energy pulse generator (51s), for delivering electrical or optical energy pulses, and coupled to the cuff electrode/optrode by one or more electrical conductors (41e) and/or optical fibres (41f), an external controller device (100) of the kit includes laryngeal electrodes (161) suitable for being coupled to a laryngeal region (Lx) of a patient for measuring a laryngeal electrical activity at the laryngeal region, the laryngeal electrodes being coupled to an external control unit (150).

Abstract: An implantable cuff electrode and/or optrode (40) adapted to encircle a substantially cylindrical tissue (70), is provided that includes a support sheet (43) rolled about a longitudinal axis, forming a cuff of inner diameter, Dc, and extending over a length, L a central portion, extending over a length, lc, of at least 50% of the length, L, and having a mean central thickness, tc, and wherein the central portion is flanked on either side by, a first edge portion (43e) of mean edge thickness, te1, and a second edge portion (43e) of mean edge thickness, te2, at least a first electrode contact or a first optrode exposed at an inner surface of the cuff, and remote from an outer surface forming the exterior of the cuff, Characterized in that, the mean edge thicknesses, te1, te2, of the first and second edge portions are each lower than the mean central thickness, tc,

Abstract: A kit of parts and a system for centering an external element with respect to an implantable medical device is provided that includes: •An implantable medical device (20) for being implanted under the skin of a patient and having an internal housing with a light source (22) positioned such as to emit a light beam coaxial to a secondary axis (Z2), •An external element (10) having —a number, N>2, of photodetectors (12a-12d) forming a polygon of N edges, normal to a primary axis (Z1), and —an indicator (4) indicating how the external element is to be displaced over the the skin to position the external element with the primary axis (Z1), being coaxial with the secondary axis (Z2), as a function of the energy received by each of the N photodetectors. A corresponding method for aligning the external element and the implantable medical device are provided.

Abstract: A kit of parts and a system for centering an external element with respect to an implantable medical device is provided that includes: •An implantable medical device (20) for being implanted under the skin of a patient and having an internal housing with a light source (22) positioned such as to emit a light beam coaxial to a secondary axis (Z2), •An external element (10) having —a number, N> 2, of photodetectors (12a-12d) forming a polygon of N edges, normal to a primary axis (Z1), and —an indicator (4) indicating how the external element is to be displaced over the skin to position the external element with the primary axis (Z1), being coaxial with the secondary axis (Z2), as a function of the energy received by each of the N photodetectors. A corresponding method for aligning the external element and the implantable medical device are provided.