A surgical implant (10) comprises an areal, flexible, porous basic structure (12) having a first face and a second face. At least one resorbable dyed film piece (20) is attached to the basic structure (12) and comprises a plurality of solid protrusions emerging from the dyed film piece (20) in a direction away from the basic structure (12). The at least one dyed film piece (20) is arranged in a shape structure which is asymmetric (“E”) in the area of the basic structure (12). Optionally, the implant (10) further comprises an adhesion barrier sheet (16).

A surgical implant (10) comprises an areal, flexible, porous basic structure (12) having a first face and a second face. At least one resorbable dyed film piece (20) is attached to the basic structure (12) and comprises a plurality of solid protrusions emerging from the dyed film piece (20) in a direction away from the basic structure (12). The at least one dyed film piece (20) is arranged in a shape structure which is asymmetric (“E”) in the area of the basic structure (12). Optionally, the implant (10) further comprises an adhesion barrier sheet (16).

An intravascular cell therapy device comprises a scaffold (2, 12) that is radially adjustable between a contracted orientation suitable for transluminal delivery to a vascular locus and an expanded orientation, and a biodegradable matrix provided on at least a portion of the scaffold that is suitable for seeding with cells and degrades in a vascular environment. The scaffold is configured to have a distal piercing tip (5) when in a deployed orientation. The scaffold comprises a plurality of sidewall panels (3, 13, 14) arranged around a longitudinal axis of the scaffold, and adjustable couplings (4) between the panels configured for adjustment between an expanded configuration and a contracted orientation, and in which each sidewall panel comprises a matrix suitable for seeding with cells.

Provided herein is technology relating to materials having microscale and/or nanoscale features and particularly, but not exclusively, to porous materials comprising microscale features, methods for producing porous materials comprising microscale features, drug delivery vehicles, and related kits, systems, and uses.

Provided herein is technology relating to materials having microscale and/or nanoscale features and particularly, but not exclusively, to porous materials comprising microscale features, methods for producing porous materials comprising microscale features, drug delivery vehicles, and related kits, systems, and uses.

Implantable devices, such as artificial organs, increasingly incorporate hardware, software, firmware, and/or wireless communication capabilities. For example, such implantable devices can utilize wireless technology to allow for efficient configuration, maintenance, and operational analysis. As these implantable devices become more connected, electronic security will become more important. This disclosure relates to implantable devices that may utilize a secure boot process and secure communication, both between artificial devices in the human body and between these devices and the external world. This disclosure provides secure communication approaches for maintaining the digital privacy and integrity of artificial devices, for protecting the individual from malicious hacking of data, and for controlling of such implantable devices.

Implantable devices, such as artificial organs, increasingly incorporate hardware, software, firmware, and/or wireless communication capabilities. For example, such implantable devices can utilize wireless technology to allow for efficient configuration, maintenance, and operational analysis. As these implantable devices become more connected, electronic security will become more important. This disclosure relates to implantable devices that may utilize a secure boot process and secure communication, both between artificial devices in the human body and between these devices and the external world. This disclosure provides secure communication approaches for maintaining the digital privacy and integrity of artificial devices, for protecting the individual from malicious hacking of data, and for controlling of such implantable devices.

A photo-responsive composite actuator according to the present invention includes a polymeric scaffold film; an azobenzene liquid crystal polymer applied on a surface of the polymeric scaffold film; and a protective film attached to a surface of the azobenzene liquid crystal polymer.

A photo-responsive composite actuator according to the present invention includes a polymeric scaffold film; an azobenzene liquid crystal polymer applied on a surface of the polymeric scaffold film; and a protective film attached to a surface of the azobenzene liquid crystal polymer.

A method of 3D printing in which a 3D product is built up layer by layer by jetting from print heads includes forming part of a 3D product by a functional binder jetting process; jetting one or more material in a 2D pattern to form a structure on said part; completing the formation of the 3D product by continuing the functional binder jetting process, so that said structure becomes embedded in said product. Functional binder jetting may include: providing a layer of a powder bed; jetting a functional binder onto selected parts of said layer, wherein said functional binder infiltrates into pores in the powder bed and locally fuses particles of the powder bed in situ; sequentially repeating applying a layer of powder on top and selectively jetting functional binder, multiple times, to provide a powder bed bonded at selected locations by printed functional binder.