A soft tapping device for preparing a bone hole that includes a substantially cylindrical insert that is sized to enter into a compressed woven retention device. The substantially cylindrical insert has protrusions that are adaptable to expand portions of a compressed woven retention device inside the bone hole. The substantially cylindrical insert is also configured to exit from the compressed woven retention device without changing the expanded portions of the compressed woven retention device.

A surgical instrument includes an end effector with a surface made of amorphous titanium oxide, and a film resin covering the surface and chemically bonding to the surface.

The present disclosure provides methods of forming interlayer tissue cushions (e.g., submucosal cushions) using shear-thinning hydrogels comprising an anionic polysaccharide and layered silicate and subsequent use of the cushions for removing protrusions (e.g., lesions, such as polyps or tumors) from above the cushions. Further provided are uses, methods of treatment, and kits.

A chamber providing controlled amounts of IR and visible light within an internal space sized to seat at least one human being. The chamber includes at least one heater configured to emit FIR energy, at least one heater configured to emit NIR energy, and at least one heater configured to emit at least MIR energy. The chamber includes at least one light emitting source configured to emit a selected wavelength of visible light, and a control panel configured to control the amount and duration of FIR, MIR, NIR and visible light within the chamber.

A catheter assembly for insertion into the brain. The assembly comprises a first length of tubing made of a first material. A second material surrounds the first length of tubing, the second material being more flexible than the first material and having a hardness of less than 50 Rockwell E. The second material provides damping to the first length of tubing.

A flowable liquid formulation for 3D printing is described. The formulation comprises from 0.1 to 25 wt. % radiopaque particles, wherein at least 50% by weight of the particles have a diameter of at most 100 nm. The formulation further comprises monomeric, oligomeric and/or polymeric precursors adapted for polymerization to form a solidified article. Also described is an article (100) formed by 3D printing, the article (100) comprising a first 3D printed region (110) having a first radiopacity and a second 3D printed region (120) having a second radiopacity, wherein the first radiopacity is greater than the second radiopacity. Also described is a method of forming the article (100).

The present invention relates to novel biocompatible oxygen gas generating devices that can be implanted into a living subject. In certain embodiments, the oxygen gas generating devices can be used to deliver oxygen gas to tissue in a subject, thereby stimulating tissue growth and repair. In other embodiments, the devices operate by electrolytically splitting endogenous water in a subject. In yet other embodiments, the device further comprises an implantable supercapacitor capable of supplying energy to the oxygen gas generating device.

The present disclosure relates to woven and knitted fabrics including boron nitride nanotubes and to methods of manufacturing and using such materials. In one embodiment, these materials are incorporated into implantable medical devices such as stent graft devices and the like.

Provided herein is technology relating to medical imaging and particularly, but not exclusively, to devices, methods, systems, and kits related to a quantitative diffusion imaging phantom.

Methods for improving the antibacterial characteristics of biomedical implants and related implants manufactured according to such methods. In some implementations, a biomedical implant comprising a silicon nitride ceramic material may be subjected to a surface roughening treatment so as to increase a surface roughness of at least a portion of the biomedical implant to a roughness profile having an arithmetic average of at least about 500 nm Ra. In some implementations, a coating may be applied to a biomedical implant. Such a coating may comprise a silicon nitride ceramic material, and may be applied instead of, or in addition to, the surface roughening treatment process.