A method for embolization of a blood vessel in a body, wherein at least one gelling component is biocompatible, biodegradable, with radiopaque capability and in liquid form to be supplied to a blood vessel by means of a single or multi lumen microcatheter and forming once in contact with a gelling agent in situ a deformable solid matrix in the body. The microcatheter may be provided with a first lumen disposed inside a second lumen. The gelling agent may be supplied to the blood vessel before the gelling component. Therapeutic compositions may be supplied to the blood vessel through the microcatheter.

Disclosed is a medicine loaded nano-capsule additive Polymethylmethacrylate (PMMA) cement and its production method.

The invention features adhesive devices for holding objects (e.g., bone fragments) fixed with respect to each other.

The invention features adhesive devices for holding objects (e.g., bone fragments) fixed with respect to each other.

A system for performing a minimally invasive percutaneous procedure comprises a medical device comprising a hydrogel delivery needle (4) with a tip and a hydrogel outlet (6), an injectable, shear-thinning, self-healing viscoelastic hydrogel that exhibits a storage modulus (G′) of at least 600 Pa, and a tan δ (G″/G) from 0.1 to 0.6 in dynamic viscoelasticity measured by a rheometer at 1 Hz and 1% strain rate at 25° C. The system may also comprise a coaxial cannula (2) having a lumen configured for receipt of the hydrogel delivery needle (4), wherein the hydrogel delivery needle comprises an adjustable positioning mechanism (8) configured to limit the advancement depth of the hydrogel delivery needle through the coaxial cannula to a predetermined depth distal to a distal-most end of the coaxial cannula.

A system for performing a minimally invasive percutaneous procedure comprises a medical device comprising a hydrogel delivery needle (4) with a tip and a hydrogel outlet (6), an injectable, shear-thinning, self-healing viscoelastic hydrogel that exhibits a storage modulus (G′) of at least 600 Pa, and a tan δ (G″/G) from 0.1 to 0.6 in dynamic viscoelasticity measured by a rheometer at 1 Hz and 1% strain rate at 25° C. The system may also comprise a coaxial cannula (2) having a lumen configured for receipt of the hydrogel delivery needle (4), wherein the hydrogel delivery needle comprises an adjustable positioning mechanism (8) configured to limit the advancement depth of the hydrogel delivery needle through the coaxial cannula to a predetermined depth distal to a distal-most end of the coaxial cannula.

The invention features adhesive devices for holding objects (e.g., bone fragments) fixed with respect to each other.

The invention features adhesive devices for holding objects (e.g., bone fragments) fixed with respect to each other.

A composite viscoelastic hydrogel comprises a continuous phase of non-crosslinked hyaluronic acid gel and a dispersed phase of dehydrothermally-crosslinked micron-sized gelatin hydrogel particles. The hydrogel exhibits a storage modulus (G′) of greater than 400 Pa and a tan δ (G″/G′) from 0.1 to 0.8 in dynamic viscoelasticity measured by a rheometer at 1 Hz and 1% strain rate at 25° C. The dehydrothermally crosslinked micron-sized gelatin hydrogel particles have an average dimension of less than 100 microns prior to hydration.

A composite viscoelastic hydrogel comprises a continuous phase of non-crosslinked hyaluronic acid gel and a dispersed phase of dehydrothermally-crosslinked micron-sized gelatin hydrogel particles. The hydrogel exhibits a storage modulus (G′) of greater than 400 Pa and a tan δ (G″/G′) from 0.1 to 0.8 in dynamic viscoelasticity measured by a rheometer at 1 Hz and 1% strain rate at 25° C. The dehydrothermally crosslinked micron-sized gelatin hydrogel particles have an average dimension of less than 100 microns prior to hydration.