According to the invention there is provided inter alia a process for the manufacture of a solid object having a surface comprising a layered coating of cationic and anionic polymer wherein the outer coating layer comprises an anticoagulant entity, comprising the steps of:

i) treating a surface of the solid object with a cationic polymer;
ii) treating the surface with an anionic polymer;
iii) optionally repeating steps i) and ii) one or more times;
iv) treating the surface with a cationic polymer; and
v) treating the outermost layer of cationic polymer with an anticoagulant entity, thereby to covalently attach the anticoagulant entity to the outermost layer of cationic polymer; wherein, the anionic polymer is characterized by having (a) a total molecular weight of 650 kDa-10,000 kDa; and (b) a solution charge density of >4 eq/g; and wherein, step ii) is carried out at a salt concentration of 0.25 M-5.0 M.

According to the invention there is provided inter alia a process for the manufacture of a solid object having a surface comprising a layered coating of cationic and anionic polymer wherein the outer coating layer comprises an anticoagulant entity, comprising the steps of:

i) treating a surface of the solid object with a cationic polymer;
ii) treating the surface with an anionic polymer;
iii) optionally repeating steps i) and ii) one or more times;
iv) treating the surface with a cationic polymer; and
v) treating the outermost layer of cationic polymer with an anticoagulant entity, thereby to covalently attach the anticoagulant entity to the outermost layer of cationic polymer; wherein, the anionic polymer is characterized by having (a) a total molecular weight of 650 kDa-10,000 kDa; and (b) a solution charge density of >4 eq/g; and wherein, step ii) is carried out at a salt concentration of 0.25 M-5.0 M.

Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for coating of any material where reduced fibrosis is desired, such as encapsulated cells for transplantation and medical devices implanted or used in the body.

Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for coating of any material where reduced fibrosis is desired, such as encapsulated cells for transplantation and medical devices implanted or used in the body.

According to the invention there is provided inter alia a process for the manufacture of a solid object having a surface comprising a layered coating of cationic and anionic polymer wherein the outer coating layer comprises an anticoagulant entity, comprising the steps of: i) treating a surface of the solid object with a cationic polymer; ii) treating the surface with an anionic polymer; iii) optionally repeating steps i) and ii) one or more times; iv) treating the surface with a cationic polymer; and v) treating the outermost layer of cationic polymer with an anticoagulant entity, thereby to covalently attach the anticoagulant entity to the outermost layer of cationic polymer; wherein, the anionic polymer is characterized by having (a) a total molecular weight of 650 kDa-10,000 kDa; and (b) a solution charge density of >4 ?eq/g; and wherein, step ii) is carried out at a salt concentration of 0.25 M-5.0 M.

According to the invention there is provided inter alia a process for the manufacture of a solid object having a surface comprising a layered coating of cationic and anionic polymer wherein the outer coating layer comprises an anticoagulant entity, comprising the steps of: i) treating a surface of the solid object with a cationic polymer; ii) treating the surface with an anionic polymer; iii) optionally repeating steps i) and ii) one or more times; iv) treating the surface with a cationic polymer; and v) treating the outermost layer of cationic polymer with an anticoagulant entity, thereby to covalently attach the anticoagulant entity to the outermost layer of cationic polymer; wherein, the anionic polymer is characterized by having (a) a total molecular weight of 650 kDa-10,000 kDa; and (b) a solution charge density of >4 ?eq/g; and wherein, step ii) is carried out at a salt concentration of 0.25 M-5.0 M.

Use of embolic material that is biodegradable provides for embolizing a hypervascular vessel formed in response to chronic inflammation in a musculoskeletal vasculature or a vessel related to production of ghrelin. The embolic material is biodegradable within a predetermined period of time. Medical systems are configured for delivery of embolic material for embolizing the hypervascular vessel or the vessel related to production of ghrelin.

Use of embolic material that is biodegradable provides for embolizing a hypervascular vessel formed in response to chronic inflammation in a musculoskeletal vasculature or a vessel related to production of ghrelin. The embolic material is biodegradable within a predetermined period of time. Medical systems are configured for delivery of embolic material for embolizing the hypervascular vessel or the vessel related to production of ghrelin.

Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for coating of any material where reduced fibrosis is desired, such as encapsulated cells for transplantation and medical devices implanted or used in the body.

Covalently modified alginate polymers, possessing enhanced biocompatibility and tailored physiochemical properties, as well as methods of making and use thereof, are disclosed herein. The covalently modified alginates are useful as a matrix for coating of any material where reduced fibrosis is desired, such as encapsulated cells for transplantation and medical devices implanted or used in the body.