There is provided a process for producing a medical, material that retains the properties which are inherent in a polyanionic polysaccharide being a raw material, that has a high level of safety because there is no need to use a chemical crosslinking agent, and that has moderate strength and flexibility. The present invention is a process for producing a medical material, the process including a step of dispersing a powder or a granular product of a first polyanionic polysaccharide, the first polyanionic polysaccharide water-insolubilized with a treatment liquid containing a first acid anhydride, in an aqueous solution of a water-soluble salt of a second polyanionic polysaccharide, thereby obtaining a dispersion liquid, a step of drying the dispersion liquid obtained, thereby obtaining a dried film, and a step of water-insolubilizing the dried film obtained with a treatment liquid containing a second acid anhydride, thereby obtaining the medical material.

The present disclosure relates to methods and products for reducing adhesions. In certain embodiments, the present disclosure provides a method of reducing adhesions in a subject, the method comprising exposing a region in the subject susceptible to formation of an adhesion to an agent having iron chelation and/or antioxidant activity, thereby reducing adhesions in the subject.

The purpose of the present invention is to provide an adhesion prevention material capable of exhibiting excellent adhesion preventive effect. This adhesion prevention material concurrently uses: (A) a peptide (A-1) having an amino acid sequence-(X-Pro-Y)n-[wherein X represents an arbitrary defined amino acid, Pro represents proline, Y represents hydroxyproline or proline, and n is an integer between 1 and 10] and/or a peptide (A-2) having an amino acid sequence-(Pro-Y)m-[wherein Pro represents proline, Y represents hydroxyproline or proline, and m is an integer between 1-10]; and (B) a gelatin gel. This adhesion prevention material exhibits a dramatically enhanced adhesion preventive effect as compared with the case where the abovementioned components are used individually, and in particular, has a markedly superior effect against adhesion of tendons.

An embodiment of the present invention is to provide a bioabsorbable medical material having adhesiveness to a biological tissue and improved degradability. A bioabsorbable medical material according to an embodiment of the present invention contains a crosslinked polymer material forming a specific shape, and a disintegration delaying material retained by the crosslinked polymer material. The crosslinked polymer material has degradability in water, the degradability being suppressed in the presence of an acid. The disintegration delaying material releases 0.5 mol%/day or greater of an acid until the seventh day upon contact with water at 37° C.

This disclosure is directed to methods of treating a subject with a fibrotic or fibroproliferative disease, comprising administering to the subject a composition comprising an effective amount of an anti-fibrosis agent, e.g., a CXCR4 and/or CXCR7 binding agent, such as CXCL12.

A medical needle may include a lumen coating configured to reduce surface energy of the lumen-facing/lumen defining surface, in a manner effective to slow and/or reduce coagulation of biomaterial (particularly blood) that contacts the needle lumen surface. Such a coating may include a hydrophobic coating such as a silane and/or siloxane material on at least the needle lumen surface. The coating reduces a surface energy of coated needle regions below the surface energy of uncoated regions, and particularly reduces the polar component of the surface energy in the coated needle regions. The needle may be a metallic biopsy needle with the coating comprised by at least a distalmost length of sample-collection lumen.

The inventive subject matter provides compositions and methods for transiently or permanently treating or managing an injury. Contemplated compositions are polymerizable in situ over short time periods, even in the presence of blood, without undue exothermic heat. Contemplated compositions may further comprise an anesthetic, an antiseptic, an adhesion promoter, and/or a vasoconstrictor.

Disclosed is a composition based on copolymers including at least one A-B block copolymer, wherein block A is a polyester and block B is a polyoxyethylene (PEG), and wherein the total molecular mass in weight of the PEG is higher than or equal to 50 kDa, and the ethylene oxide motif/ester motif molar ratio is between 0.5 and 5. The invention also relates to an anti-adhesive material including such a composition, used for the prevention of tissue adhesions and especially for the prevention of intrauterine synechiae.

A problem to be solved by the present invention is to provide a fibrosis inhibitor that solves the problem of inhibiting fibrosis of an organ or tissue surface, and especially of inhibiting fibrosis of an epicardial surface. Furthermore, by inhibiting fibrosis, the present invention prevents or reduces subsequent development of adhesions to avoid organ or tissue damage during re-operation. Provided is a fibrosis inhibitor for inhibiting fibrosis of a tissue by fixing a biocompatible polymer to a tissue where it is desirable to inhibit fibrosis.

Disclosed are hydrogels polymerized with or around a solid biofunctional moiety, biodegradable or permanent, designed to be implantable in a mammalian body, intended to block or mitigate the formation of tissue adhesions, and intended to aid in functional healing. The hydrogels of the present invention are characterized by comprising multiphasic structural elements: a) at least one gel phase, b) at least one solid phase, c) optional polymeric chains connecting gel and solid phases, d) optional shape designs that provide for an interpenetrating geometry between gels and solids, e) optional shape designs that enhance a tissue-hydrogel interface, and f) optional shape designs that provide a biofunctional aspect. The hydrophobicity of the various phases is chosen to reduce tissue adhesion and enhance tissue healing. The morphology of the polymers comprising the gel phase is typically of high molecular weight and has morphology that encourages entanglement. Useful polymeric structures include branching chains, comb or brush, and dendritic morphologies.