1878 results about "Dextran" patented technology

The invention is directed toward a sterile cartilage defect implant material comprising milled lyophilized allograft cartilage pieces ranging from 0.01 mm to 1.0 mm in size in a bioabsorbable carrier taken from a group consisting of sodium hyaluronate, hyaluronic acid and its derivatives, gelatin, collagen, chitosan, alginate, buffered PBS, Dextran or polymers with allogenic chondrocytes or bone marrow cells in an amount exceeding the natural occurrence of same in hyaline cartilage and adding a cell growth additive.

The present invention relates to the discovery that biocompatible anionic polymers can effectively inhibit fibrosis, scar formation, and surgical adhesions. The invention is predicated on the discovery that anionic polymers effectively inhibit invasion of cells associated with detrimental healing processes, and in particular, that the effectiveness of an anionic polymer at inhibiting cell invasion correlates with the anionic charge density of the polymer. Thus the present invention provides a large number of materials for use in methods of inhibiting fibrosis and fibroblast invasion. Anionic polymers for use in the invention include but are not limited to natural proteoglycans, and the glycosaminoglycan moieties of proteoglycans. Additionally, anionic carbohydrates and other anionic polymers may be used. The anionic polymers dextran sulfate and pentosan polysulfate are preferred. In a more preferred embodiment, dextran sulfate, in which the sulfur content is greater than about 10% by weight, may be used. In a more preferred embodiment, the average molecular weight is about 40,000 to 500,000 Daltons. The present invention provides compositions and methods to inhibit fibrosis and scarring associated with surgery. The invention further provides compositions and methods to inhibit glial cell invasion, detrimental bone growth and neurite outgrowth. In a preferred embodiment, the inhibitory compositions further comprise an adhesive protein.

The present invention relates to one kind of composite biological adsorbent and its preparation process. The adsorbent is chitosan or dextran cross-linked resin with supported titania photocatalyst and surface heavy metal ion blotting, and has the functions of adsorbing heavy metal ion, and degrading and eliminating organic pollutant, pathogen and microbe from water solution. The adsorbent is prepared through cross-linking and supporting titania photocatalyst onto chitosan and other saccharide biomass, coupling molecular engram with nanometer titania photocatalyst to form surface heavy metal ion blotting in the surface. The adsorbent has high adsorption capacity, high heavy metal selectivity, and high capacity of degrading and eliminating organic pollutant, pathogen and microbe.

The invention is directed toward a sterile cartilage defect implant material comprising milled lyophilized allograft cartilage pieces ranging from 0.01 mm to 1.0 mm in size in a bioabsorbable carrier taken from a group consisting of sodium hyaluronate, hyaluronic acid and its derivatives, gelatin, collagen, chitosan, alginate, buffered PBS, Dextran or mixed polymers with allograft chondrocytes added in an amount ranging from 2.5×105 to 2.5×107.

Disclosed are powders, preferably spray-dried powders, which contain a pharmaceutical active substance and low-molecular dextran as excipient. Also disclosed are processes for preparing such powders and methods of administering them by inhalation.

In a process for producing an iron-dextran compound for use in parenteral treatment of iron-deficiency in humans or animals a stable compound of desired relatively low molecular weight is obtained by using first hydrogenation and then oxidation to convert reducing terminal groups on the dextran molecules before reaction with the iron. By varying the ratio of hydrogenated groups to oxygenated groups the average molecular weight of the resulting iron-dextran compound can be varied.

Connective tissue regenerative compositions and methods of repairing and regenerating connective tissue using such compositions are provided. The compositions generally comprise a bioactive hydrogel matrix comprising a polypeptide, such as gelatin, and a long chain carbohydrate, such as dextran. The hydrogel matrix may further include polar amino acids, as well as additional beneficial additives. Advantageously, the compositions include further components, such as osteoinductive or osteoconductive materials, medicaments, stem or progenitor cells, and three-dimensional structural frameworks. The compositions are useful for regenerating connective tissue, and can be administered to an area having injury to, or a loss of, connective tissue, such as bone, cartilage, tendon, and ligament.

The present invention is directed to immunoassays for detecting one or more target analytes in a fluid sample wherein the detection reaction occurs on a solid support and involves an amplification system. In particular, the invention is directed to making and using a test device having at least one site for detecting the presence of at least one target analyte, wherein a conjugate comprising dextran-polystreptavidin is immobilized at the test site(s) as a capture reagent for a complex containing the target analyze.

An improved demineralized bone matrix (DBM) or other matrix composition is provided that has been mixed with a stabilizing agent that acts as (1) a diffusion barrier, (2) a enzyme inhibitor, (3) a competitive substrate, or (4) a masking moiety. A diffusion barrier acts as a barrier so as to protect the osteoinductive factors found in DBM from being degraded by proteolytic and glycolytic enzymes at the implantation site. Stabilizing agents may be any biodegradable material such as starches, modified starches, cellulose, dextran, polymers, proteins, and collagen. As the stabilizing agents degrades or dissolves in vivo, the osteoinductive factors such as TGF-.beta., BMP, and IGF are activated or exposed, and the activated factors work to recruit cells from the preivascular space to the site of injury and to cause differentiation into bone-forming cells. The invention also provides methods of preparing, testing, and using the inventive improved osteodinductive matrix compositions

Beverage products are disclosed comprising at least one fruit juice, at least one sweetener, probiotic bacteria, and beta-glucan, where the beverage product has a pH of at most 4.5 and an acid level of 0.5%-1.0%. In certain exemplary and non-limiting embodiments, the beverage product has the characteristic that if tested after 45 days of storage in hermetically sealed individually sized 12 fl. oz. PET vessels stored in the dark or in otherwise UV shielded conditions at a refrigeration temperature of 35° F. the beverage product has an increased shelf life when compared to the same beverage product without beta glucan. Methods are provided for making such beverage products with extended probiotic stability.

Injectable hydrogel microspheres are prepared by forming an emulsion where hydrogel precursors are in a disperse aqueous phase and polymerizing the hydrogel precursors. In a preferred case, the hydrogel precursors are poly(ethylene glycol) diacrylate and N-isopropylacrylamide and the continuous phase of the emulsion is an aqueous solution of dextran and a dextran solubility reducer. The microspheres will load protein, e.g., cytokines, from aqueous solution.

The invention relates to the field of cell culture, in particular to cell cryopreservation liquid, application thereof and a cryopreservation method of megakaryocyte progenitor cells. The cell cryopreservation liquid comprises DMSO, fetal calf serum, dextran, trehalose and albumin. By means of the cell cryopreservation liquid, the cytoactive of the megakaryocyte progenitor cells can be well maintained during the cryopreservation period, and damage to cells in the cryopreservation and resuscitation processes is lowered. According to the cell cryopreservation liquid, application thereof and the cryopreservation method of the megakaryocyte progenitor cells, the cryopreservation and temperature reduction processes are softer, the cells are stored in liquid nitrogen after the temperature reduction process is conducted, the influence on the cytoactive is small, and damage to the cells in the cryopreservation process is lowered. It is indicated by experiments that the vigour of the resuscitated cells can reach 94% one month after the megakaryocyte progenitor cells are cryopreservated in the cryopreservation liquid, and multiplication activity is good, and the cell cryopreservation liquid is significantly superior to the prior art.