A medicine developed for treatment of psoriasis and production method thereof are disclosed. This medicine for treatment of psoriasis developed in the scope of the present invention comprises tallow, larch resin, beeswax, gum mastic, propolis, Alkanna tinctoria, alum and Juniper tar. The production method of the psoriasis medicine of the present invention includes the steps of: Melting the tallow at 300° C. by continuously mixing it with the beeswax, adding first the gum mastica and then the propolis to the obtained molten mixture, adding ground larch resin to the mixture together with alum, finally adding ground Alkanna tinctoria and juniper tar to the mixture, obtaining a homogenous mixture by means of continuous mixing, filtering the homogenous mixture, obtaining the medicine for treatment of psoriasis, which is the final product in the form an elute.

Methods and devices are disclosed for processing stromal precursor cells (i.e., cells which can differentiate into connective tissue cells, such as in muscles, ligaments, or tendons) which can be obtained from fatty tissue extracts obtained via liposuction. Normal processing of a liposuction extract involves centrifugation, to concentrate the stromal cells into a semi-concentrated form called “spun fat”. That “spun fat” can then be treated by mechanical processing (such as pressure-driven extrusion through 0.5 mm holes) under conditions which can gently pry the stromal cells away from extra-cellular collagen fibers and other debris in the “spun fat”. The extruded mixture is then centrifuged again, to separate a highly-enriched population of stromal cells which is suited for injection back into the patient (along with platelet cells, if desired, to further promote tissue repair or regeneration).

Methods and devices are disclosed for processing stromal precursor cells (i.e., cells which can differentiate into connective tissue cells, such as in muscles, ligaments, or tendons) which can be obtained from fatty tissue extracts obtained via liposuction. Normal processing of a liposuction extract involves centrifugation, to concentrate the stromal cells into a semi-concentrated form called “spun fat”. That “spun fat” can then be treated by mechanical processing (such as pressure-driven extrusion through 0.5 mm holes) under conditions which can gently pry the stromal cells away from extra-cellular collagen fibers and other debris in the “spun fat”. The extruded mixture is then centrifuged again, to separate a highly-enriched population of stromal cells which is suited for injection back into the patient (along with platelet cells, if desired, to further promote tissue repair or regeneration).

An acellular soft tissue-derived matrix suitable for use as a medical graft or implant may comprise, for example, a delipidated, decellularized adipose tissue matrix. The delipidated, decellularized adipose tissue matrix is substantially free of substances that pose a significant risk of causing an immunogenic response in a patient receiving the matrix. Methods for producing the delipidated, decellularized adipose tissue matrix include the steps of delipidating an adipose tissue sample, followed by decellularizing the delipidated adipose tissue sample. The resulting delipidated, decellularized adipose tissue matrix contains a proportion of Type IV collagen which is greater than the proportion of Type IV collagen contained in a matrix produced by decellularizing an adipose tissue sample prior to delipidating. Additionally, the delipidated, decellularized adipose tissue matrix contains a proportion of lipids which is less than the proportion of lipids contained in a matrix produced by decellularizing an adipose tissue sample prior to delipidating.

An acellular soft tissue-derived matrix suitable for use as a medical graft or implant may comprise, for example, a delipidated, decellularized adipose tissue matrix. The delipidated, decellularized adipose tissue matrix is substantially free of substances that pose a significant risk of causing an immunogenic response in a patient receiving the matrix. Methods for producing the delipidated, decellularized adipose tissue matrix include the steps of delipidating an adipose tissue sample, followed by decellularizing the delipidated adipose tissue sample. The resulting delipidated, decellularized adipose tissue matrix contains a proportion of Type IV collagen which is greater than the proportion of Type IV collagen contained in a matrix produced by decellularizing an adipose tissue sample prior to delipidating. Additionally, the delipidated, decellularized adipose tissue matrix contains a proportion of lipids which is less than the proportion of lipids contained in a matrix produced by decellularizing an adipose tissue sample prior to delipidating.

Provided are fetal tissue cells or a fetal tissue extract which can effectively prevent or treat bone disorders or diseases.

Provided are fetal tissue cells or a fetal tissue extract which can effectively prevent or treat bone disorders or diseases.

Disclosed are compositions and methods related to the use of adipocytes for sustained release of anti-cancer therapeutics and treatment of cancer. In one aspect, disclosed herein are engineered adipocytes comprising an anti-cancer prodrug (such as, for example, doxorubicin prodrug) and a conjugated fatty acid (such as, for example, one or more isomers of conjugated linoleic acid including, but not limited, to 9cis, 11trans, 10trans, and/or 12cis).

Disclosed are compositions and methods related to the use of adipocytes for sustained release of anti-cancer therapeutics and treatment of cancer. In one aspect, disclosed herein are engineered adipocytes comprising an anti-cancer prodrug (such as, for example, doxorubicin prodrug) and a conjugated fatty acid (such as, for example, one or more isomers of conjugated linoleic acid including, but not limited, to 9cis, 11trans, 10trans, and/or 12cis).

Methods and compositions involving exosomes or lipid nanovesicles are provided. For example, certain aspects relate to compositions comprising exosomes obtained from cells that have been induced to undergo oxidative stress or stimulated. Furthermore, some aspects of the invention provide methods of treating a subject at risk or having a demyelinating disorder using the compositions.