The growth factor profile, connective tissue matrix constituents, and immunoprivileged status of urodele extracellular matrix (ECM) and accompanying cutaneous tissue, plus the presence of antimicrobial peptides there, render urodele-derived tissue an ideal source for biological scaffolds for xenotransplantation. In particular, a biological scaffold biomaterial can be obtained by a process that entails (A) obtaining a tissue sample from a urodele, where the tissue comprises ECM, inclusive of the basement membrane, and (B) subjecting the tissue sample to a decellularization process that maintains the structural and functional integrity of the extracellular matrix, by virtue of retaining its fibrous and on-fibrous proteins, glycoaminoglycans (GAGs) and proteoglycans, while removing sufficient cellular components of the sample to reduce or eliminate antigenicity and immunogenicity for xenograft purposes. The resultant urodele-derived biomaterial can be used to enhance restoration of skin homeostasis, to reduce the severity, durations and associated damage caused by post-surgical inflammation, and to promote progression of natural healing and regeneration processes. In addition, the biomaterial promotes the formation of remodeled tissue that is comparable in quality, function, and compliance to undamaged human tissue.

The growth factor profile, connective tissue matrix constituents, and immunoprivileged status of urodele extracellular matrix (ECM) and accompanying cutaneous tissue, plus the presence of antimicrobial peptides there, render urodele-derived tissue an ideal source for biological scaffolds for xenotransplantation. In particular, a biological scaffold biomaterial can be obtained by a process that entails (A) obtaining a tissue sample from a urodele, where the tissue comprises ECM, inclusive of the basement membrane, and (B) subjecting the tissue sample to a decellularization process that maintains the structural and functional integrity of the extracellular matrix, by virtue of retaining its fibrous and on-fibrous proteins, glycoaminoglycans (GAGs) and proteoglycans, while removing sufficient cellular components of the sample to reduce or eliminate antigenicity and immunogenicity for xenograft purposes. The resultant urodele-derived biomaterial can be used to enhance restoration of skin homeostasis, to reduce the severity, durations and associated damage caused by post-surgical inflammation, and to promote progression of natural healing and regeneration processes. In addition, the biomaterial promotes the formation of remodeled tissue that is comparable in quality, function, and compliance to undamaged human tissue.

The present disclosure relates to methods of using a compound to induce regeneration of hematopoietic stem cells or increase the recovery of red blood cells. In some aspects, the present methods can be used to with or in place of erythropoietin in patients to mitigate the side effects of erythropoietin.

A medical adhesive and the preparation method, and application thereof. The medical adhesive is in the form of a gel, which contains a giant salamander skin mucus and an aqueous solution; the ratio parts by weight of the giant salamander skin dried powder and the aqueous solution is 1:1 to 1:6, and the weight content of the giant salamander skin mucus freeze-dried powder in the medical adhesive ranges from 14.2% to 50%. The present invention also provides the preparation method for preparing the aforementioned medical adhesive, and at the same time, the aforementioned medical adhesive is applied for the wound.

A freeze-dried formulation and a preparation method and an application thereof are provided. Triterpenoid saponin has a mass percentage of 0.004-95% in the freeze-dried formulation, a binding agent has a mass percentage of 0.01-99% in the freeze-dried formulation; the freeze-dried formulation is freeze-dried by a primary prepared solution containing the triterpenoid saponin and the binding agent; when the triterpenoid saponin has a mass percentage of 0.001%-50% in the primary prepared solution, the binding agent has a mass percentage of 0.01%-50% in the primary prepared solution, and a mass of the triterpenoid saponin increases with an increase of a mass of the binding agent; and when the triterpenoid saponin has a mass percentage of 50%-95% in the primary prepared solution, the binding agent has a mass percentage of 0.01%-20% in the primary prepared solution, and the mass of triterpenoid saponin decreases with the increase of the mass of the binding agent.

A freeze-dried formulation and a preparation method and an application thereof are provided. Triterpenoid saponin has a mass percentage of 0.004-95% in the freeze-dried formulation, a binding agent has a mass percentage of 0.01-99% in the freeze-dried formulation; the freeze-dried formulation is freeze-dried by a primary prepared solution containing the triterpenoid saponin and the binding agent; when the triterpenoid saponin has a mass percentage of 0.001%-50% in the primary prepared solution, the binding agent has a mass percentage of 0.01%-50% in the primary prepared solution, and a mass of the triterpenoid saponin increases with an increase of a mass of the binding agent; and when the triterpenoid saponin has a mass percentage of 50%-95% in the primary prepared solution, the binding agent has a mass percentage of 0.01%-20% in the primary prepared solution, and the mass of triterpenoid saponin decreases with the increase of the mass of the binding agent.

The growth factor profile, connective tissue matrix constituents, and immunoprivileged status of urodele extracellular matrix (ECM) and accompanying cutaneous tissue, plus the presence of antimicrobial peptides there, render urodele-derived tissue an ideal source for biological scaffolds for xenotransplantation. In particular, a biological scaffold biomaterial can be obtained by a process that entails (A) obtaining a tissue sample from a urodele, where the tissue comprises ECM, inclusive of the basement membrane, and (B) subjecting the tissue sample to a decellularization process that maintains the structural and functional integrity of the extracellular matrix, by virtue of retaining its fibrous and on-fibrous proteins, glycoaminoglycans (GAGs) and proteoglycans, while removing sufficient cellular components of the sample to reduce or eliminate antigenicity and immunogenicity for xenograft purposes. The resultant urodele-derived biomaterial can be used to enhance restoration of skin homeostasis, to reduce the severity, durations and associated damage caused by post-surgical inflammation, and to promote progression of natural healing and regeneration processes. In addition, the biomaterial promotes the formation of remodeled tissue that is comparable in quality, function, and compliance to undamaged human tissue.

The growth factor profile, connective tissue matrix constituents, and immunoprivileged status of urodele extracellular matrix (ECM) and accompanying cutaneous tissue, plus the presence of antimicrobial peptides there, render urodele-derived tissue an ideal source for biological scaffolds for xenotransplantation. In particular, a biological scaffold biomaterial can be obtained by a process that entails (A) obtaining a tissue sample from a urodele, where the tissue comprises ECM, inclusive of the basement membrane, and (B) subjecting the tissue sample to a decellularization process that maintains the structural and functional integrity of the extracellular matrix, by virtue of retaining its fibrous and on-fibrous proteins, glycoaminoglycans (GAGs) and proteoglycans, while removing sufficient cellular components of the sample to reduce or eliminate antigenicity and immunogenicity for xenograft purposes. The resultant urodele-derived biomaterial can be used to enhance restoration of skin homeostasis, to reduce the severity, durations and associated damage caused by post-surgical inflammation, and to promote progression of natural healing and regeneration processes. In addition, the biomaterial promotes the formation of remodeled tissue that is comparable in quality, function, and compliance to undamaged human tissue.

The present invention relates to a method of treating a chemical injury of the eye, in particular alkali burn of the cornea, as well as ocular GVHD and similar inflammatory ocular conditions, with extracellular vesicles, in particular exosomes obtained from human cardiospheres or cardiosphere-derived cells. The present invention also provides a formulation comprising extracellular vesicles, in particular exosomes obtained from human cardiospheres or cardiosphere-derived cells, for subconjunctival or topical administration to the eye in the treatment of a chemical injury of the eye, in particular alkali burn of the cornea, as well as ocular GVHD and similar inflammatory ocular conditions.

The present invention relates to a method of treating a chemical injury of the eye, in particular alkali burn of the cornea, as well as ocular GVHD and similar inflammatory ocular conditions, with extracellular vesicles, in particular exosomes obtained from human cardiospheres or cardiosphere-derived cells. The present invention also provides a formulation comprising extracellular vesicles, in particular exosomes obtained from human cardiospheres or cardiosphere-derived cells, for subconjunctival or topical administration to the eye in the treatment of a chemical injury of the eye, in particular alkali burn of the cornea, as well as ocular GVHD and similar inflammatory ocular conditions.