Abstract: The present invention relates to a novel peptide derived from the copine 7 protein and having both cell permeability and bone tissue regeneration ability, and to a use of the peptide. The peptide according to the present invention has excellent bone tissue regeneration ability and is therefore useful for treating a disease requiring bone regeneration, such as osteoporosis. Particularly, by also having cell permeability, the peptide does not require the attachment of a separate peptide or addition of another preparation for the cell permeation thereof and thus can be conveniently applied in orthopedics and the like requiring various surgical regeneration treatments.

Abstract: Disclosed are a bifunctional peptide having the capability to reduce inflammation and the capability to facilitate differentiation of stem cells into chondrocytes and the use thereof. Advantageously, the bifunctional peptide is useful for the prevention or treatment of arthritis accompanied by inflammation and damage of cartilage tissue due to excellent effects of reducing inflammation and facilitating differentiation of stem cells into chondrocytes, can be easily applied to various surgical regenerative treatments including orthopedic treatments, and can shorten the treatment period.

Abstract: Disclosed are a bifunctional peptide having the capability to permeate cells and the capability to regenerate muscles and the use thereof. Advantageously, the bifunctional peptide has a function of regenerating muscle cells and thus is useful for the prevention or treatment of diseases affecting muscle regeneration, and additionally has the capability to permeate cells and thus eliminates the necessity to adhere an additional peptide or add other agent or drug for cell permeation of the peptide, thereby finally exerting an efficient muscle generation effect. Thus, the bifunctional peptide can be easily applied to various surgical regenerative treatments and can shorten the treatment period.

Abstract: The present invention relates to a peptide having the ability to bind specifically to the surface of titanium. The titanium-binding peptide according to the present invention is fixed securely to the titanium surface so that the activity of a physiologically active substance linked to the peptide can be stably maintained over a long period of time. Thus, the peptide can be effectively used for surgical regeneration therapy.

Abstract: Provided are a tissue structure mimetic used for regenerating a tissue and a method for manufacturing the same, and more particularly, a 3-dimensional tissue structure mimetic which consists of a complex of extracellular matrix protein and bone mineral, wherein the complex is specifically bound to a regeneration-functional peptide to thereby be capable of implementing environment of a tissue requiring restoration, and a method for manufacturing the same. In the tissue structure mimetic according to the present invention, bone mineral components are finely dispersed in the extracellular matrix protein to have excellent mechanical strength of the tissue structure mimetic and conductivity which provides a migration path of cells involved in tissue regeneration. Further, environment of the tissue may be implemented by the peptide contained in the tissue structure mimetic to finally remarkably increase tissue regeneration capacity.

Abstract: The disclosure relates to a fat accumulation inhibitory peptide which essentially comprises an amino acid sequence represented by SEQ ID NO: 1, a pharmaceutical composition for preventing or treating obesity, which contains the peptide, and a health functional food for preventing or alleviating obesity, which contains the peptide. The fat accumulation inhibitory peptide according to the present invention has the function of inhibiting the differentiation of mesenchymal stem cells into adipocytes to thereby inhibit the accumulation of adipose tissue. Thus, the peptide according to the present invention is highly useful for the prevention or treatment of obesity.

Abstract: The present invention relates to a peptide having the ability to bind specifically to the surface of titanium. The titanium-binding peptide according to the present invention is fixed securely to the titanium surface so that the activity of a physiologically active substance linked to the peptide can be stably maintained over a long period of time. Thus, the peptide can be effectively used for surgical regeneration therapy.

Abstract: Provided is a method of preparing induced pluripotent stem cells using a synthetic peptide, and more particularly, to a method of preparing induced pluripotent stem cells using a peptide capable of inhibiting the activity of NF-?B and promoting mesenchymal-epithelial transition (MET). Since undifferentiated multipotent stem cells may be efficiently prepared under xenopathogen-free or feeder cell-free conditions without requiring co-culture with animal serum or xenogeneic cells, the method for preparing the induced pluripotent stem cells using the synthetic peptide according to the present disclosure is very useful for developing stem cell therapeutic agents that are clinically applicable.

Abstract: The present invention relates to an anticancer composition comprising a peptide that inhibits the proliferation of cancer stem cells present in tumor tissue and that induces apoptosis of such cancer stem cells, and more particularly, to an anticancer peptide that inhibits the activity of NF-?B which is overexpressed specifically in cancer stem cells present in tumors.

Abstract: The disclosure relates to a fat accumulation inhibitory peptide which essentially comprises an amino acid sequence represented by SEQ ID NO: 1, a pharmaceutical composition for preventing or treating obesity, which contains the peptide, and a health functional food for preventing or alleviating obesity, which contains the peptide. The fat accumulation inhibitory peptide according to the present invention has the function of inhibiting the differentiation of mesenchymal stem cells into adipocytes to thereby inhibit the accumulation of adipose tissue. Thus, the peptide according to the present invention is highly useful for the prevention or treatment of obesity.

Abstract: The present invention relates to a peptide that binds specifically to the surface of zirconia, and more particularly, to a peptide conjugate obtained by linking a functional drug to the peptide so as to enable the drug to be securely fixed to the surface of zirconia to thereby maintain the activity of the drug over a long period of time. The zirconia-binding peptide according to the present invention can be securely fixed to the surface of zirconia so that the activity of a physiologically active substance introduced into the peptide can be maintained on the zirconia surface over a long period of time. Thus, the zirconia-binding peptide is useful for surgical regenerative treatment.

Abstract: The present invention relates to a peptide that binds specifically to the surface of zirconia, and more particularly, to a peptide conjugate obtained by linking a functional drug to the peptide so as to enable the drug to be securely fixed to the surface of zirconia to thereby maintain the activity of the drug over a long period of time. The zirconia-binding peptide according to the present invention can be securely fixed to the surface of zirconia so that the activity of a physiologically active substance introduced into the peptide can be maintained on the zirconia surface over a long period of time. Thus, the zirconia-binding peptide is useful for surgical regenerative treatment.

Abstract: Provided is a method of preparing induced pluripotent stem cells using a synthetic peptide, and more particularly, to a method of preparing induced pluripotent stem cells using a peptide capable of inhibiting the activity of NF-?B and promoting mesenchymal-epithelial transition (MET). Since undifferentiated multipotent stem cells may be efficiently prepared under xenopathogen-free or feeder cell-free conditions without requiring co-culture with animal serum or xenogeneic cells, the method for preparing the induced pluripotent stem cells using the synthetic peptide according to the present disclosure is very useful for developing stem cell therapeutic agents that are clinically applicable.

Abstract: A method of preparing a reprogramming induced pluripotent stem cell from a human-derived somatic cell using a fusion protein in which a reprogramming inducing factor and cell permeable peptide (CPP) are fused, and a fusion protein in which a reprogramming inducing factor and a cell permeable peptide are fused are disclosed. According to the present invention, the induced pluripotent stem cell having high efficiency and high stability can be prepared by maximizing the effect of the reprogramming inducing transcription factor beyond the existing viral peptide transporter, in inducing the reprogramming of the somatic cell.

Abstract: The present invention relates to an anticancer composition comprising a peptide that inhibits the proliferation of cancer stem cells present in tumor tissue and that induces apoptosis of such cancer stem cells, and more particularly, to an anticancer peptide that inhibits the activity of NF-?B which is overexpressed specifically in cancer stem cells present in tumors.

Abstract: The present invention relates to a fat accumulation inhibitory peptide which essentially comprises an amino acid sequence represented by SEQ ID NO: 1, a pharmaceutical composition for preventing or treating obesity, which contains the peptide, and a health functional food for preventing or alleviating obesity, which contains the peptide. The fat accumulation inhibitory peptide according to the present invention has the function of inhibiting the differentiation of mesenchymal stem cells into adipocytes to thereby inhibit the accumulation of adipose tissue. Thus, the peptide according to the present invention is highly useful for the prevention or treatment of obesity.

Abstract: The present invention relates to a cell permeable fusion protein for strengthening regenerative potential of stem cells, and more particularly to a cell permeable fusion protein for strengthening regenerative potential of stem cells for stimulating the differentiation of stem cells, inhibiting apoptosis, maintaining the functionality of stem cells and restoring the stress-inhibited functionality of stem cells.

Abstract: Provided are a tissue structure mimetic used for regenerating a tissue and a method for manufacturing the same, and more particularly, a 3-dimensional tissue structure mimetic which consists of a complex of extracellular matrix protein and bone mineral, wherein the complex is specifically bound to a regeneration-functional peptide to thereby be capable of implementing environment of a tissue requiring restoration, and a method for manufacturing the same. In the tissue structure mimetic according to the present invention, bone mineral components are finely dispersed in the extracellular matrix protein to have excellent mechanical strength of the tissue structure mimetic and conductivity which provides a migration path of cells involved in tissue regeneration. Further, environment of the tissue may be implemented by the peptide contained in the tissue structure mimetic to finally remarkably increase tissue regeneration capacity.

Abstract: A collagen membrane having fusion protein bound thereto is described, in which the fusion protein includes collagen binding peptide and antibacterial peptide. The collagen membrane is usefully employed in vivo to promote cell migration, proliferation, and differentiation associated with bone tissue regeneration, for bone induction and regeneration. The fusion protein may also be applied to other collagenic graft materials, for use as a biomaterial for regenerating other tissues such as the skin.

Abstract: The present invention relates to a novel human-derived cell permeable peptide-bioactive peptide conjugate and the use thereof. According to the present invention, cationic cell permeable peptides derived from human bone morphogenetic protein-4 have no toxicity and immunogenicity and thus exhibit high stability as compared to viral peptide delivery vehicles, and can transport cell impermeable material into cells and into an organism without any damage to cell or material, thereby significantly increasing target gene expression. In addition, the peptide may be applied to clinical use without having to undergo a large number of processes and mass-produced, such that the present invention may be useful in the development of a drug delivery system and treatment technologies using said peptide.