Abstract: The present invention relates to a nano-ligand for promoting cell adhesion and regeneration of macrophages and a method of promoting cell adhesion and regeneration of macrophages by using the nano-ligand. The method of promoting cell adhesion and regeneration of macrophages according to the present invention applies a magnetic field to a substrate including the nano-ligand, so that it is possible to reversely control the sliding of the nano-ligand, as well as temporally and spatially control the sliding of the nano-ligand, and efficiently control cell adhesion and phenotypic polarization of macrophages in vivo or ex vivo through the magnetic field-based spatiotemporal control.

Abstract: The present invention relates to a nano-ligand for promoting cell adhesion and differentiation of stem cells and a method of promoting cell adhesion and differentiation of stem cells by using the nano-ligand, and the method of promoting cell adhesion and differentiation of stem cells according to the present invention may temporally and spatially, and reversibly control nano-ligand sliding by applying a magnetic field to a substrate including the nano-ligands, and efficiently control stem cell adhesion and differentiation ex vivo or in vivo through the magnetic-field based on spatiotemporal control.

Abstract: Disclosed is a self-assembled complex containing a calcium ion that includes a calcium ion; and at least one ligand, where the calcium ion and the ligand participate in a reversibly self-assembly or self-disassembly. The shape of the self-assembled complex varies depending on the type of the ligand, or the mixing ratio of the ligand when there are a plurality of ligands.

Abstract: Disclosed is a self-assembled complex containing an iron ion that includes an iron ion; and at least one ligand, where the iron ion and the ligand are reversibly self-assembled or self-disassembled. The iron ion and the ligand are self-assembled to form an assembly structure at least part of which is round shaped.

Abstract: The present invention relates to a nano-ligand for promoting cell adhesion and differentiation of stem cells and a method of promoting cell adhesion and differentiation of stem cells by using the nano-ligand, and the method of promoting cell adhesion and differentiation of stem cells according to the present invention may temporally and spatially, and reversibly control nano-ligand sliding by applying a magnetic field to a substrate including the nano-ligands, and efficiently control stem cell adhesion and differentiation ex vivo or in vivo through the magnetic-field based on spatiotemporal control.

Abstract: Discloses is a technology of collecting a biological sample, delivering a substance into a living body, and regulating macrophage adhesion and polarization, by controlling a self-assembled complex and a nanosystem including the same by irradiation with light.

Abstract: The present invention relates to a nanosatellite-substrate complex capable of regulating stem cell adhesion and differentiation, and a method for preparing the same. Moreover, the present invention relates to a method of regulating stem cell adhesion and differentiation by applying a magnetic field to the nanosatellite-substrate complex.

Abstract: The present invention relates to a nanobarrier for regulating macrophage adhesion and polarization. Moreover, the present invention relates to a method of regulating macrophage adhesion and polarization using the nanobarrier. According to the nanobarrier of the present invention and the method of regulating macrophage adhesion and polarization using the same, it is possible to efficiently regulate macrophage adhesion and polarization by applying a magnetic field to the nanobarrier.

Abstract: The present invention relates to an effective component delivery system using self-assembly and self-disassembly of a self-assembled complex, and the effective component delivery system uses a self-assembled complex which is composed of substances existing in the body, thereby being less toxic and harmless to the human body, and the effective component delivery system is capable of controlling a self-disassembly rate and an effective component release rate by using various kinds of metal ions and ligands including phosphate or phosphonate.

Abstract: The present invention relates to a nano-ligand for promoting cell adhesion and regeneration of macrophages and a method of promoting cell adhesion and regeneration of macrophages by using the nano-ligand. The method of promoting cell adhesion and regeneration of macrophages according to the present invention applies a magnetic field to a substrate including the nano-ligand, so that it is possible to reversely control the sliding of the nano-ligand, as well as temporally and spatially control the sliding of the nano-ligand, and efficiently control cell adhesion and phenotypic polarization of macrophages in vivo or ex vivo through the magnetic field-based spatiotemporal control.

Abstract: The present invention relates to a nano-ligand for promoting cell adhesion and differentiation of stem cells and a method of promoting cell adhesion and differentiation of stem cells by using the nano-ligand, and the method of promoting cell adhesion and differentiation of stem cells according to the present invention may temporally and spatially, and reversibly control nano-ligand sliding by applying a magnetic field to a substrate including the nano-ligands, and efficiently control stem cell adhesion and differentiation ex vivo or in vivo through the magnetic-field based on spatiotemporal control.