Laboratory animals are an important part of life sciences and medical researches, as well an important support for the science and technology innovation in our country. Laboratory animal science is of great significance to the protection of human health,food safety and biological safety. Laboratory animals are indispensable in the development of food safety,drugs,vaccines and biological products and the studies of human disease pathogenesis. In order to adapt to the requirements for overall development of the laboratory animal industry in China, our institute has independently developed the Network Training System for Laboratory Animal Managers. This system is an online education and training platform which integrates the practical operation and theoretical knowledge of laboratory animals,including seven knowledge modules such as animal welfare,animal breeding,animal surgery and so on. The training subjects of the system include managers, experiment operators, laboratory animal doctors and breeders, aimed at accelerating the personnel training and team building of laboratory animal sciences,and promoting the transformation and development of personnel training in laboratory animal industry.

Bone diseases, such as osteoporosis and osteoarthritis, have emerged as pressing public health concerns requiring immediate attention and resolution. Cellular therapy and tissue engineering techniques are among the most promising therapeutic approaches for such conditions. Human induced pluripotent stem cells (hiPSCs) possess remarkable capacity for indefinite self-renewal in vitro and the ability to differentiate into all somatic cell types originating from the three germ layers, thereby making them a promising source of osteoblasts. Consequently, it is crucial to establish a well-delineated system for osteogenic differentiation of hiPSCs in vitro, with the aim to generate osteoblast-like cells that conform to clinical application standards. Numerous research teams have achieved substantial advancements in both the direct osteogenic differentiation of hiPSCs and the indirect pathway via mesenchymal stem cells. In this article, we provide a comprehensive review of these two osteogenic differentiation pathways and their current applications, with the aim of serving as a valuable reference for bone regeneration technologies. Current research efforts have relied on embryoid body formation and monolayer induction methods utilizing biomaterials to develop a system that facilitates in vitro culture and osteogenic differentiation of hiPSCs. However, the existing research is primarily constrained by unclear system components and low efficiency. Therefore, the development of a stepwise and three-dimensional induction system based on stringent regulation by specific compounds is a primary research direction for the future.