scientist exploring regenerative cells as Salmander who regenerate completely
Prof Dr,DRAM,HIV /AIDS,HEPATITIS ,SEX DISEASES & WEAKNESS expert,New Delhi,India, +917838059592
The answer to regenerative medicine's most compelling question -- why some organisms can regenerate major body parts such as hearts and limbs while others, such as humans, cannot -- may lie with the body's innate immune system, according to a new study of heart regeneration in the axolotl, or Mexican Ambhibian -Salamander, an organism that can regenerate heat,eyes,limbs completely takes the prize as nature's champion of regeneration.
The study, which was conducted by James Godwin, Ph.D., of the MDI Biological Laboratory in Bar Harbor, Maine, found that the formation of new heart muscle tissue in the adult axolotl after an artificially induced heart attack is dependent on the presence of macrophages, a type of white blood cell. When macrophages were depleted, the salamanders formed permanent scar tissue that blocked regeneration.The study has significant implications for human health. Since salamanders and humans have evolved from a common ancestor, it's possible that the ability to regenerate is also built into our genetic code.
The study found that the formation of new heart muscle tissue in the adult axolotl after an artificially induced heart attack is dependent on the presence of macrophages, a type of white blood cell. When macrophages were depleted, the salamanders formed permanent scar tissue that blocked regeneration.
Godwin's research demonstrates that scar formation plays a critical role in blocking the program for regeneration. "The scar shoots down the program for regeneration," he said. "No macrophages means no cardiac regeneration."Godwin's goal is to activate regeneration in humans through the use of drug therapies derived from macrophages that would promote scar-free healing directly, or those that would trigger the genetic programs controlling the formation of macrophages, which in turn could promote scar-free healing. His team is already looking at molecular targets for drug therapies to influence these genetic programs.
The next step is to study the function of macrophages in salamanders and compare them with their human and mouse counterparts. Ultimately, Godwin would like to understand why macrophages produced by adult mice and humans don't suppress scarring in the same way as in axolotls and then identify molecules and pathways that could be exploited for human therapies