A research team from Korea now investigate the link between environmental enrichment and neurobehavioral function post transplantation of stem cells to treat brain injury.
The post-transplantation environmental enrichment (EE) included use of a running wheel and exposure to "novel objects."
The study appears as an early e-publication for the journal Cell Transplantation
"FGF2 was synergistically enhanced in the striata of mice treated with EE after ASC transplantation," said study co-author Dr. Sung-Rae Cho of the Yonsei University College of Medicine in Seoul, Korea. "The underlying mechanisms of this synergism included an enhanced repair process, such as higher engraftment of the transplanted ASCs, increased endogenous neurogenesis, and astrocytic activation coupled with the increase in FGF2."
Astrocytes, star-shaped brain cells that are also the most abundant brain cell, perform many functions, including supporting the cells that form the blood-brain barrier and providing nutrients for nervous system tissue. Multipotent ASCs have been used for promoting angiogenesis (blood vessel growth) and are also known to secrete potentially beneficial growth factors.
"Hypoxic-ischemic brain injury is a major cause of damage to the fetal and neonatal brain," said Dr. Cho. "The majority of affected children demonstrate neurodevelopment impairment. However, cell-based therapy has emerged as a potential treatment. In this study we applied EE in the chronic stage of impairment and studied its synergistic effects in the test mice at six weeks, five weeks after induced brain injury."
The authors noted that cerebral palsy has been associated with hypoxic brain injury, resulting in "considerable incidence or morbidity." They also noted that exercise has shown to be beneficial to children with CP. However, they also reported that ASC transplantation in animal models of CP has yet to be studied.
The researchers concluded that, compatible with other studies, EE increases endogenous cell migration to an ischemic injury and facilitates functional repair.
"The role of FGF2 as a mediator of the effects of exercise on the brain, and that FGF2 can be induced by physical exercise and regulated in an activity-dependent fashion, raises the possibility that FGF2 is involved in behavioral function," explained Dr. Cho. "We propose that the increase in FGF2 may provide a favorable microenvironment for repair purposes, and thus contribute to functional recovery."
They concluded that a rehabilitative strategy of cell-based therapy coupled with environmental enrichment could be effective for treating CP and other neurological diseases, including adult stroke.
"This study highlights the potential impact that combination therapies, such as stem cell transplantation and rehabilitation, could have on brain disorders, possibly due to their interaction with survival or integration of the implanted cells or to modulation of the host microenvironment," said Prof Stephen Dunnett of Cardiff University's Brain Repair Group, "but it is important to emphasise that such initial observations are a very long way from yet providing a clinical therapy. We still need to understand the mechanisms by which implanted cells and growth factors work together to enhance functional recovery, we need better animal models to test the cells that are directly relevant to the specific human disorder targeted, and there are profound technical and safety issues still to be resolved before such novel stem cell strategies can be used safely in first-in-man clinical trials".