*Note: For the investigational use of Adipose-Derived Stem Cells (ADSC’s) for clinical research and deployment.
Muscular dystrophy (MD) is a disease characterized by progressive skeletal muscle weakness, defects in muscle proteins (dystrophin concentration is greatly reduced), and the death of muscle cells and tissue. Diagnosis is based on muscle biopsy, laboratory evaluation (increased levels of creatine phosphokinase) and EMG findings. There are nine major types of MD and most types of MD are multi-system disorders with manifestations in body systems including the heart, gastrointestinal system, nervous system, endocrine glands, eyes, and brain. MD has a strong genetic link. Treatment options are limited. There has been a keen interest in using stem cells to regenerate muscle tissue and there has been a success in using human stem cells for MD in mice. There is hope that adipose-derived stem cells may be effective in regenerating muscle damaged by MD.
Stem Cells And Muscular Dystrophy
There are a number of different types of stem cells that scientists think may be used in different ways to develop treatments for muscular dystrophy. The main stem-cell-based approaches currently being investigated are:
Producing healthy muscle fibers: Scientists hope that if stem cells without the genetic defect that causes DMD can be delivered to patients’ muscles, they may generate working muscle fibers to replace the patient’s damaged ones.
Reducing inflammation: In muscular dystrophy, damaged muscles become very inflamed. This inflammation speeds up muscle degeneration. Scientists believe certain types of stem cells may release chemicals that reduce inflammation, slowing the progress of the disease.
Regenerative Cell Medicine has developed a specific SVF deployment protocol that attempts to utilize the potential regenerative properties of SVF (rich in mesenchymal stem cells and growth factors). SVF is systemically deployed and is expected to hone to damaged areas preferentially. This is all done as an outpatient at the time of SVF harvesting and procurement. The entire cellular surgical procedure takes approximately three hours.