Damaged leg muscles grew stronger and showed signs of regeneration in
three out of five men whose old injuries were surgically implanted with
extracellular matrix (ECM) derived from pig bladder, according to a new
study conducted by researchers at the University of Pittsburgh School of
Medicine and the McGowan Institute for Regenerative Medicine. Early
findings from a human trial of the process and from animal studies were
published today in Science Translational Medicine.
Pigs (stock image). Damaged leg muscles grew stronger and showed signs
of regeneration in three out of five men whose old injuries were
surgically implanted with extracellular matrix (ECM) derived from pig
bladder, according to a new study.
When a large volume of
muscle is lost, typically due to trauma, the body cannot sufficiently
respond to replace it, explained senior investigator Stephen F. Badylak,
D.V.M., Ph.D., M.D., professor of surgery at Pitt and deputy director
of the McGowan Institute, a joint effort of Pitt and UPMC. Instead, scar
tissue can form that significantly impairs strength and function.
Pig bladder ECM has been used for many years as the basis for medical products for hernia repair and treatment of skin ulcers. It is the biologic scaffold that remains left behind after cells have been removed. Previous research conducted by Dr. Badylak's team suggested that ECM also could be used to regenerate lost muscle by placing the material in the injury site where it signals the body to recruit stem and other progenitor cells to rebuild healthy tissue.
"This new study is the first to show replacement of new functional muscle tissue in humans, and we're very excited by its potential," Dr. Badylak said. "These are patients who can't walk anymore, can't get out of a car, can't get up and down from a chair, can't take steps without falling. Now we might have a way of helping them get better."
For the Muscle Tendon Tissue Unit Repair and Reinforcement Reconstructive Surgery Research Study, which is sponsored by the U.S. Department of Defense and is continuing to enroll new participants, five men who had at least six months earlier lost at least 25 percent of leg muscle volume and function compared to the uninjured limb underwent a customized regimen of physical therapy for 12 to 26 weeks until their function and strength plateaued for a minimum of two weeks.
Then, study lead surgeon J. Peter Rubin, M.D., UPMC Professor and chair of plastic surgery, Pitt School of Medicine, surgically implanted a "quilt" of compressed ECM sheets designed to fill into their injury sites. Within 48 hours of the operation, the participants resumed physical therapy for up to 26 additional weeks.
The researchers found that three of the participants, two of whom had thigh injuries and one a calf injury, were stronger by 20 percent or more six months after the surgery. One thigh-injured patient improved on the "single hop test" by 1,820 percent, and the other had a 352 percent improvement in a chair lift test and a 417 percent improvement in the single-leg squat test. Biopsies and scans all indicated that muscle growth had occurred. Two other participants with calf injuries did not have such dramatic results, but both improved on at least one functional measure and said they felt better.
"This work represents an important step forward in our ability to repair tissues and improve function with materials derived from natural proteins. There will be more options to help our patients," Dr. Rubin said.
The study also showed six months after an injury, mice treated with ECM showed signs of new muscle growth while untreated mice appeared to form typical scars.
Pig bladder ECM has been used for many years as the basis for medical products for hernia repair and treatment of skin ulcers. It is the biologic scaffold that remains left behind after cells have been removed. Previous research conducted by Dr. Badylak's team suggested that ECM also could be used to regenerate lost muscle by placing the material in the injury site where it signals the body to recruit stem and other progenitor cells to rebuild healthy tissue.
"This new study is the first to show replacement of new functional muscle tissue in humans, and we're very excited by its potential," Dr. Badylak said. "These are patients who can't walk anymore, can't get out of a car, can't get up and down from a chair, can't take steps without falling. Now we might have a way of helping them get better."
For the Muscle Tendon Tissue Unit Repair and Reinforcement Reconstructive Surgery Research Study, which is sponsored by the U.S. Department of Defense and is continuing to enroll new participants, five men who had at least six months earlier lost at least 25 percent of leg muscle volume and function compared to the uninjured limb underwent a customized regimen of physical therapy for 12 to 26 weeks until their function and strength plateaued for a minimum of two weeks.
Then, study lead surgeon J. Peter Rubin, M.D., UPMC Professor and chair of plastic surgery, Pitt School of Medicine, surgically implanted a "quilt" of compressed ECM sheets designed to fill into their injury sites. Within 48 hours of the operation, the participants resumed physical therapy for up to 26 additional weeks.
The researchers found that three of the participants, two of whom had thigh injuries and one a calf injury, were stronger by 20 percent or more six months after the surgery. One thigh-injured patient improved on the "single hop test" by 1,820 percent, and the other had a 352 percent improvement in a chair lift test and a 417 percent improvement in the single-leg squat test. Biopsies and scans all indicated that muscle growth had occurred. Two other participants with calf injuries did not have such dramatic results, but both improved on at least one functional measure and said they felt better.
"This work represents an important step forward in our ability to repair tissues and improve function with materials derived from natural proteins. There will be more options to help our patients," Dr. Rubin said.
The study also showed six months after an injury, mice treated with ECM showed signs of new muscle growth while untreated mice appeared to form typical scars.
Journal Reference:
- B. M. Sicari, J. P. Rubin, C. L. Dearth, M. T. Wolf, F. Ambrosio, M. Boninger, N. J. Turner, D. J. Weber, T. W. Simpson, A. Wyse, E. H. P. Brown, J. L. Dziki, L. E. Fisher, S. Brown, S. F. Badylak. An Acellular Biologic Scaffold Promotes Skeletal Muscle Formation in Mice and Humans with Volumetric Muscle Loss. Science Translational Medicine, 2014; 6 (234): 234ra58 DOI: 10.1126/scitranslmed.3008085
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