When RCGD 423 was applied to joint
cartilage cells in the laboratory, the cells proliferated more and died less, and when injected into the knees of rats with damaged cartilage, the animals could more effectively heal their injuries.
In a
laboratory dish — and, presumably, also inside the body — these
cells readily multiply and give rise to various structural
cells, such as fat, muscle, bone, tendon, ligament and
cartilage.
Previous studies from the
laboratory of Daniel B. F. Saris (University Medical Center Utrecht, The Netherlands) reported that a novel stem
cell combination represented a safe and efficient means to repair
cartilage in preclinical [1] and early clinical studies [2].
In a study using human muscle tissue, scientists in Children's Stem Cell Research Center - led by Johnny Huard, PhD, and Bruno Péault, PhD - isolated and characterized stem cells taken from blood vessels (known as myoendothelial cells) that are easily isolated using cell - sorting techniques, proliferate rapidly and can be differentiated in the laboratory into muscle, bone and cartilage cell
In a study using human muscle tissue, scientists
in Children's Stem Cell Research Center - led by Johnny Huard, PhD, and Bruno Péault, PhD - isolated and characterized stem cells taken from blood vessels (known as myoendothelial cells) that are easily isolated using cell - sorting techniques, proliferate rapidly and can be differentiated in the laboratory into muscle, bone and cartilage cell
in Children's Stem
Cell Research Center - led by Johnny Huard, PhD, and Bruno Péault, PhD - isolated and characterized stem cells taken from blood vessels (known as myoendothelial cells) that are easily isolated using cell - sorting techniques, proliferate rapidly and can be differentiated in the laboratory into muscle, bone and cartilage ce
Cell Research Center - led by Johnny Huard, PhD, and Bruno Péault, PhD - isolated and characterized stem
cells taken from blood vessels (known as myoendothelial
cells) that are easily isolated using
cell - sorting techniques, proliferate rapidly and can be differentiated in the laboratory into muscle, bone and cartilage ce
cell - sorting techniques, proliferate rapidly and can be differentiated
in the laboratory into muscle, bone and cartilage cell
in the
laboratory into muscle, bone and
cartilage cells.
Research done by the Comparative Orthopaedics
Laboratory allowed the continued application of cartilage cell transplantation to the human knee; by early 2004 over 10,000 cartilage cell transplantation procedures had been performed in the United States using techniques validated by the l
Laboratory allowed the continued application of
cartilage cell transplantation to the human knee; by early 2004 over 10,000
cartilage cell transplantation procedures had been performed
in the United States using techniques validated by the
laboratorylaboratory.