Despite clinical and experimental reports of digit tip regrowth, bone regrowth after amputation through terminal phalanges has not been methodically documented. We have examined bone regrowth in mice after amputation through the terminal phalanx to determine how the level of amputation affects the response and whether the response varies between adults and neonates. Digit tips were amputated, and, at selected intervals greater than 5 weeks after amputation, digits were photographed and processed for whole mount staining with alizarin red stain. Amputations within the distal 40% of the terminal phalanx yielded grossly normal digits within 5 weeks and bone regrowth which usually attained or surpassed the original length. Amputations through the proximal 20% of the distal phalanx precluded nail plate regrowth, and bone grew minimally or regressed. Amputation through the intermediate 40% of the distal phalanx produced digit tips in which bone regrowth was correlated with nail regrowth and in which bone regrowth did not reach original levels. The response in adults and neonates was similar. The correlation between nail regrowth and bone regrowth may help to predict phalangeal bone regrowth after amputation in adults and juveniles.
In tissue engineering, it is important to fabricate a three-dimensional scaffold that resemble the extracellular matrix (ECM) and topographical appearance of native tissue. The aim of this study is to test the hypothesis that varying microstructures of electrospun fibrous scaffolds by manipulating the relative degree of fiber alignment would influence the behaviors of porcine annulus fibrosus cells. Five types of electrospun fibrous scaffolds with polycaprolactone fibers having random or partially aligned arrangements have been prepared and investigated. The scaffold microstructures have been examined, and in vitro experiments have been carried out to assess cell-material interaction, cell proliferation, and ECM production. The results indicate that the scaffold with oriented fibers provides strong guidance to the cell orientation and ECM distribution. In addition, albeit the tensile moduli of electrospun fibrous scaffolds are lower than that of native tissue, they are comparable to those reported in literature; hence, the constructs cultured with optimized conditions including the scaffold material selection and dynamic mechanical conditioning would have the potential to possess the moduli closer to that of native tissue. © 2011 Wiley Periodicals, Inc. J Biomed Mater Res Part A, 2011.
Recent studies of postamputational repair following digit-tip amputation revealed an unexpected correlation between nail regrowth and bone regrowth in mice. To examine putative effects of nail on bone regrowth, phalangeal tips were amputated such that nail was artificially removed from distal levels or retained following proximal level amputations. In the absence of nail, bone did not regrow at distal levels. Conversely, when nail was surgically retained bone regrew from proximal levels. The nail organ profoundly influences bone regrowth.
The annulus fibrosus comprises concentric lamellae that can be damaged due to intervertebral disc degeneration; to provide permanent repair of these acquired structural defects, one solution is to fabricate scaffolds that are designed to support the growth of annulus fibrosus cells. In this study, electrospun nanofibrous scaffolds of polycaprolactone are fabricated in random, aligned, and round-end configurations. Primary porcine annulus fibrosus cells are grown on the scaffolds and evaluated for attachment, proliferation, and production of extracellular matrix. The scaffold consisting of round-end nanofibers substantially outperforms the random and aligned scaffolds on cell adhesion; additionally, the scaffold with aligned nanofibers strongly affects the orientation of cells.
Mammals are able to regrow the tips of amputated fingers and toes. However, regrowth is limited to regions covered by, and is dependent upon, the presence of the nail organ. If the nail organ is responsible for bone growth in digit-tips, we reasoned that transplanted nail organ might also be able to induce outgrowth from other levels of the digit. Partial nail organ has been transplanted to amputated proximal phalanges of young rats. To date, six transplants have successfully produced outgrowth of nail. New bone growth, not seen in control amputated digits, was documented by x-ray and by alizarin red and calcein injections to be directed toward implanted nail organ. These results support an inductive role for nail organ epithelium in bone growth after amputation and provide encouragement for attempts to enhance a positive outcome after appendage amputation.
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