Deep dermal burn injury results in scarless wound healing in the ovine fetus

Early to mid-term fetuses heal cutaneous incisional wounds without scars; however, fetal response to burn injury has not been ascertained. We present a fetal model of thermal injury and subsequent analysis of fetal and lamb response to burn injury. A reproducible deep dermal burn injury was created in the fetus by application of water at 66 degrees C for 7 seconds, and at 82 degrees C for 10 seconds to the lamb. Macroscopically, the area of fetal scald was undetectable from day 7 post injury, while all lamb scalds were readily identified and eventually healed with scarring. Using a five-point histopathology scoring system for alteration in tissue morphology, differences were detected between control and scalded skin at all stages in lamb postburn, but no difference was detected in the fetal model after day 7. There were also large differences in content of alpha-smooth muscle actin and transforming growth factor-beta 1 between control and scalded lamb and these differences were statistically significant at day 14 (P < 0.01). This novel model of fetal and lamb response to deep dermal injury indicates that the fetus heals a deep burn injury in a scarless fashion. Further elucidation of this specific fetal process of burn injury repair may lead to improved outcome for patients with burn injury.

A role for Rho in smooth muscle phenotypic regulation

The role of the small GTP-binding protein Rho in the process of smooth muscle cell (SMC) phenotypic modulation was investigated using cultured rabbit aortic SMCs. Both Rho transcription and Rho protein expression were high for the first 3 days of culture (contractile state cells), with expression decreasing after change to the synthetic state and peaking upon return to the contractile phenotype. Activation of Rho (indicated by translocation to the membrane) also peaked upon return to the contractile state and was low in synthetic state SMCs. Transient transfection of synthetic state rabbit SMCs with constitutively active Rho (val14rho) caused a dramatic decrease in cell size and reorganization of cytoskeletal proteins to resemble those of the contractile phenotype; alpha-actin and myosin adopted a tightly packed, highly organized arrangement, whereas vimentin localized to the immediate perinuclear region and focal adhesions were enlarged. Conversely, specific inhibition of endogenous Rho, by expression of C3 transferase, resulted in the complete loss of actin and myosin filaments without affecting the distribution of vimentin. Focal adhesions were reduced in number. Thus, Rho plays a key role in regulating SMC phenotypic expression.

Rho and smooth muscle cell phenotype

Smooth muscle cell (SMC) phenotypic modulation from the mature ’contractile’ to a less differentiated ’synthetic’ phenotype involves not only altered expression but also a reorganisation of contractile and cytoskeletal proteins. Objective: To investigate the role of RhoA, a known regulator of the actin cytoskeleton, in SMC phenotypic regulation. Methods: Rho transcription (RT-PCR), expression (Western analysis) and activation (membrane translocation or Rho ’pull-down’ assay) was investigated in cultured rabbit aortic SMC during phenotypic modulation, and under the influence of known SM-regulatory proteins (thrombin, heparin and TGF- β). Rho’s effect on cell morphology was examined by transient transfection of ’synthetic’ state SMC with either constitutively active Rho (Val14RhoA) or its inhibitor, C3 transferase. Results: RhoA transcription was elevated in the first 3 days of primary culture, and protein expression peaked at 2 days post-confluence when SMC return to a more ’contractile’ state. However, RhoA showed augmented activation at three time-points in primary culture: the transition point when SMCs enter logarithmic growth and are highly motile, upon reaching quiescence, and when they return to a more ’contractile’ state. Thrombin, heparin and TGF-β activated RhoA in ’synthetic’ state SMCs. Transfection with Val14RhoA caused a dramatic decrease in SMC size and a reorganization of cytoskeletal proteins, reminiscent of the ’contractile’ phenotype. Specific inhibition of endogenous Rho by C3 transferase resulted in an almost complete loss of contractile proteins. Conclusion: These data indicate that Rho is an important determining factor of SMC functional state.

Dog peritoneal and pleural cavities as bioreactors to grow autologous vascular grafts

Objective: The purpose of this study was to grow artificial blood vessels for autologous transplantation as arterial interposition grafts in a large animal model (dog). Method and results: Tubing up to 250 mm long, either bare or wrapped in biodegradable polyglycolic acid (Dexon) or nonbiodegradable polypropylene (Prolene) mesh, was inserted in the peritoneal or pleural cavity of dogs, using minimally invasive techniques, and tethered at one end to the wall with a loose suture. After 3 weeks the tubes and their tissue capsules were harvested, and the inert tubing was discarded. The wall of living tissue was uniformly 1-1.5 mm thick throughout its length, and consisted of multiple layers of myofibroblasts and matrix overlaid with a single layer of mesothelium. The myofibroblasts stained for a-smooth muscle actin, vimentin, and desmin. The bursting strength of tissue tubes with no biodegradable mesh scaffolds was in excess of 2500 mm Hg, and the suture holding strength was 11.5 N, both similar to that in dog carotid and femoral arteries. Eleven tissue tubes were transplanted as interposition grafts into the femoral artery of the same dog in which they were grown, and were harvested after 3 to 6.5 months. Eight remained patent during this time. At harvest, their lumens were lined with endothelium-like cells, and wall cells stained for alpha-actin, smooth muscle myosin, desmin and smoothelin; there was also a thick adventitia containing vasa vasorum. Conclusion: Peritoneal and pleural cavities of large animals can function as bioreactors to grow myofibroblast tubes for use as autologous vascular grafts.