The force generated in granulation tissue during wound contraction is thought to be cell mediated; however, it is unclear whether contractile forces are generated by fibroblast locomotion or contraction of myofibroblasts. To help clarify this question the force of this contraction can now be determined accurately in a human dermal fibroblast collagen lattice system using a novel instrument known as a Culture Force Monitor. Three distinct phases of contraction of such collagen gels could be identified over the first 24 hours. Most of the force generated by human dermal fibroblasts was produced during the first stage in parallel with cell attachment and associated changes in cell shape, and the appearance of cell processes. During this initial 24 hours no evidence could be found for the presence of myofibroblasts, but stereoscopic and electron microscopic analysis at a range of time points indicated that migratory fibroblasts were present in the system. Comparison of the contraction profiles of cells extracted from other tissues (tendon and articular cartilage), and extracted by different means from the same tissue specimen, indicated that different populations of fibroblasts can be distinguished on the basis of their pattern of contractions. It would seem that most of the force generated in this model is a result of fibroblast attachment and movement within the collagen lattice. Furthermore, different groups of fibroblasts, even within the same tissue, may vary in their contraction (hence locomotory) activity.
The possibility of altering the pathophysiology of keloid scars was investigated in 11 patients, using a single application of 5-fluorouracil solution for 5 minutes after extralesional excision was performed. Similar excisional wounds treated with phosphate-buffered saline for 5 minutes served as synchronous controls. An objective scoring system and subjective assessment were made to assay the change in the quality of the wound-healing and scar tissue produced by this treatment. A keloid scar score was used at regular time intervals after treatment to assess the quality of scar produced, thereby enabling the treated and control scars to be clinically compared. Biopsies were taken of the control and treated scars 1 month after treatment; the biopsy specimens were then subjected to immunohistochemical analysis as well as a functional assessment of cultured keloid fibroblasts. The immunohistochemical antigens assayed were Ki-67 (also called MIB-1; a marker of cell proliferation); vascular cell adhesion molecule-1 (a marker of inflammation); transforming growth factor beta-1 (a factor involved in scarring) and CD-68 (a macrophage-specific marker). Fibroblast-populated collagen lattices provided a functional assessment of fibroblast contraction. All treated and control wounds healed without any dehiscence or infection. The keloid scar score revealed that there was a perceived improvement in condition for those treated with 5-fluorouracil, compared with the control specimens, during the 6-month follow-up period in the five patients who attended all their clinic appointments; data on later recurrence are not complete as yet. The wounds treated with 5-fluorouracil produced scars that had a significant (p < 0.01) reduction in all the markers assayed, apart from CD-68. Functionally, the keloid fibroblasts from three of five of the treated patients showed reduced contractile capacity. This pilot study demonstrates that a "single-touch" technique with 5-fluorouracil can produce a change in the characteristics of the healing keloid wound after extralesional excision. Long-term studies are required to elucidate the correct dosage and time of exposure to improve the efficacy of this potential treatment.
Using an animal model, the effect of a single intraoperative application of 5-fluorouracil on digital flexor tendon adhesions was assessed. After a standard partial division of the tendon and immobilization with a stitch, the synovial sheath in 30 rabbit tendons was treated with 5-fluorouracil solution (50 mg/ml)-soaked sponge pledgets for 5 minutes. Buffered saline was substituted for 5-fluorouracil in 30 control tendons. The tendons were harvested 1 week postoperatively, and histologic sections were assessed with a light microscope. There was a significant reduction in synovial sheath thickening (p < 0.001), cell counts (p < 0.001) and proportional length of adhesions (p < 0.001) in the treated tendons. The reduction in synovial reaction and adhesion formation using this "one touch" technique presents a novel strategy for the management of the clinical problem of postoperative adhesions complicating tendon injury and repair.
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