Permissive environment in postnatal wounds induced by adenoviral-mediated overexpression of the anti-inflammatory cytokine interleukin-10 prevents scar formation.

Wound healing in the mid-gestation fetus is scarless with minimal inflammation and a unique extracellular matrix. We have previously documented the relative lack of inflammatory cytokines in this environment. We demonstrate that interleukin (IL)-10 is highly expressed in mid-gestation human fetal skin but is absent in postnatal human skin. We hypothesize that overexpression of IL-10 in postnatal skin may replicate a permissive environment for scarless healing. To study the mechanism underlying this process we performed immunohistochemistry for IL-10 in human mid-gestation fetal and postnatal skin. We also determined if adenoviral-mediated overexpression of IL-10 could allow for scarless wound healing in a murine incisional wound model. Wounds were analyzed at 1-90 days postwounding for effects on scar formation, inflammatory response, and biomechanical properties. Ad-IL-10 reconstitutes a permissive environment for scarless healing as shown by reconstitution of a normal dermal reticular collagen pattern and distribution of dermal elements. Compared with controls, Ad-IL-10 treated wounds showed reduced inflammatory response and no difference in biomechanical parameters. Therefore, overexpression of IL-10 in postnatal wounds results in a permissive environment for scarless wound repair, possibly by replicating a fetal wound environment.

Regenerative properties of fetal sheep tendon are not adversely affected by transplantation into an adult environment.

Tendon injuries account for a significant number of musculoskeletal afflictions each year. While new surgical techniques and rehabilitation protocols have led to improved clinical outcomes, postsurgical scarring remains the most problematic aspect of tendon repair. In contrast to this typical pattern of fibrosis, recent studies have shown that fetal tendon is capable of healing without scar. However, whether this regenerative healing pattern is intrinsic to the fetal tissue itself or the result of its environment is not known. Thus, the objective of this study is to examine the influence of an adult environment on healing in adult and fetal tendons. We hypothesized that injured fetal tendon tissue transplanted into an adult environment would retain a regenerative healing pattern after injury, demonstrating normal histological and mechanical properties. Our results support this hypothesis. Histological analyses revealed considerable alterations in adult tendon transplants after injury while fetal transplants showed no abnormalities. The injured adult tendons also demonstrated elevated levels of TGF-beta1, bFGF, and CD44 at the wound site, whereas the fetal specimens showed little or no such changes in response to injury. The data from our biomechanical studies further corroborate these observations, with significant decreases in the stiffness, modulus, and almost all viscoelastic properties in wounded versus unwounded adult tendons, and fetal specimens showing no differences in mechanical properties between the wounded and unwounded groups. Thus, the results of our investigation demonstrate that the adult environment is not an impediment to scarless repair and that this capability is intrinsic to the fetal tendon itself. Our study also begins to provide insight into the mechanisms controlling this regenerative response.

Variation of biomechanical, structural, and compositional properties along the tendon to bone insertion site.

The tendon to bone insertion site is a complex transitional region that links two very different materials. The insertion site must transfer a complex loading environment effectively to prevent injury and provide proper joint function. In order to accomplish this load transfer effectively, the properties of the insertion site were hypothesized to vary along its length. The quasilinear viscoelastic (QLV) Model was used to determine biomechanical properties, polarized light analysis was used to quantitate collagen orientation (structure), and in situ hybridization was used to determine the expression of extracellular matrix genes (composition). All assays were performed at two insertion site locations: the tendon end of the insertion and the bony end of the insertion. Biomechanically, the apparent properties of peak strain, the coefficients (A and B) that describe the elastic component of the QLV model, and one of the coefficients (tau(1)) of the viscous component of the model were significantly higher, while another of the coefficients (C) of the viscous component was significantly lower at the tendon insertion compared to the bony insertion. The collagen was significantly more oriented at the tendon insertion compared to the bony insertion. Finally, collagen types II, IX, and X, and aggrecan were localized only to the bony insertion, while decorin and biglycan were localized only to the tendon insertion. Thus, the tendon to bony insertion site varies dramatically along its length in terms of its viscoelastic properties, collagen structure, and extracellular matrix composition.

Regenerative versus reparative healing in tendon: a study of biomechanical and histological properties in fetal sheep.

Previous studies have shown fetal tissues heal in a regenerative fashion without scar formation. The objective of this study is to compare the healing properties of adult and fetal tendons. Time-mated pregnant ewes at 80-85 days of gestation were utilized. A partial, midsubstance tenotomy was performed in the lateral extensor fetal tendons, and analogous tenotomies were created in the maternal limbs. One week after injury, the fetal and adult animals were sacrificed, and tendons were histologically and mechanically evaluated. Immunohistochemical staining for transforming growth factor beta isoform 1 (TGF-beta1) was performed. Histologically, a gap with granulation tissue and inflammatory cells was visible in the site of wounding in the adult tendons. In the fetal tendons, no abnormalities were noted in the wound, with reconstitution of collagen architecture. TGF-beta1 expression was low in fetal but upregulated in the adult wounds. No significant differences were found in the biomechanical properties between groups. We identified regenerative healing properties in injured fetal tendon, while adult tendon tissue healed reparatively with scar formation. Fetal tendons demonstrated a limited recovery of mechanical properties after injury that was no better than that of the adult tendons at seven days. A better understanding of the mechanisms of fetal healing may lead to novel therapeutic strategies in the clinical setting.