Temporal variation in the deposition of different types of collagen within a porous biomaterial implant.

The deposition of new collagen in association with a medical implant has been studied using expanded polytetrafluoroethylene vascular replacement samples implanted subcutaneously in sheep, for up to 28 days. New type I collagen mRNA synthesis was followed by in situ hybridization, while the accumulation of new collagen types III, V, VI, XII, and XIV was followed by immunohistochemistry. All the collagen detected in the pores of the implant were newly deposited at various times after implantation and were not due to any pre-existing dermal collagen that may have been present around the implant. Collagen deposition was seen initially surrounding the implant and, with time, was seen to infiltrate within its pores. In situ hybridization showed that the majority of infiltrating cells had switched on mRNA that coded for type I collagen production. Histology showed that cellular infiltration increased with time, accompanied by increasing collagen deposition. The deposition of different collagen types happened at different rates. The type V and VI collagens preceded the major interstitial collagens in the newly deposited tissue, although at longer time points, detection of type V collagen appeared to decrease. After disruption of the interstitial collagens with enzyme, the "masked" type V collagen was clearly still visible by immunohistochemistry. Little type XII collagen could be seen within the porous mesh, although it was seen in the surrounding tissues. By contrast, type XIV was seen throughout the porous structure of the implanted mesh, with less being visible outside the material where type XII was more abundant.

In situ hybridization using cRNA probes: isotopic and nonisotopic detection methods.

In this chapter we describe the use of cRNA (riboprobes) in the detection of gene expression in tissue sections. Riboprobes offer good sensitivity and allow the detection of low-level mRNA expression. In some cases, the use of radiolabeling is justified because this method is still sensitive. However, recent advances in nonisotopic detection methods mean that in some cases digoxigenin (DIG) or biotin labeling also may be sufficiently sensitive to detect mRNA expression in tissues of interest. The use of alkaline phosphatase conjugated anti-DIG antibodies improves the sensitivity of DIG detection over peroxidase systems, and the use of amplification systems based on biotinyl tyramide has improved the sensitivity of biotin labelled probe detection. Finally, it can be shown that low-level mRNA expression is easier to detect in frozen sections than in paraffin-embedded material, with a consequent loss in quality of morphology.

Histochemical localization of apoptosis with in situ labeling of fragmented DNA.

Cell death by apoptosis is now recognized widely as an important constituent of cell turnover and disease pathology. Characterized by the cleavage of DNA into oligonucleosome-sized DNA fragments, end-labeling of fragmented DNA often is used as an in situ histological marker of apoptosis. The judicious and appropriate use of this technique therefore provides us with an important tool for assessing cell kinetics. Protocols for both terminal transferase-mediated UTP nick end-labeling, so-called TUNEL, and the combination of TUNEL with immunohistochemical staining are presented here, along with a discussion of its significance and interpretation.

Skeletal myocytes are a source of interleukin-6 mRNA expression and protein release during contraction: evidence of fiber type specificity.

In this study, we aimed to determine whether skeletal muscle cells per se are a source of interleukin (IL)-6 during contraction and whether IL-6 production is fiber type specific. Muscle biopsy samples were collected from seven males before (PRE) and after (POST) completing 120 min of continuous bicycle ergometry. Biopsies were sectioned and analyzed for the following: IL-6 protein detected by immunohistochemistry (IHC), IL-6 mRNA content detected by in situ hybridization, fiber type measured by either IHC or myofibrillar ATPase activity stain, and glycogen content measured by periodic acid schiff (PAS) assay. Fibers were qualitatively categorized according to glycogen content to one of five groups (1-5), with 1 being very low (LOW) and 5 being very high (HIGH) glycogen. Total fluorescence (PRE vs. POST) and glycogen-dependent fluorescence (LOW vs. HIGH) of IL-6 protein were quantitated using Metamorph software. Total IL-6 protein was elevated from PRE to POST exercise (P<0.05). At PRE, IL-6 protein was evenly distributed across all fibers at low levels, consistent with glycogen distribution. At POST, IL-6 protein was greater (P<0.05) in HIGH compared with LOW glycogen fibers, which coincided with type 2 fibers. IL-6 mRNA was distributed peripherally in all fibers at PRE. At POST, however, IL-6 mRNA appeared predominantly in type 2 fibers, which also had higher glycogen content (P<0.05). These data demonstrate that myocytes per se are a source of IL-6 produced during contraction. Our data also suggest that type 2 fibers predominantly produce IL-6 during muscle contractile activity.

Collagen fibril formation in a wound healing model.

Control of tissue composition and organization will be a key feature in the development of successful products through tissue engineering. However, the mechanism of collagen fibril formation, growth, and organization is not yet fully understood. In this study we have examined collagen fibril formation in a wound healing model in which the newly formed fibrils were kept distinct from preexisting tissue through use of a porous tubular biomaterial implant. Samples were examined after 4, 6, 14, and 28 days by light microscopy, in situ hybridization, and immunofluorescence microscopy. These showed a normal wound healing response, with significant collagen formation at 14 and 28 days. Individual collagen fibrils were isolated from these samples by gentle extraction in a gentamicin-containing buffer which allowed extraction of a large proportion of intact fibrils. Examination by transmission electron microscopy showed that approximately 80% of the intact fibrils showed a single polarity reversal, with both ends of each fibril comprising collagen amino-terminal domains; the remaining fibrils had no polarity reversal. All fibrils had similar diameters at both time points. Immunoelectron microscopy showed that all labeled fibrils contained both type I and III collagens. These data indicate that this wound healing model provides a system in which collagen fibril formation can be readily followed.

Skin flap-induced regression of granulation tissue correlates with reduced growth factor and increased metalloproteinase expression.

Previous studies have shown that covering granulation tissue of a full-thickness skin wound by a vascularized skin flap induces tissue remodeling, with a rapid loss of granulation tissue cells by apoptosis. In the present study, in situ hybridization has been used to examine mRNA expression for several factors that may be implicated in the apoptosis seen in this tissue. Skin wounds were made on the dorsal skin of 8-week-old rats. Ten days after wounding, skin flaps were created surgically and sutured over the granulation tissue. Tissue sections of granulation tissue from various times after addition of the skin flap were hybridized with 33P-labelled cRNA probes for transforming growth factor-beta1 (TGF-beta1), beta-inducible gene H3 (beta-ig-h3), alpha1 (1) procollagen, alpha-smooth muscle actin, matrix metalloproteinase-13 (MMP-13) and -2 (MMP-2), tissue inhibitor of metalloproteinase-1 (TIMP-1), and inducible nitric oxide synthase (iNOS). Control granulation tissue prior to addition of the skin flap showed high levels of TGF-beta1, beta-ig-h3, alpha1 (1) procollagen, alpha-smooth muscle actin, and TIMP-1 expression. MMP-13, MMP-2, and iNOS mRNA were low in 10-day granulation tissue. Addition of a skin flap resulted in a decrease in the expression of TGF-beta1, beta-ig-h3, alpha1 (I) procollagen, alpha-smooth muscle actin, and TIMP-1, but increased expression of MMP-13 and MMP-2. Similarly, an increase in iNOS mRNA expression was observed in the granulation tissue after addition of the skin flap. Addition of a vascularized skin flap may result in rapid remodelling of granulation tissue due to a decrease in expression of the trophic growth factor TGF-beta1 and increased degradation of extracellular matrix due to an alteration in the balance between MMPs and their inhibitor, TIMP-1. Additionally, increased iNOS expression may also favour apoptosis through the generation of free radicals. The additive effect of reduced growth factor expression, increased extracellular matrix turnover, and nitric oxide generation may result in the fibroblast and vascular cell apoptosis seen during the rapid remodelling of this tissue.