In vitro and in vivo detection of microbial gene expression in bioactivated scaffolds seeded with cyanobacteria.

Dermal replacement materials bioactivated with cyanobacteria have shown promising potential for wound regeneration. To date, extraction of cyanobacteria RNA from seeded scaffolds has not been described. The aim of this study was to develop a method to isolate total RNA from bioactivated scaffolds and to propose a new approach in determining living bacteria based on real-time PCR. Transgenic Synechococcus sp. PCC 7002 (tSyn7002) were seeded in liquid cultures or scaffolds for dermal regeneration in vitro and in vivo for 7 days. RNA was extracted with a 260/280 ratio of ≥2. The small subunit of the 30S ribosome in prokaryotes (16S) and RNAse P protein (rnpA) were validated as reference transcripts for PCR analysis. Gene expression patterns differed in vitro and in vivo. Expression of 16S was significantly upregulated in scaffolds in vitro, as compared to liquid cultures, whilst rnpA expression was comparable. In vivo, both 16S and rnpA showed reduced expression compared to in vitro (16S: in vivo Ct value 13.21 ± 0.32, in vitro 12.44 ± 0.42; rnpA in vivo Ct value 19.87 ± 0.41, in vitro 17.75 ± 1.41). Overall, the results demonstrate rnpA and 16S expression after 7 days of implantation in vitro and in vivo, proving the presence of living bacteria embedded in scaffolds using qPCR.

The influence of pancreas-derived stem cells on scaffold based skin regeneration.

It has been shown that Pancreatic Stem Cells (PSCs) share many features with skin stem cells. Yet, their potential role in skin regeneration remains to be elucidated. 5x10(5) PSCs from male Rattus norwegicus were seeded on Matriderm scaffold overnight. Cells survival and proliferation were then tested in vitro showing the survival of the cells and their homogenous distribution in the scaffolds. Afterwards, scaffolds were used to replace bilateral full-thickness skin wounds made on the dorsum of Nu/Nu mice. A control group of nude mice received the Matriderm scaffolds without cells. Two weeks after transplantation, wound areas were harvested and analyzed with respect to epithelialization, vascularization and wound closure. The healing area and regeneration rate were significantly increased in the group used the PSCs-seeded scaffolds (factor of 2.1). Vascularization rate showed a significant increase in the PSCs-seeded scaffolds(factor of 1.5). Morphology and immunohistochemistry showed new skin-like structures positive to epidermal markers in the healing wound bed. PSCs were detected in the regenerated tissues. This study showed that the combined use of PSCs with the Matriderm as a scaffold for dermal regeneration significantly increased the epidermalization, vascularization and healing in full-thickness wounds.

Use of Erythropoietin as adjuvant therapy in nerve reconstruction.

BACKGROUND AND AIMS: Adjuvant therapies may improve the outcome after nerve reconstruction. We analyzed the influence of recombinant human Erythropoietin (rHuEpo), which has proven angiogenic and neuroprotective effects, on the quality of peripheral nerve regeneration. METHODS: Thirty two female Lewis rats underwent nerve reconstruction by means of tubulization (groups I and II) or autologous sciatic nerve grafting (groups III and IV). Groups I and III received daily subcutaneous rHuEpo injections over 2 weeks (1,000 U/kg bw) with normal saline injections as controls (groups II and IV). Data on histology and muscle weight were collected after 7 weeks. Axon count and diameter were assessed by a new method based on digital segmentation. RESULTS: Atrophy of the tibial muscle was less severe in the rHuEpo-treated group compared to controls resulting in significant higher muscle weight quotients (p = 0.006). The same trend was found in the gastrocnemius muscle, but without being statistically significant. No significant differences in axon count or axon diameter were detected in the presence of rHuEpo treatments. CONCLUSION: Our findings give evidence for a positive effect of Erythropoietin on functional recovery after nerve grafting. Muscle recovery benefited from rHuEpo administration despite absence of improved neural morphology. Semi-automated axon detection facilitated accurate morphometrical assessment.

A technique to detect and to quantify fasciocutaneous blood vessels in small laboratory animals ex vivo.

PURPOSE: A microangiographical technique is described, which allows visualization of small and capillary blood vessels and quantification of fasciocutaneous blood vessels by means of digital computer analysis in very small laboratory animals. MATERIALS AND METHODS: The left carotid artery of 20 nu/nu mice was cannulated (26 gauge) and a mixture of gelatin, bariumsulfate, and green ink was injected according to standardized protocol. Fasciocutaneous blood vessels were visualized by digital mammography and analyzed for vessel length and vessel surface area as standardized units [SU] by computer program. RESULTS: With the described microangiography method, fasciocutaneous blood vessels down to capillary size level can be clearly visualized. Regions of interest (ROIs) can be defined and the containing vascular network quantified. Comparable results may be obtained by calculating the microvascular area index (MAI) and the microvascular length index (MLI), related to the ROIs size. Identical ROIs showed a high reproducibility for measured [SU] < 0.01 +/- 0.0012%. CONCLUSION: Combining microsurgical techniques, pharmacological knowledge, and modern digital image technology, we were able to visualize small and capillary blood vessels even in small laboratory animals. By using our own computer analytical program, quantification of vessels was reliable, highly reproducible, and fast.