Might the Masson trichrome stain be considered a useful method for categorizing experimental tendon lesions?

Strain injuries of tendons are the most common orthopedic injuries in athletic subjects, be they equine or human. When the tendon is suddenly damaged, an acute inflammatory phase occurs whereas its repetitive overloading may cause chronic injuries. Currently the criteria used for grading injuries are general and subjective, and therefore a reliable grading method would be an improvement. The main purpose of this study was to assess qualitatively the histological pattern of Masson trichrome stain in healthy and injured tendons; indeed, the known "paradox" of Masson staining was used to create an evaluation for the matrix of tendons, following experimental lesions and natural repair processes. A statistically significant difference of aniline-staining between healthy and lesioned tendons was observed. Overall, we think that the Masson staining might be regarded as an informative tool in discerning the collagen spatial arrangement and therefore the histological characteristics of tendons.

Successful recellularization of human tendon scaffolds using adipose-derived mesenchymal stem cells and collagen gel.

The major goal of regenerative medicine is to determine experimental techniques that take maximal advantage of reparative processes that occur naturally in the animal body. Injection of mesenchymal stem cells into the core of a damaged tendon represents such an approach. Decellularization of native tendons as potential targets and seeding protocols are currently under investigation. The aim of our study was to manufacture a recellularized biocompatible scaffold from cadaveric tissue for use in total or partial tendon injuries. Results showed that it was possible to introduce proliferating cells into the core of a decellularized tendon to treat the scaffold with a collagen gel. The method was effective in maintaining scaffold extracellular matrix and for expressing collagen type I and cartilage oligomeric matrix protein by injecting mesenchymal stem cells.

Effects of in vivo applications of peripheral blood-derived mesenchymal stromal cells (PB-MSCs) and platlet-rich plasma (PRP) on experimentally injured deep digital flexor tendons of sheep.

Tendon injuries, degenerative tendinopathies, and overuse tendinitis are common in races horses. Novel therapies aim to restore tendon functionality by means of cell-based therapy, growth factor delivery, and tissue engineering approaches. This study examined the use of autologous mesenchymal stromal cells derived from peripheral blood (PB-MSCs), platelet-rich plasma (PRP) and a combination of both for ameliorating experimental lesions on deep digital flexor tendons (DDFT) of Bergamasca sheep. In particular, testing the combination of blood-derived MSCs and PRP in an experimental animal model represents one of the few studies exploring a putative synergistic action of these treatments. Effectiveness of treatments was evaluated at 30 and 120 days comparing clinical, ultrasonographic, and histological features together with immunohistochemical expression of collagen types 1 and 3, and cartilage oligomeric matrix protein (COMP). Significant differences were found between treated groups and their corresponding controls (placebo) regarding tendon morphology and extracellular matrix (ECM) composition. However, our results indicate that the combined use of PRP and MSCs did not produce an additive or synergistic regenerative response and highlighted the predominant effect of MSCs on tendon healing, enhanced tissue remodeling and improved structural organization.

Sublethal effects of trimethoprim on four freshwater organisms.

Sublethal effects of trimethoprim (TMP) were evaluated in four freshwater organisms: Pseudokirchneriella subcapitata and Lemna minor (growth inhibition), Daphnia magna (reproduction and growth inhibition) and Poecilia reticulata (swimming activity inhibition). Cytochrome P4501A induction was also evaluated in P. reticulata. TMP showed varying levels of toxicity in the four test performed, with NOEC for the various endpoints in the range of 3.12-25 mg L(-1). The compound was active on P. reticulata at concentration ≥ 50 mg L(-1) causing inhibition of swimming activity. In the same organism an induction of CYP1A protein, mainly in kidney, gills and intestine, was also detected. L. minor was more sensitive than unicellular algae to TMP, with a NOEC of 12.5 mg L(-1). The lowest NOEC (3.12 mg L(-1)) was obtained in D. magna reproduction test and then a Risk Quotient of <0.03 was calculated by comparing the PNEC (31.2 µg L) and the TMP concentrations usually detected in freshwater (<1 µg L(-1)). However, based on recently reported data, it was concluded that while TMP concentrations normally detected in surface water are below those able to evoke appreciable biological effects in the various aquatic organisms, TMP concentrations in aquaculture and hospital effluents can be one to three orders of magnitude higher. Furthermore, the co-occurrence and additive effects of other antifolic agents should be taken into account for a cautious risk assessment of the drug.

Expression and tissue-specific localization of nitrate-responsive miRNAs in roots of maize seedlings.

Nitrogen availability seriously affects crop productivity and environment. The knowledge of post-transcriptional regulation of plant response to nutrients is important to improve nitrogen use efficiency of crop. This research was aimed at understanding the role of miRNAs in the molecular control of plant response to nitrate. The expression profiles of six mature miRNAs were deeply studied by quantitative real time polymerase chain reaction and in situ hybridization (ISH). To this aim, a novel optimized protocol was set up for the use of digoxygenin-labelled Zip Nucleic Acid-modified oligonucleotides as probes for ISH. Significant differences in miRNAs' transcripts accumulation were evidenced between nitrate-supplied and nitrate-depleted roots. Real-time PCR analyses and in situ detection of miRNA confirmed the array data and allowed us to evidence distinct miRNAs spatio-temporal expression patterns in maize roots. Our results suggest that a prolonged nitrate depletion may induce post-transcriptionally the expression of target genes by repressing the transcription of specific miRNAs. In particular, the repression of the transcription of miR528a/b, miR528a*/b*, miR169i/j/k, miR169i*/j*/k*, miR166j/k/n and miR408/b upon nitrate shortage could represent a crucial step integrating nitrate signals into developmental changes in maize roots.

Localization of gamma-glutamyl transferase activity and protein in Zea mays organs and tissues.

Gamma-glutamyl transferase/transpeptidase (GGT, (5-l-glutamyl)-peptide:amino-acid 5-glutamyltransferase; EC 2.3.2.2.) is an ectoenzyme promoting the cleavage of the gamma-glutamyl moiety of glutathione (GSH) and gamma-glutamyl related compounds. In this work, we describe the localization of GGT by enzymehistochemical and immunohistochemical analysis in maize plants. Our results show that the tissue spatial distribution of GGT activity closely correlates with the localization of the GGT protein. We also demonstrate that GGT activity and protein are unevenly distributed in tissues, being higher in the epidermis and stomata, parenchyma of conductive elements and root meristem. These results can contribute to our understanding of GGT function and regulation as well as its role in glutathione metabolism. To date, these are largely unknown in plants.