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Complete Regeneration (complete + regeneration)

Distribution by Scientific Domains
Medical Sciences40%

Selected Abstracts

Overexpression of the transcription factor Msx1 is insufficient to drive complete regeneration of refractory stage Xenopus laevis hindlimbs

DEVELOPMENTAL DYNAMICS, Issue 6 2009
Donna M. Barker
Abstract Xenopus laevis tadpoles are capable of hindlimb regeneration, although this ability declines with age. Bmp signaling is one pathway known to be necessary for successful regeneration to occur. Using an inducible transgenic line containing an activated version of the Bmp target Msx1, we assessed the ability of this transcription factor to enhance regeneration in older limbs. Despite considerable evidence correlating msx1 expression with regenerative success in vertebrate regeneration models, we show that induction of msx1 during hindlimb regeneration fails to induce complete regeneration. However, we did observe some improvement in regenerative outcome, linked to morphological changes in the early wound epithelium and a corresponding increase in proliferation in the underlying distal mesenchyme, neither of which are maintained later. Additionally, we show that Msx1 is not able to rescue limb regeneration in a Bmp signalling-deficient background, indicating that additional Bmp targets are required for regeneration in anuran limbs. Developmental Dynamics 238:1366,1378, 2009. © 2009 Wiley-Liss, Inc. [source]

Retinoic acid, a regeneration-inducing molecule

DEVELOPMENTAL DYNAMICS, Issue 2 2003
Malcolm Maden
Abstract Retinoic acid (RA) is the biologically active metabolite of vitamin A. It is a low molecular weight, lipophilic molecule that acts on the nucleus to induce gene transcription. In amphibians and mammals, it induces the regeneration of several tissues and organs and these examples are reviewed here. RA induces the "super-regeneration" of organs that can already regenerate such as the urodele amphibian limb by respecifying positional information in the limb. In organs that cannot normally regenerate such as the adult mammalian lung, RA induces the complete regeneration of alveoli that have been destroyed by various noxious treatments. In the mammalian central nervous system (CNS), which is another tissue that cannot regenerate, RA does not induce neurite outgrowth as it does in the embryonic CNS, because one of the retinoic acid receptors, RAR,2, is not up-regulated. When RAR,2 is transfected into the adult spinal cord in vitro, then neurite outgrowth is stimulated. In all these cases, RA is required for the development of the organ, in the first place suggesting that the same gene pathways are likely to be used for both development and regeneration. This suggestion, therefore, might serve as a strategy for identifying potential tissue or organ targets that have the capacity to be stimulated to regenerate. Developmental Dynamics 226:237,244, 2003.© 2003 Wiley-Liss, Inc. [source]

A Novel Possible Strategy Based on Self-Assembly Approach to Achieve Complete Periodontal Regeneration

ARTIFICIAL ORGANS, Issue 7 2010
Zhen-Hua Yang
Abstract Limitations of current regeneration modalities underscore the importance of restoring the three-dimensional (3D) microenvironment of periodontal development, which is able to elicit the intrinsic capacity of mesenchymal stem cells to proceed to engage in a redevelopment-like program. With increased attention for the potential therapeutic applications of periodontal ligament stem cells (PDLSCs) in periodontal regeneration, it has been proposed that bone marrow mesenchymal stem cells (BMMSCs) are very likely another cell source of physiological repair of periodontal tissues. With this in mind, enlightened from the research targeting the fabrication of laminar structures such as liver and kidney with heterotypic stratification of cell sheets, we proposed a novel possible strategy based on self-assembly approach, which is akin to the physiological phenomenon that occurs during organogenesis, to enhance complete reconstruction of functional complex periodontium-organ systems. We assumed that in this strategy, using the intrinsic capacity of monodispersed cells to self-assemble into a microtissue such as a 3D spheroid, bilayered cell pellet constructs comprising calcified bone-forming cell pellets (i.e., BMMSCs) and cementum/PDL-forming cell pellets (i.e., PDLSCs) would be fabricated in vitro in a tissue-mimicking way and then implanted into periodontal defects. We hypothesize that this novel strategy might open new options to reconstruct extended periodontal defects and then achieve the ultimate goal of predictable and complete regeneration of the periodontium. [source]

Mitochondrial metabolism in the rat during bladder regeneration induced by small intestinal submucosa

BJU INTERNATIONAL, Issue 3 2004
Rozbeh Faramarzi-Roques
OBJECTIVE To assess mitochondrial metabolism of bladder tissue induced by small-intestinal submucosa (SIS), by comparing the mitochondrial enzyme metabolism in this tissue with that in normal bladder tissue and thus evaluate intracellular normality. MATERIAL AND METHODS In all, 70 rats were grouped into healthy controls (10), surgical controls with a simple bladder incision (15) and rats treated by partial cystectomy with replacement by the SIS graft (45). At 1, 3 and 6 months the rats were killed, the enzymes of mitochondrial respiratory chain complexes assayed, and the respiration of permeabilized bladder fibres assessed using polarographic analysis. RESULTS The enzyme activities of control and treated rats at 3 months were identical. The results from the polarographic analysis of respiration were also similar to that in normal tissue apart from a decrease in the number of mitochondria. Histologically, there was complete regeneration at 6 months. CONCLUSION After a phase of inflammation the bladder regenerates after a patch is placed. The new tissue has the same enzymatic and histological features as normal bladder tissue. [source]