Objective: This study aimed to determine the effect of seven edible mushrooms in the regeneration rate of planarian Dugesia hymanae (D. hymanae). Methods: The ability of D. hymanae to regenerate was used to test extracts of seven mushrooms to reduce regeneration time, using eyespot and tail formations as endpoints. The planarians were amputated and were allowed to heal and regenerate in planarian water (control) and varying concentrations of Crude Ethanolic Extracts (CEE) of the seven edible mushrooms. The CEE with the most significant effect in reducing the regeneration time will be further sub-fractionated into hexane, ethyl acetate, and ethanol solvent extracts. Results: In untreated planarian water, amputated planarians' eyespot and tail formations took 4.65 (SD 0.34) and 4.1 (SD 0.21) days, respectively. The CEE of four mushrooms (Shiitake var Benguet, Tea tree, Shiitake var flower, and Black & White) significantly reduced the regeneration time, with Shiitake var Benguet extract reducing the regeneration time the most at 2.56 (SD 0.30) days and 2.61 (SD 0.22) days for both eyespot and tail formations (P<.0001) respectively. The solvent extracts of the Shiitake (Benguet variety) did not reduce the planarian regeneration time relative to the control (P>.05). Conclusion Lentinula edodes (L. edodes) [Benguet variety CEE] had reduced the regeneration time most significantly for both the eyespot and tail formations compared to the other six tested fungi extracts. The L. edodes (Benguet variety) CEE may contain compounds that can hasten the regeneration of the planarian D. hymanae.
Wound Healing ; Regeneration ; Agaricales ; Planarians

The emergence of regenerative medicine has raised the hope of treating an extraordinary range of disease and serious injuries. Understanding the processes of cell proliferation, differentiation and pattern formation in regenerative organisms could help find ways to enhance the poor regenerative abilities shown by many other animals, including humans. Recently, planarians have emerged as an attractive model in which to study regeneration. These animals are considering as in vivo plate, during which we can study the behavior and characristics of stem cells in their own niche. A variety of characteristic such as: simplicity, easy to manipulate experimentally, the existence of more than 100 years of literature, makes these animals an extraordinary model for regenerative medicine researches. Among planarians free-living freshwater hermaphrodite Schmidtea mediterranea has emerged as a suitable model system because it displays robust regenerative properties and, unlike most other planarians, it is a stable diploid with a genome size of about 4.8x108 base pairs, nearly half that of other common planarians. Planarian regeneration involves two highly flexible systems: pluripotent neoblasts that can generate any new cell type and muscle cells that provide positional instructions for the regeneration of anybody region. neoblasts represent roughly 25~30 percent of all planarian cells and are scattered broadly through the parenchyma, being absent only from the animal head tips and the pharynx. Two models for neo-blast specification have been proposed; the naive model posits that all neoblasts are stem cells with the same potential and are a largely homogeneous population.
Animals ; Base Pairing ; Cell Proliferation ; Diploidy ; Fresh Water ; Genome Size ; Head ; Hope ; Humans ; Muscle Cells ; Pharynx ; Planarians* ; Regeneration ; Regenerative Medicine* ; Stem Cells

Planarian is among the simplest animals that possess a centralized nervous system (CNS), and its neural regeneration involves the replacement of cells lost to normal 'wear and tear' (cell turnover), and/or injury. In this review, we state and discuss the recent studies on molecular control of neural regeneration in planarians. The spatial and temporal expression patterns of genes in intact and regenerating planarian CNS have already been described relatively clearly. The bone morphogenetic protein (BMP) and Wnt signaling pathways are identified to regulate neural regeneration. During neural regeneration, conserved axon guidance mechanisms are necessary for proper wiring of the nervous system. In addition, apoptosis may play an important role in controlling cell numbers, eliminating unnecessary tissues or cells and remodeling the old tissues for regenerating CNS. The bilateral symmetry is established by determination of anterior-posterior (A-P) and dorsal-ventral (D-V) patterns. Moreover, neurons positive to dopamine, serotonin (5-HT), and gamma-aminobutyric acid (GABA) have been detected in planarians. Therefore, planarians present us with new, experimentally accessible contexts to study the molecular actions guiding neural regeneration.
Animals ; Apoptosis ; Bone Morphogenetic Proteins ; metabolism ; Central Nervous System ; cytology ; Fibroblast Growth Factors ; Gene Expression ; physiology ; Nerve Regeneration ; genetics ; Neurotransmitter Agents ; metabolism ; Planarians ; genetics ; physiology ; Signal Transduction ; physiology ; Wnt Proteins ; physiology