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

Background: Nanotechnology and nanomedicine are rising novel fields in plastic and reconstructive surgery (PRS).The use of nanomaterials often goes with regenerative medicine. Due to their nanoscale, these materials stimulate repair at the cellular and molecular levels. Nanomaterials may be placed as components of nanocomposite polymers allowing enhancement of overall biochemical and biomechanical properties with improved scaffold properties, cellular attachment, and tissue regeneration. They may also be formulated as nanoparticle-based delivery systems for controlled release of signal factors or antimicrobials, for example. However, more studies on nanoparticle-based delivery systems still need to be done in this field. Nanomaterials are also used as frameworks for nerves, tendons, and other soft tissues.Main body In this mini-review, we focus on nanoparticle-based delivery systems and nanoparticles targeting cells for response and regeneration in PRS. Specifically, we investigate their roles in various tissue regeneration, skin and wound healing, and infection control. Cell surface-targeted, controlled-release, and inorganic nanoparticle formulations with inherent biological properties have enabled enhanced wound healing, tumor visualization/imaging, tissue viability, and decreased infection, and graft/transplantation rejection through immunosuppression. Conclusions Nanomedicine is also now being applied with electronics, theranostics, and advanced bioengineering technologies. Overall, it is a promising field that can improve patient clinical outcomes in PRS.