Photopolymerizable Hydrogel-Encapsulated Fibromodulin-Reprogrammed Cells for Muscle Regeneration.

A central challenge in tissue engineering is obtaining a suitable cell type with a capable delivery vehicle to replace or repair damaged or diseased tissues with tissue mimics. Notably, for skeletal muscle tissue engineering, given the inadequate availability and regenerative capability of endogenous myogenic progenitor cells as well as the tumorigenic risks presented by the currently available pluri- and multipotent stem cells, seeking a safe regenerative cell source is urgently demanded. To conquer this problem, we previously established a novel reprogramming technology that can generate multipotent cells from dermal fibroblasts using a single protein, fibromodulin (FMOD). The yield FMOD-reprogrammed (FReP) cells exhibit exceeding myogenic capability without tumorigenic risk, making them a promising and safe cell source for skeletal muscle establishment. In addition to using the optimal cell for implantation, it is equally essential to maintain cellular localization and retention in the recipient tissue environment for critical-sized muscle tissue establishment. In this study, we demonstrate that the photopolymerizable methacrylated glycol chitosan (MeGC)/type I collagen (ColI)-hydrogel provides a desirable microenvironment for encapsulated FReP cell survival, spreading, extension, and formation of myotubes in the hydrogel three-dimensionally in vitro, without undesired osteogenic, chondrogenic, or tenogenic differentiation. Furthermore, gene profiling revealed a paired box 7 (PAX7) → myogenic factor 5 (MYF5) → myogenic determination 1 (MYOD1) → myogenin (MYOG) → myosin cassette elevation in the encapsulated FReP cells during myogenic differentiation, which is similar to that of the predominant driver of endogenous skeletal muscle regeneration, satellite cells. These findings constitute the evidence that the FReP cell-MeGC/ColI-hydrogel construct is a promising tissue engineering mimic for skeletal muscle generation in vitro, and thus possesses the extraordinary potential for further in vivo validation.

Herbal Medicine in the Mitigation of Reactive Oxygen Species, Autophagy, and Cancer: A Review.

Since the discovery of autophagy in the mid-2000s, the interest in autophagy-related processes within the scientific community has been burgeoning. Countless authors have investigated its function in cellular homeostasis, but arguably of higher importance is its role during pathology. Although primarily a catabolic process, in cancer cells autophagy has numerous downstream effects, being observed to be both pro- and anti-apoptotic. One of the primary factors mediating this differential role of autophagy is the accumulation or sequestration of reactive oxygen species (ROS). Until recently, despite its increasing popularity in the Western world, the efficacy of herbal supplements has been largely anecdotal. Herein, we reviewed the ten most commonly studied herbs in cancer research and their impact on ROS regulation, on the activation and inhibition of autophagy, and ultimately on cancer cell death.