Your competent? doctor created dendritic branching and axon pathfinding protocols years ago, right? Oh, your incompetent doctor hasn't even started creating protocols! WOW!
axon pathfinding (42 posts to March 2012)
dendritic branching (42 posts to February 2012)
Send me hate mail on this: oc1dean@gmail.com. I'll print your complete statement with your name and my response in my blog. Or are you afraid to engage with my stroke-addled mind? No excuses are allowed! You're medically trained; it should be simple to precisely state EXACTLY WHY you haven't created those protocols in the last decade with NO EXCUSES! Your definition of competence in stroke is obviously much lower than stroke survivors' definition of your competence! Swearing at me is allowed, I'll return the favor. Don't even attempt to use the excuse that brain research is hard.
Neuronal branching in stem cell models of mitochondrial and neurological diseases
Abstract
Neuronal branching, the extension and arborization of neurites, is critical for establishing and maintaining functional neural circuits. Emerging evidence suggests that mitochondria play an important role in regulating this process. In this review, we explore how the use of human induced pluripotent stem cell (iPSC)-derived neuronal models in two dimensions (2D) and three dimensions (3D) could help uncover possible mechanisms linking mitochondrial function and dysfunction to neuronal branching capacity. We highlight examples of iPSC-based models of mitochondrial and neurological diseases where aberrant neurite growth has been observed and discuss the potential therapeutic implications. Additionally, we review current methodologies for assessing neurite outgrowth in 2D and 3D neuronal models, addressing their strengths and limitations. Insights gained from these models emphasize the significance of mitochondrial health in neuronal branching and demonstrate the potential of iPSC-derived neurons and brain organoids for studying disrupted neuronal morphology. Harnessing these human stem cell models to devise phenotypic drug discovery platforms can eventually pave the way for innovative therapeutic interventions, particularly in the context of disorders with poorly understood genetic mechanisms and limited therapeutic options.
No comments:
Post a Comment