Three‐dimensional imaging and quantification of real‐time cytosolic calcium oscillations in microglial cells cultured on electrospun matrices using laser scanning confocal microscopy

The development of a minimally invasive, robust, and inexpensive technique that permits real-time monitoring of cell responses on biomaterial scaffolds can improve the eventual outcomes of scaffold-based tissue engineering strategies. Towards establishing correlations between in situ biological activity and cell fate, we have developed a comprehensive workflow for real-time volumetric imaging of spatiotemporally varying cytosolic calcium oscillations in pure microglial cells cultured on electrospun meshes. Live HMC3 cells on randomly oriented electrospun fibers were stained with a fluorescent dye and imaged using a laser scanning confocal microscope. Resonance scanning provided high-resolution in obtaining the time-course of intracellular calcium levels without compromising spatial and temporal resolution. Three-dimensional reconstruction and depth-coding enabled the visualization of cell location and intracellular calcium levels as a function of sample thickness. Importantly, changes in cell morphology and in situ calcium spiking were quantified in response to a soluble biochemical cue and varying matrix architectures (i.e., randomly oriented and aligned fibers). Importantly, raster plots generated from spiking data revealed calcium signatures specific to culture conditions. In the future, our approach can be used to elucidate correlations between calcium signatures and cell phenotype/activation, and facilitate the rational design of scaffolds for biomedical applications

Three‐dimensional imaging and quantification of real‐time cytosolic calcium oscillations in microglial cells cultured on electrospun matrices using laser scanning confocal microscopy

The development of a minimally invasive, robust, and inexpensive technique that permits real-time monitoring of cell responses on biomaterial scaffolds can improve the eventual outcomes of scaffold-based tissue engineering strategies. Towards establishing correlations between in situ biological activity and cell fate, we have developed a comprehensive workflow for real-time volumetric imaging of spatiotemporally varying cytosolic calcium oscillations in pure microglial cells cultured on electrospun meshes. Live HMC3 cells on randomly oriented electrospun fibers were stained with a fluorescent dye and imaged using a laser scanning confocal microscope. Resonance scanning provided high-resolution in obtaining the time-course of intracellular calcium levels without compromising spatial and temporal resolution. Three-dimensional reconstruction and depth-coding enabled the visualization of cell location and intracellular calcium levels as a function of sample thickness. Importantly, changes in cell morphology and in situ calcium spiking were quantified in response to a soluble biochemical cue and varying matrix architectures (i.e., randomly oriented and aligned fibers). Importantly, raster plots generated from spiking data revealed calcium signatures specific to culture conditions. In the future, our approach can be used to elucidate correlations between calcium signatures and cell phenotype/activation, and facilitate the rational design of scaffolds for biomedical applications

WNT-β Catenin Signaling as a Potential Therapeutic Target for Neurodegenerative Diseases: Current Status and Future Perspective

Wnt/β-catenin (WβC) signaling pathway is an important signaling pathway for the maintenance of cellular homeostasis from the embryonic developmental stages to adulthood. The canonical pathway of WβC signaling is essential for neurogenesis, cell proliferation, and neurogenesis, whereas the noncanonical pathway (WNT/Ca2+ and WNT/PCP) is responsible for cell polarity, calcium maintenance, and cell migration. Abnormal regulation of WβC signaling is involved in the pathogenesis of several neurodegenerative diseases such as Alzheimer’s disease (AD), Parkinson’s disease (PD), Huntington’s disease (HD), amyotrophic lateral sclerosis (ALS), multiple sclerosis (MS), and spinal muscular atrophy (SMA). Hence, the alteration of WβC signaling is considered a potential therapeutic target for the treatment of neurodegenerative disease. In the present review, we have used the bibliographical information from PubMed, Google Scholar, and Scopus to address the current prospects of WβC signaling role in the abovementioned neurodegenerative diseases