Time Lapse Microscopy is a sophisticated imaging technique that involves capturing a series of images over time, providing dynamic insights into biological processes at the cellular or molecular level. This method is extensively utilized in cell biology and microbiology to observe and analyze the temporal aspects of living cells or organisms. Using specialized microscopy equipment and digital imaging systems, researchers can record changes in cell morphology, movement, division, and other dynamic cellular events. Time-lapse microscopy has significantly advanced our understanding of cellular processes, including mitosis, cell migration, and intracellular signaling. It has proven instrumental in drug discovery, studying the effects of pharmaceutical compounds on cell behavior over time. In neurobiology, time-lapse microscopy allows researchers to track neuronal growth and synaptic activity. The technique has also found applications in fields like developmental biology, immunology, and cancer research. Time-lapse microscopy offers a non-invasive and real-time approach, enabling scientists to unravel the intricacies of cellular dynamics. Continuous technological advancements, such as improved imaging modalities and automated analysis tools, enhance the precision and efficiency of time-lapse microscopy, making it an indispensable tool for unraveling the dynamic world within cells and tissues.
Title : AI-integrated high-throughput tissue-chip for space-based biomanufacturing applications
Kunal Mitra, Florida Tech, United States
Title : Will be updated soon...
Vasiliki E Kalodimou, European University-Cyprus Ltd, Cyprus
Title : Will be updated soon...
Nagy Habib, Imperial College London, United Kingdom
Title : Will be updated soon...
Alexander Seifalian, Nanotechnology & Regenerative Medicine Commercialisation Centre, United Kingdom
Title : Advanced 3D tissue models: Pioneering tools for investigating health and disease
Lucie Bacakova, Institute of Physiology of the Czech Academy of Sciences, Czech Republic
Title : Developing iPSC-derived 3D Outer Blood-Retinal Barrier Disease Models of Choroideremia for Gene Therapy Evaluation
Aradhana Kasimsetty, National Center for Advancing Translational Sciences (NCATS), National Institutes of Health (NIH), United States