Time Lapse Imaging is a powerful technique in various scientific and medical fields that involves capturing a sequence of images over time, allowing researchers to observe dynamic processes and changes. In cell biology, time-lapse microscopy enables the visualization of live cells in culture, providing insights into cell division, migration, and other cellular behaviors. This technique is instrumental in studying developmental processes, tracking the progression of diseases, and evaluating the effects of therapeutic interventions. In astronomy, time-lapse imaging is utilized to capture celestial events, such as the movement of planets, changes in star brightness, or the paths of comets. In geology, time-lapse photography records the evolution of landscapes, capturing phenomena like erosion, glaciation, or volcanic activity. The technique is also widely employed in filmmaking and photography to create captivating sequences by compressing time, for instance, capturing the blooming of flowers or the transition from day to night. Time-lapse imaging has revolutionized research methodologies, allowing scientists to unveil dynamic processes in various disciplines and contributing to a deeper understanding of natural phenomena and complex systems. Advances in technology continue to enhance the precision and accessibility of time-lapse imaging, expanding its applications across scientific and creative domains.
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