Light-Sheet Images in Other Applications
Typical applications of light-sheet fluorescence microscopy capitalize on its low phototoxicity and its ability to image large samples with sub-cellular details. One common application is time-lapse imaging of living organisms, for example when studying zebrafish embryonic development. Additionally, light-sheet microscopy is often applied to image large, cleared samples, such as entire optically cleared mice.
Bruker offers several light-sheet microscopes for many models, systems, and specialized applications.
For more specialized samples, Bruker's application specialists are adeptly positioned to assist researchers in navigating the intricacies of their experiments. Whether dealing with unconventional biological models, unique tissues, or challenging imaging conditions, Bruker's specialists are committed to tailoring solutions that align with the specific demands of diverse research endeavors.
Other Applications
Daphnia
Daphnia, commonly known as water fleas, are small aquatic crustaceans that serve as valuable models in biological sciences. Their translucent exoskeleton allows for non-invasive visualization of internal organs and physiological processes. Researchers utilize Daphnia to study environmental toxicology, reproductive biology, and neurobiology.
Volvox
Volvox, a colonial green alga, serves as a distinctive model system in ecology, environmental biology, genomics, and cell biology. The transparent nature of Volvox colonies allows researchers to visualize cellular structures and developmental processes in three dimensions and to study individual and colony behavior.
Xenopus
Xenopus frog embryos are often used in developmental biology studies. Their large size and external development make them amenable to light-sheet imaging, enabling researchers to visualize dynamic processes in 3D. Xenopus studies allow new insights into development, regeneration, and gene regulation.
Arabidopsis thaliana (thale cress)
Arabidopsis thaliana is a small flowering plant commonly used in plant biology research. Light-sheet microscopy can be applied to study the 3D architecture of plant tissues and organs, providing insights into plant development and responses to environmental stimuli. Plants have unique characteristics and challenges that need to be considered for imaging.
Octopus
The octopus presents an intriguing preclinical model with its complex nervous system and remarkable cognitive abilities. Octopuses are known for their adaptive behavior, intelligence, and unique body structure. Light-sheet microscopy allows researchers to explore the three-dimensional intricacies of the octopus brain, shedding light on neural circuits and behavioral patterns.
Cell cultures, organoids, and spheroids
In addition to whole organisms, light-sheet microscopy can be applied to study sub- and extracellular structures, such as in 3D cell cultures, organoids, and spheroids. Cell cultures play a crucial role in life sciences for investigating biological processes within a controlled environment. In recent years, the emphasis has shifted towards cultivating cells in a three-dimensional (3D) setting as opposed to the traditional two-dimensional (2D) approach. This is commonly achieved using a gel-like matrix or scaffold designed to replicate the extracellular matrix present in natural tissues. This approach is particularly useful in cancer research and tissue engineering.
C. elegans (Caenorhabditis elegans)
The transparent nature of the nematode C. elegans makes it suitable for light-sheet microscopy. Researchers can use this model to investigate neural circuits, organ development, and other biological processes.
Drosophila melanogaster (fruit fry)
Fruit flies have been a classic model organism in genetics and developmental biology. Light-sheet imaging can be applied to study Drosophila embryos or other developmental stages, providing detailed information about tissue morphology and cellular dynamics.
Zebrafish (Danio rerio)
Zebrafish are a widely used model organism. The embryos are transparent, allowing for easy visualization of internal structures. They are widely used to study embryonic development, organogenesis, genetics, regeneration and various other physiological processes. Light-sheet microscopy enables researchers to image entire zebrafish embryos at high speeds, with minimal phototoxicity, in 3D over time.
Mouse
Light-sheet microscopy is also applied to study developmental biology, environmental responses, and disease pathogenesis in mice. Especially in the last few years, light-sheet microscopy, in combination with tissue clearing techniques, has become a powerful tool to perform whole-organ or whole-organism multi-dimensional imaging.
