High-resolution deep tissue imaging without being highly invasive is difficult to achieve. Therefore, a new imaging method that allows non- or minimally-invasive image acquisition in vivo and in real-time with sub-cellular spatial resolution, and at sub-second sampling rates is needed.
Can be easily integrated into most (Olympus, Nikon, etc) current 2 photon microscopes, and giving an excellent spatiotemporal resolution of <0.3μm
Minimally invasive recordings from deep tissues such as brain regions (e.g. hippocampus) using anesthetized animals or awake animals that are head-fixed
Provides access to any organ or tissue from the surface to deep structures.
Feature | Pryer 70x |
---|---|
Numerical Aperture | 0.7 |
Resolution | 0.5 um |
Working Band | 400 - 1080 nm |
Field of View | 200 um |
Tip Dimensions | 5.87 mm length / 2.1 mm diameter |
Imaging Depth: | 5.87 mm + 0.2 mm = 6.07 mm |
High-resolution deep tissue imaging without being highly invasive is difficult to achieve. Therefore, a new imaging method that allows non- or minimally-invasive image acquisition in vivo and in real-time with sub-cellular spatial resolution, and at sub-second sampling rates is needed.
Can be easily integrated into most (Olympus, Nikon, etc) current 2 photon microscopes, and giving an excellent spatiotemporal resolution of <0.3μm
Minimally invasive recordings from deep tissues such as brain regions (e.g. hippocampus) using anesthetized animals or awake animals that are head-fixed
Provides access to any organ or tissue from the surface to deep structures.
Feature | Pryer 70x |
---|---|
Numerical Aperture | 0.7 |
Resolution | 0.5 um |
Working Band | 400 - 1080 nm |
Field of View | 200 um |
Tip Dimensions | 5.87 mm length / 2.1 mm diameter |
Imaging Depth: | 5.87 mm + 0.2 mm = 6.07 mm |
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