Log In Sign up
The largest database of trusted experimental protocols

R2200 ultrahigh resolution spectral domain oct system

Manufactured by Bioptigen
Visit Supplier

The R2200 ultrahigh resolution spectral domain OCT system is a laboratory equipment designed for high-resolution optical coherence tomography imaging. It provides a non-invasive, cross-sectional imaging capability with micrometer-scale resolution. The core function of the R2200 is to capture and display detailed images of biological samples or structures.

Automatically generated - may contain errors

Lab products found in correlation

Micron 3 retinal imaging system, by Phoenix Pharmaceuticals (2 mentions)

2 protocols using r2200 ultrahigh resolution spectral domain oct system

1

Quantifying Mouse ONL Thickness via OCT

Check if the same lab product or an alternative is used in the 5 most similar protocols
Live fundus images were obtained with a Micron III Retinal Imaging System (Phoenix Research Laboratories) and an R2200 ultrahigh resolution spectral domain OCT system (Bioptigen). Image acquisition and processing were performed as described previously.58 (link) ONL thickness in one eye of each mouse was determined from OCT volume datasets imported into Fiji at four positions, each ∼250 μm from the optic nerve head in the superior, nasal, temporal and temporal fundus. Thickness was determined from 50-pixel wide lines drawn vertically across the ONL at each position. To identify the ONL boundaries reproducibly, the Plot Profile tool was used to plot image intensity by distance, and the length (in pixels) of a horizontal line between the midpoints of the intensity peaks on either side of the ONL was determined. Values from each eye were averaged and converted to ONL thickness by an axial factor of 1.53 μm/pixel determined from the OCT acquisition program.
Saksens N.T., Krebs M.P., Schoenmaker-Koller F.E., Hicks W., Yu M., Shi L., Rowe L., Collin G.B., Charette J.R., Letteboer S.J., Neveling K., van Moorsel T.W., Abu-Ltaif S., De Baere E., Walraedt S., Banfi S., Simonelli F., Cremers F.P., Boon C.J., Roepman R., Leroy B.P., Peachey N.S., Hoyng C.B., Nishina P.M, & den Hollander A.I. (2015). Mutations in CTNNA1 cause butterfly-shaped pigment dystrophy and perturbed retinal pigment epithelium integrity. Nature genetics, 48(2), 144-151.
+ Open protocol
+ Expand
2

Quantifying Mouse ONL Thickness via OCT

Check if the same lab product or an alternative is used in the 5 most similar protocols
Live fundus images were obtained with a Micron III Retinal Imaging System (Phoenix Research Laboratories) and an R2200 ultrahigh resolution spectral domain OCT system (Bioptigen). Image acquisition and processing were performed as described previously.58 (link) ONL thickness in one eye of each mouse was determined from OCT volume datasets imported into Fiji at four positions, each ∼250 μm from the optic nerve head in the superior, nasal, temporal and temporal fundus. Thickness was determined from 50-pixel wide lines drawn vertically across the ONL at each position. To identify the ONL boundaries reproducibly, the Plot Profile tool was used to plot image intensity by distance, and the length (in pixels) of a horizontal line between the midpoints of the intensity peaks on either side of the ONL was determined. Values from each eye were averaged and converted to ONL thickness by an axial factor of 1.53 μm/pixel determined from the OCT acquisition program.
Saksens N.T., Krebs M.P., Schoenmaker-Koller F.E., Hicks W., Yu M., Shi L., Rowe L., Collin G.B., Charette J.R., Letteboer S.J., Neveling K., van Moorsel T.W., Abu-Ltaif S., De Baere E., Walraedt S., Banfi S., Simonelli F., Cremers F.P., Boon C.J., Roepman R., Leroy B.P., Peachey N.S., Hoyng C.B., Nishina P.M, & den Hollander A.I. (2015). Mutations in CTNNA1 cause butterfly-shaped pigment dystrophy and perturbed retinal pigment epithelium integrity. Nature genetics, 48(2), 144-151.
+ Open protocol
+ Expand

About PubCompare

Our mission is to provide scientists with the largest repository of trustworthy protocols and intelligent analytical tools, thereby offering them extensive information to design robust protocols aimed at minimizing the risk of failures.

We believe that the most crucial aspect is to grant scientists access to a wide range of reliable sources and new useful tools that surpass human capabilities.

However, we trust in allowing scientists to determine how to construct their own protocols based on this information, as they are the experts in their field.

Ready to get started?

Sign up for free.
Registration takes 20 seconds.
Available from any computer
No download required

Sign up now

Revolutionizing how scientists
search and build protocols!