Strategies for reducing variance in laser Doppler flowmetry measurements

Background Scattering of blood flow data as assessed with laser Doppler flowmetry (LDF) in humans is a problem in many studies using this technique. We set out to reduce variability in LDF data by eliminating the effect of the total returning light level (DC) on LDF parameters in the choroid through...

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Bibliographic Details
Published in:Graefe's archive for clinical and experimental ophthalmology 2009, Vol.247 (1), p.67-71
Main Authors: Pemp, Berthold, Maar, Noemi, Weigert, Guenther, Luksch, Alexandra, Resch, Hemma, Garhofer, Gerhard, Orgul, Selim, Schmetterer, Leopold
Format: Article
Language:English
Subjects:
Adult
Basic Science
Blood Pressure
Choroid - blood supply
Choroid - diagnostic imaging
Diagnostic Techniques, Ophthalmological - standards
Female
Heart Rate
Humans
Intraocular Pressure
Laser-Doppler Flowmetry - standards
Linear Models
Male
Medicine
Medicine & Public Health
Ophthalmology
Optic Disk - blood supply
Optic Disk - diagnostic imaging
Reproducibility of Results
Ultrasonography
Young Adult
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Summary:Background Scattering of blood flow data as assessed with laser Doppler flowmetry (LDF) in humans is a problem in many studies using this technique. We set out to reduce variability in LDF data by eliminating the effect of the total returning light level (DC) on LDF parameters in the choroid through partial regression analysis. Methods In 20 healthy subjects, choroidal blood flow parameters were measured at different DC values using a portable confocal LDF device. We used two different strategies to reduce scattering of data eliminating the effect of yield, which is defined as DC/gain. On the one hand, we used a previously described method based on a third-order polynomial fit, which combines all obtained data. On the other hand, we applied a new method based on a linear fit for each individual subject. Results Variability of data during changes in DC is higher for LDF parameters volume and flow than for velocity. Both methods were successful in reducing scattering of LDF parameters with varying DC. Conclusions The present study indicates that both methods to correct for changes in yield were successful in reducing the variability of LDF measurements. When systematic changes in DC occur after an intervention, one needs to be careful in interpreting the obtained data and it remains to be shown if either of the two techniques is capable of correcting for this effect. The approach presented here may, however, represent an effective, easily applicable and valid approach to reduce scattering of data from using LDF to assess blood flow in the posterior pole of the human eye.
ISSN:0721-832X
1435-702X
DOI:10.1007/s00417-008-0942-0