Initial color Doppler findings in retinal vein occlusion

Tranquart, F.; Arsène, S.; Giraudeau, Bruno; Piquemal, R.; Eder, Véronique; Lez, M.L. Le; Rossazza, C; Pourcelot, L.

doi:10.1002/(sici)1097-0096(200001)28:1<28::aid-jcu4>3.0.co;2-5

Cited by 26 publications

(18 citation statements)

References 17 publications

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“…Collateral capacity in symptomatic cases obviously does not suffice to ward off an increase in retinal venous pressure, venous dilation, retinal haemorrhage, retinal oedema and the occasional optic disc oedema. Studies have shown a reduction in retinal venous blood flow velocity using colour Doppler flowmetry,2 3 a reduction in capillary blood flow velocity on the Heidelberg retinal flow meter4 and an increased arteriovenous passage time on fluorescein and indocyanine green angiographies 5–7. Reduction of blood flow leads to retinal hypoxia8–10 and upregulation of vascular endothelial growth factor (VEGF),11 12 which would lead to vasodilation and hyperperfusion 13.…”

Section: Introductionmentioning

confidence: 99%

Retinal vascular oximetry during ranibizumab treatment of central retinal vein occlusion

2014

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Section: Introductionmentioning

confidence: 99%

Retinal vascular oximetry during ranibizumab treatment of central retinal vein occlusion

2014

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“…14 15 Arterial and venous flows are modified at the outset of the disease, and CDI helps in differentiating ischaemic from nonischaemic types of CRVO with a minimum velocity (CRVmin) in the central retinal vein of less than 2 cm/s in non-ischaemic types with a sensitivity of 0.67 and specificity of 0.65. 16 The effect of isovolaemic haemodilution is clearly demonstrated on arterial and venous velocities, with significant improvement from prehaemodilution to post-haemodilution velocities. 17 In a previous study we showed that eyes of patients without RVO and contralateral eyes in RVO patients are similar, with no difference in arterial and venous velocities, thus allowing us to use unaffected eyes as controls.…”

mentioning

confidence: 99%

“…17 In a previous study we showed that eyes of patients without RVO and contralateral eyes in RVO patients are similar, with no difference in arterial and venous velocities, thus allowing us to use unaffected eyes as controls. 16 The natural course of RVO is long and unpredictable, with possible occurrence of ischaemia several months after onset of the disease. 3 18 Arterial and venous flow changes during this evolution remain unknown.…”

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confidence: 99%

Follow up by colour Doppler imaging of 102 patients with retinal vein occlusion over 1 year

Arsène¹,

Giraudeau

Lez

et al. 2002

British Journal of Ophthalmology

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Background/aim: Retinal vein occlusion (RVO) is one of the most frequent ocular vascular diseases and leads to severe vision impairment. Colour Doppler imaging (CDI) is the first method which allows distinct evaluation of arterial and venous velocities in RVO. CDI is valuable for diagnosis of RVO and shows the effects of isovolaemic haemodilution. Patients with RVO were monitored by CDI for 1 year in order to clarify venous and arterial involvement in the pathogenesis of this disease. Methods: Patients with RVO were monitored prospectively for 1 year with clinical examinations, fluorescein angiography, and CDI every 3 months. 102 adults referred for RVO for less than 2 months were enrolled. Unaffected eyes were used as control. The maximum systolic and diastolic flow velocities and the resistance index (RI) were measured in the central retinal artery (CRA) and the maximum and minimum blood flow velocities in the central retinal vein (CRV). Results: During the year of observation, branch retinal vein occlusion (BRVO), ischaemic central retinal vein occlusion (CRVO), and non-ischaemic CRVO had a distinct pattern of venous velocity changes. BRVO had a similar profile to that observed in controls. Venous velocities were continuously lower in central forms, with the lowest values in ischaemic occlusion. In contrast, a brief decrease in arterial diastolic velocity was observed in ischaemic CRVO at presentation, correlated with arteriovenous passage time on fluorescein angiography, but with rapid normalisation. Conclusions: CDI findings were correlated with the type of RVO at all times during follow up. CDI showed persistent impairment of central venous velocity in CRVO whereas there was a fast initial values recovery of the arterial velocity. These results using CDI show strong evidence of a primary venous mechanism in RVO.

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“…8,14,17 [27][28][29][30] and fellow eyes. [31][32][33][34] It has also been suggested that a characteristic decrease in the blood flow velocity in the central retinal vein was highly predictive of iris neovascularisation. 30 Most of the studies in eyes with CRVO that investigated arterial blood flow reported impaired blood flow parameters in the retrobulbar arteries, suggesting that altered arterial blood flow is involved in the pathogenesis of CRVO.…”

Section: Colour Doppler Imaging In Diabetic Retinopathymentioning

confidence: 97%

“…30 Most of the studies in eyes with CRVO that investigated arterial blood flow reported impaired blood flow parameters in the retrobulbar arteries, suggesting that altered arterial blood flow is involved in the pathogenesis of CRVO. [30][31][32][33][35][36][37][38] In branch retinal vein occlusion (BRVO), there have been reports of non-significant differences 34 …”

Section: Colour Doppler Imaging In Diabetic Retinopathymentioning

confidence: 99%

Colour Doppler Imaging of Ocular and Orbital Blood Vessels in Retinal Diseases

Dimitrova¹

2011

European Ophthalmic Review

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ImagingColour Doppler Imaging (CDI) is an established method for investigation of the ocular and orbital blood flow characteristics. It is an ultrasonographic method that has been employed for the evaluation of the circulatory status in much ocular pathology, but is most used for the investigation of the circulatory status in retinal vascular disorders and in glaucoma. [1][2][3] Ultrasound imaging (sonography) is accomplished with a pulse-echo technique. Pulses of ultrasound (generated by a transducer) are sent into the patient where they produce echoes at organ boundaries and within tissues. These echoes then return to the transducer, they are being detected and then displayed. Colour-flow imaging extends the use of the pulse-echo imaging principle. Echoes returning from stationary tissues are detected and presented in greyscale in appropriate locations along the scan line. The depth is determined by the echo's arrival time and the brightness is determined by the echo's amplitude. If a returning echo has a different frequency than what is emitted a frequency change has occurred because the echo-generating object was moving. If the motion is towards or away from the transducer, the Doppler shift is positive or negative, respectively. Along with the transducer, the colour-flow instrument consists of a pulser, a beam-former, a receiver, a memory and a display (see Figure 1).In ophthalmology, CDI is most often used to study the circulatory parameters in the retrobulbar blood vessels -the central retinal artery, central retinal vein, ophthalmic artery and the short and long posterior ciliary arteries. However, intraocular blood vessels have also been studied, such as vortex veins, blood vessels in the intraocular tumours, in detached retina, etc. The measurement is usually obtained through closed eyelids in a supine or in a seated position. Nagahara et al.patented a device for CDI measurement in seated subjects that increased the reproducibility of the measurement by 50% (see Figure 2). 4 The reflected ultrasound from the moving cells in the measured blood vessels is recorded by the CDI device and represented as a velocity wave. Two such velocity waves from the central retinal artery and the central retinal vein are presented in Figure 3.Several blood flow parameters can be obtained from the velocity wave, such as peak systolic blood velocity (PSV), end-diastolic blood velocity (EDV), mean blood velocity (MV), resistivity index (RI) and pulsatility index (PI): RI is calculated as (PSV-EDV)/PSV; PI is calculated as (PSV-EDV)/MV.Although the CDI device is equipped for measurement of blood vessel diameter, the dimension of the retrobulbar blood vessels is too small to obtain a reliable estimation of their diameter. Therefore, total blood flow cannot be evaluated in the retrobulbar blood vessels using CDI.The recording of the blood flow parameters of the central retinal artery and vein is obtained inside the optic nerve, a few millimetres away from the lamina cribrosa (see Figure 3). A specific finding of the blood flo...

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Initial color Doppler findings in retinal vein occlusion

Cited by 26 publications

References 17 publications

Retinal vascular oximetry during ranibizumab treatment of central retinal vein occlusion

Retinal vascular oximetry during ranibizumab treatment of central retinal vein occlusion

Follow up by colour Doppler imaging of 102 patients with retinal vein occlusion over 1 year

Colour Doppler Imaging of Ocular and Orbital Blood Vessels in Retinal Diseases

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