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Ординатура / Офтальмология / Учебные материалы / Retinal Vein Occlusions Springer.pdf
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342

 

 

1 Retinal Vein Occlusions in the Young

Table 14.2 Initial and follow-up visual acuities in younger patients with CRVO

 

VA group

Initial percentage

Follow-up percentage

F/U time (months)

Reference/N

20/15–20/40

39

35

32a

Fong and Schatz7/103

 

36

34

6

Recchia et al.30/57

20/50–20/100

27

14

32a

Fong and Schatz7/103

20/50–20/200

44

40

6

Recchia et al.30/57

20/200–20/400

19

17

32a

Fong and Schatz7/103

<20/200

17

25

6

Recchia et al.30/57

<20/400

17

16

32a

Fong and Schatz7/103

VA visual acuity, N number of patients in the study, F/U follow-up aAverage follow-up time, range 6–132 months

Table 14.3 Visual prognosis of central retinal vein occlusion in younger patients depending on capillary perfusion status

Capillary perfusion status

Improve ³2 lines (%)

No change (%)

Worsen ³2 lines (%)

References

Nonischemic

42

49

8

Fong and Schatz7

 

43

38

19

Kuo et al.21

Ischemic

27

30

43

Fong and Schatz7

 

0

78

22

Kuo et al.21

There were 103 eyes in the study of Fong and Schatz7 and 25 eyes in the study of Kuo et al.21

for these probably ischemic eyes.34 A separate series of 11 cases of CRVO in patients of age 45 or younger, however, documented a poor visual prognosis in the ischemic group.9

Intraocular neovascularization of any type after CRVO in 67 younger patients followed for a mean of 29 months has been reported to occur in 18%, ASNV in 11%, posterior segment neovascularization (PSNV) in 9%, and NVG in 5%.30 In another study of 103 younger patients with CRVO followed for an average of 32 months, ASNV occurred in 19%, PSNV in 3%, and NVG in 8%.8 These percentages are generally lower than median percentages reported for case series without age constraints (see Chaps. 10 and 11; Table 11.4). Patients developing intraocular neovascularization had a similar profile of systemic associations compared to patients who did not.30

14.4Workup in the Younger Patient with Retinal Vein Occlusion

As for RVO in older patients, the available evidence suggests that in younger patients, investigating for unsuspected hypertension is worthwhile.23 Although some have recommended

a search for various associated laboratory abnormalities if no common vascular risk factors are present, the evidence to support the recommendation is poor.23 Because of the rarity of finding thrombophilia in a young patient without vascular risk factors and with no personal or family history of thrombosis or miscarriage, most would recommend no special laboratory workup (see Chap. 6).29,32

14.5 Summary of Key Points

The cutoff point in the definition of “younger” varies from 40 to 60 in studies of RVO. Therefore, combining results across studies is problematic.

Approximately 5% of BRVOs, 10% of HCRVOs, and 15% of CRVOs occur in patients of age 45 and younger.

No thrombophilic associations are recognized in population-based samples of younger patients with BRVO or CRVO compared to control samples without RVO. Specific patients with RVO may have thrombophilia.

There is no evidence that CRVO in younger patients has an inflammatory basis. Papillophlebitis and benign retinal vasculitis

References

 

343

 

(historical terms for CRVO in younger

8.

Fong ACO, Schatz H, McDonald HR, Burton TC,

 

patients) are misnomers.

 

Maberley AL, Joffe L, Zegarra H, Nadel AJ,

Younger patients with CRVO may show fewer

 

Johnson RN. Central retinal vein occlusion in young

 

adults (papillophlebitis). Retina. 1992;12:3–11.

 

retinal hemorrhages, a lower incidence of

 

 

9. Frucht J, Yanko L, Merin S. Central retinal vein occlu-

 

macular edema, and more frequent cilioretinal

 

sions in young adults. Acta Ophthamol. 1984;62:780–6.

 

artery insufficiency or occlusion than older

10.

Gottlieb JL, Blice JP, Mestichelli B, Konkle BA,

 

patients with CRVO.

 

Benson WE. Activated protein C resistance, factor V

 

 

leiden, and central retinal vein occlusion in young

The relative proportions of nonischemic and

 

 

adults. Arch Ophthalmol. 1998;116:577–9.

 

ischemic CRVOs among younger patients are

11. Hart CD, Sanders MD, Miller SJ. Benign retinal vas-

 

approximately the same as in older patients.

 

culitis: clinical and fluorescein angiographic study. Br

Younger patients with nonischemic CRVO

 

J Ophthalmol. 1971;55:721–33.

12.

Hayreh SS. So-called “central retinal vein occlusion”

 

have a better VA prognosis than older patients

 

 

II: venous stasis retinopathy. Ophthalmologica. 1976;

 

with nonischemic CRVO.

 

172:14–37.

Younger patients with ischemic CRVO have

13. Hayreh SS, Fraterrigo L, Jonas J. Central retinal vein

 

as poor a VA prognosis as older patients with

 

occlusion associated with cilioretinal artery occlu-

 

 

sion. Retina. 2008;28:581–94.

 

ischemic CRVO, but the younger patients

 

 

14.

Hayreh SS, Podhajsky PA, Zimmerman MB. Natural

 

progress to neovascular complications less

 

history of visual outcome in central retinal vein occlu-

 

often.

15.

sion. Ophthalmology. 2011;118:119–33.

In the absence of a personal or family history

Hayreh SS, Zimmerman B, Mccarthy MJ, Podhajsky P.

 

Systemic diseases associated with various types of retinal

 

of thrombosis, miscarriage, or bilateral or mul-

 

 

 

vein occlusion. Am J Ophthalmol. 2001;2001:61–77.

 

tiple RVO, no special laboratory workup is rec-

16.

Hayreh SS, Zimmerman MB, Podhajsky P. Incidence

 

ommended for younger patients with RVO.

 

of various types of retinal vein occlusion and their

 

 

 

recurrence and demographic characteristics. Am J

 

 

 

Ophthalmol. 1994;117:429–41.

 

 

17.

Incorvaia C, Parmeggiani F, Costagliola C,

References

 

Lamberti G, Ferraresi P, Bernardi F, Sebastiani A. The

 

heterozygous 20210 G/A genotype prevalence in

 

 

 

patients affected by central and branch retinal vein

 

 

 

occlusion: a pilot study. Graefes Arch Clin Exp

1. Abu El-Asrar AM, Gader AGMA, Al-Amro S,

 

Ophthalmol. 2001;239:251–6.

 

Al-Momen AK. Hypercoagulable states in patients

18. Kalayci D, Gurgey A, Guven D, Parlak H, Hasiripi H.

 

with retinal venous occlusion. Doc Ophthalmol. 1998;

 

Factor V Leiden and prothrombin 20210 A mutations

 

95:133–43.

 

in patients with central and branch retinal vein occlu-

2. Biancardi AL, Gadelha T, Borges WIA, de Moraes MV,

 

sions. Acta Ophthalmol Scand. 1999;77:622–4.

 

Spector N. Thrombophilic mutations and risk of retinal

19.

Kohner EM, Cappin JM. Do medical conditions have

 

vein occlusion. Arq Bras Oftalmol. 2007;70:971–4.

 

an Influence on central retinal vein occlusion? Proc R

3. Cruciani F, Moramarco A, Curto T, Labate A, Recupero

 

Soc Med. 1974;67:1052–4.

 

V, Conti L, Gandolfo GM, Balacco Gabrieli C. MTHFR

20.

Kuhli C, Hattenbach LO, Scharrer I, Koch F,

 

C677T mutation, factor II G20210A mutation and fac-

 

Ohrloff C. High prevalence of resistance to APC in

 

tor V Leiden as risks factor for youth retinal vein occlu-

 

young patients with retinal vein occlusion. Graefe

 

sion. Clin Ter. 2003;154:299–303.

 

Arch Clin Exp Ophthalmol. 2002;240:163–8.

4. D’Amato RJ, Miller NR, Fine SL, Enger C, Quinlan P,

21. Kuo JZC, Lai CC, Ong FSC, Shih CP, Yeung L, Chen TL,

 

Elman MJ. The effect of age and initial VA on the sys-

 

Chen KJ, Wu WC. Central retinal vein occlusion in a

 

temic and visual prognosis of central retinal vein occlu-

 

young Chinese population; Risk factors and associated

 

sion. Aust N Z J Ophthalmol. 1991;19:119–22.

 

morbidity and mortality. Retina. 2010;30:479–84.

5. Di Capua M, Coppola A, Albisinni R, Tufano A, Guida

22. Lahey JM, Tunc M, Kearney J, Modlinski B, Koo H,

 

A, Di Minno MN, Cirillo F, Loffredo M, Cerbone AM.

 

Johnson RJ, Tanaka S. Laboratory evaluation of

 

Cardiovascular risk factors and outcome in patients

 

hypercoagulable states in patients with central retinal

 

with retinal vein occlusion. J Thromb Thrombolysis.

 

vein occlusion who are less than 56 years of age.

 

2010;30:16–22.

 

Ophthalmology. 2002;109:126–31.

6. Dodson PM, Kritzinger EE. Underlying medical con-

23. Lam HD, Lahey JM, Kearney JJ, Ng RR, Lehmer JM,

 

ditions in young patients and ethnic differences in reti-

 

Tanaka SC. Young patients with branch retinal vein occlu-

 

nal vein occlusion. Trans Ophthalmol Soc UK.

 

sion: a review of 60 cases. Retina. 2011;30:1520–3.

 

1985;104(Pt 2):114–9.

24. Larsson J, Olafsdottir E, Bauer B. Activated protein C

7. Fong ACO, Schatz H. Central retinal vein occlusion in

 

resistance in young adults with central retinal vein

 

young adults. Surv Ophthalmol. 1993;37:393–417.

 

occlusion. Br J Ophthalmol. 1996;80:200–2.

344

1 Retinal Vein Occlusions in the Young

25. Lonn LI, Hoyt WF. Papillophlebitis: a cause of protracted yet benign optic disc edema. Eye Ear Nose Throat Mon. 1966;45:62–8.

26.Magargal LE, Brown GC, Augsburger JJ, Parrish RK. Neovascular glaucoma following central retinal vein obstruction. Ophthalmology. 1981;88:1095–101.

27.Mcleod D. Central retinal vein obstruction with cilio-

retinal infarction. Eye. 2003;17:283.

28. Mitchell P, Smith W, Chang A. Prevalence and associations of retinal vein occlusion in Australia: the Blue Mountains Eye Study. Arch Ophthalmol. 1996; 114:1243–7.

29.Priluck I, Robertson D, Hollenhorst R. Long-term follow-up of occlusion of the central retinal vein in young adults. Am J Ophthalmol. 1980;90:190–202.

30.Recchia FM, Carvalho-Recchia CA, Hassan TS. Clinical course of younger patients with central retinal vein occlusion. Arch Ophthalmol. 2004;122:317–21.

31.Salomon O, Moisseiev J, Rosenberg N. Analysis of genetic polymorphisms related to thrombosis and other risk factors in patients with retinal vein occlusion. Blood Coagul Fibrinolysis. 1998;9:617–22.

32.Tourville E, Schachat AP. Plasma proteins-possible risk factors for retinal vascular occlusive disease. 2007;424–42

33.Vannas S, Raitta C. Anticoagulant treatment of retinal venous occlusion. Am J Ophthalmol. 1966;62:874–84.

34.Walters RF, Spalton DJ. Central retinal vein occlusion in people aged 40 years or less: a review of 17 patients. Br J Ophthalmol. 1990;74:30–5.

35.Weger M, Renner W, Steinbrugger I, Cichocki L, Temmel W, Stanger O, El Shabrawi Y, Lechner H, Schmut O, Haas A. Role of thrombophilic gene polymorphisms in branch retinal vein occlusion. Ophthalmology. 2005;112:1910–5.

Chapter 15

Failed and Unadopted Treatments for Retinal Vein Occlusions

The history of treatments for many diseases is often as notable for failures as for successes. For retinal vein occlusions (RVO), the list of failed therapies is particularly long. A review of the failures and an analysis of the reasons may be helpful for future attempts at devising more successful therapy than we currently have. Reasons for failure range widely: treatment is based on an erroneous conception of pathogenesis, too many complications relative to successes, and insufficient efficacy relative to cost. Some treatments have not been failures, but have not been adopted for other reasons. An example would be laser chorioretinal venous anastomosis (LCRVA) for nonischemic central retinal vein occlusion (CRVO). A randomized, controlled clinical trial has shown that LCRVA is efficacious compared to observation.39 Nevertheless, the treatment has not been adopted because other treatments (e.g., intravitreal injections (IVI) of antivascular endothelial growth factor (VEGF) drugs) have been perceived, although not proven in head-to-head comparison, to be better.6 These unadopted treatments are also covered here. Abbreviations commonly used in the discussion of failed and unadopted treatments for RVO are listed in Table 15.1. Each abbreviation is spelled out at its first occurrence.

Table 15.1 Abbreviations used in failed and unadopted treatments for retinal vein occlusions

Abbreviation

Term

ASNV

Anterior segment

 

neovascularization

BRVO

Branch retinal vein occlusion

CRVO

Central retinal vein occlusion

CVOS

Central vein occlusion study

DD

Disc diameter

FA

Fluorescein angiogram

HCRVO

Hemicentral retinal vein occlusion

IU

International unit

IVI

Intravitreal injection

logMAR

Logarithm of the minimum angle

 

of resolution

LCRVA

Laser chorioretinal venous

 

anastomosis

ME

Macular edema

mfERG

Multifocal electroretinogram

POAG

Primary open-angle glaucoma

PSNV

Posterior segment

 

neovascularization

PRP

Panretinal photocoagulation

REVS

Retinal endovascular surgery

RON

Radial optic neurotomy

RVO

Retinal vein occlusion

TPA

Tissue plasminogen activator

VA

Visual acuity

VEGF

Vascular endothelial growth factor

W

Watt

D.J. Browning, Retinal Vein Occlusions, DOI 10.1007/978-1-4614-3439-9_15,

345

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