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eISSN: 2377-4290

Ophthalmology & Visual System

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Received: January 01, 1970 | Published: ,

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Abstract

Purpose: to study changes of ERG and depth of retinal vessels bedding in children with cicatricial ROP.

Methods: We examined 58 children (82 eyes) aged from 6 months to 16 years old with cicatricial ROP. We evaluated maximal and flicker ERG, glial and AB-indexes and location of vessels in the retina using OCT.

Results: In GCL retinal vessels were only in 12 of 82 eyes (15%). In 29 eyes (35%)-they were located in NFL, and in 41 eyes (50%)-extraretinal (on the surface of the retina). There was a relation between the degree of displacement of retinal vessels and presence of extraretinal tissue, as well as a tendency to thinning of the retina in cases with extraretinal localization of the vessels (p <0.01). The incidence of traction retinal detachments and retinoschisis increases with growing degree of the displacement vessels. There was no statistically significant differences in the standard amplitude-time parameters of the ERG, but there was a tendency to growth of glial and AB-indexes with the increasing degree of displacement of the vascular bedding, which corresponds to the nature and frequency of late complications in cicatricial ROP.

Conclusion: These parameters can be important criteria of the severity of the process and important tests helping to detect a preclinical negative trend in cicatricial ROP.

Keywords: retinopathy of prematurity, spectral-domain, optical coherence tomography, retinal vessels, glial index, extraretinal growth, later complications

Abbreviations

ERG, electroretinogram; OCT, optical coherence tomography; ROP, retinopathy of prematurity; NFL, nerve fiber layer; ANOVA, analyses of variance

Introduction

Retinopathy of prematurity (ROP) is a vascular proliferative retinal disease of premature infants and is one of the leading cause of childhood blindness and visual impairment1 and remains the focus of ophthalmologists around the world for decades. Pathological vascularization and subsequent proliferation play a major role in the development and progression of ROP. Criteria of diagnosis, prognosis and indications for treatment of ROP are based on the assessment of retinal vessels.2−5 Electrophysiology is very important in the assessment of the visual sensory system in ROP, considering the complex nature of the formation of vision. The degree of visual loss does not always correlate with the severity of pathology of the eye with ROP, and the level and extent of lesions of the visual sensory system with ROP can be estimated in detail only by electrophysiology.

Changes of the standard electroretinogram (ERG)-the maximum, scotopic, photopic, flicker (FERG), at different stages of ROP are well described by many authors.6–9 Glial index (b-wave/FERG 12 Hz), described by Zueva MV and Tsapenko IV in 1992-2009, reflects the state of glial cells in various degenerative and proliferative retinal conditions such as AMD, diabetic retinopathy, retinal detachment10−12 but it has not been studied well at ROP. Considering rather large avascular zones or coagulates in the periphery of the retina that could significantly affect the results of the study, using FERG at 12 Hz for the calculation of the glial index in patients with cicatricial ROP is not appropriate in our opinion. 30 Hz FERG, in contrast, is more stable and easy to use, because requires no changes to the standard examination protocol. AB-index (also called b/a ratio) was suggested by I. Perlman as an additional method in assessment of the retina.13 It is based on physiological considerations regarding the origin of the ERG components. In children with ROP this method can be used to assess retinal blood flow by evaluating the difference in function of outer and inner retina. At the present stage, despite the active introduction of morphometric techniques in ophthalmic practice only individual papers are devoted to retinal vessels in children. Investigation of blood vessels in infants with ROP was conducted only in the active phase of the disease, and the importance of the progressive changes in caliber and tortuosity of vessels was confirmed for the prognosis of the disease and the choice of tactics of treatment.14−16 A detailed analysis of retinal vessels in cicatricial ROP has not been previously performed. Considering that cicatricial/regressive ROP has a great polymorphism of clinical manifestations, it is necessary to evaluate the role of the vascular component in the pathogenesis of late complications of this disease.

Changes of the standard electroretinogram (ERG)-the maximum, scotopic, photopic, flicker (FERG), at different stages of ROP are well described by many authors.6-9 Glial index (b-wave/FERG 12 Hz), described by Zueva MV and Tsapenko IV in 1992-2009, reflects the state of glial cells in various degenerative and proliferative retinal conditions such as AMD, diabetic retinopathy, retinal detachment10-12 but it has not been studied well at ROP. Considering rather large avascular zones or coagulates in the periphery of the retina that could significantly affect the results of the study, using FERG at 12 Hz for the calculation of the glial index in patients with cicatricial ROP is not appropriate in our opinion. 30 Hz FERG, in contrast, is more stable and easy to use, because requires no changes to the standard examination protocol. AB-index (also called b/a ratio) was suggested by I. Perlman as an additional method in assessment of the retina.13 It is based on physiological considerations regarding the origin of the ERG components. In children with ROP this method can be used to assess retinal blood flow by evaluating the difference in function of outer and inner retina. At the present stage, despite the active introduction of morphometric techniques in ophthalmic practice only individual papers are devoted to retinal vessels in children. Investigation of blood vessels in infants with ROP was conducted only in the active phase of the disease, and the importance of the progressive changes in caliber and tortuosity of vessels was confirmed for the prognosis of the disease and the choice of tactics of treatment.14-16 A detailed analysis of retinal vessels in cicatricial ROP has not been previously performed. Considering that cicatricial/regressive ROP has a great polymorphism of clinical manifestations, it is necessary to evaluate the role of the vascular component in the pathogenesis of late complications of this disease.

Results

ROP findings

We examined 58 children (82 eyes) aged from 6 months to 16 years old at the moment of the first examination and followed them for 5 years (Figure 1). All surveyed children were born of premature birth on gestational age 26-36 weeks (average 29 weeks) and weighing 830-2920 g. (average 1377 g). Prophylactic treatment in active phase was performed on 46 eyes (56.1%). Visual acuity was from 20/20 to 20/400 (mean 20/70). All patients had no general complaints at the time of investigation. Ophthalmoscopic changes in cicatricial ROP included residual avascular zones (82 eyes, 100%), the shift of the vascular bundle (81 eyes, 98.8%, (Figure 2), extraretinal tissue (52 eyes, 63.4%), retinal folds (35 eyes, 42.7%, (Figure 3), degenerative and atrophic focuses (36 eyes, 43.9%), tractional retinoschisis (31 eyes, 37.8%, (Figure 4).

Figure 1 Distribution of children by age at the moment of the first examination.

Figure 2 Scheme of retina of right eye (RE) and left eye (LE) showing zone borders and clock hours used to place OCT scans.5,14,7

Figure 3 Fundus image of cicatricial ROP with shift of the vascular bundle, macular ectopia and epiretinal fibrosis in central zone.

Figure 4 Fundus image of cicatricial ROP with retinal fold in macular zone.

OCT findings

Normally, arteries and veins are localized in the retina ganglion cell layer (GCL).17 Location of blood vessels in our patients was pertaining to the inner surface of the retina. In 12 of 82 eyes (15%) retinal vessels were in GCL (Figure 5). In 29 eyes (35%)-they were located in the nerve fiber layer (NFL), and in 41 eyes (50%)-extraretinal (on the surface of the retina, (Figure 6). Thus, only 15% of cases demonstrated a physiological, GCL location of vessels. We have studied the localization of the retinal vessels in various clinical situations (Table 1). There was a relation between the degree of displacement of retinal vessels and presence of extraretinal tissue, as well as a tendency to thinning of the retina in cases with extraretinal localization of the vessels (p <0.01). Interconnection between gestational age and birth weight with the position of vessels in the retina was not found (p> 0.05). We analyzed the dependency of the frequency of late complications of cicatricial ROP, such as atrophic changes and traction retinoschisis, with the depth of retinal vessels bedding (Figure 7). The Figure 7 shows that the cicatricial ROP proceeded without complications in a quarter of cases at the localization of vessels in GCL (4 eyes) and NFL (7 eyes), and only in 5% of the cases with extraretinal localization (2 eyes). Atrophic changes were more frequent in cases with localization of vessels in GCL (67%, 8 eyes), and traction retinal detachment and retinoschisis –in cases with extraretinal localization (63%, 26 eyes). Atrophy and traction retinoschisis met with the same frequency in cases with localization of retinal vessels in NFL-38% (11 eyes).

Figure 5 Fundus image of tractional retinoschisis on the periphery of the retina.

Figure 6 OCT scan. The arrow indicates the localization of vessels in the ganglion cell layer.

Figure 7 OCT scan. The arrow indicates extraretinal localization of the vessel.

Localization of retinal vessels

Gestationalage (weeks)

Birth weight (grams)

Thickness of neuroepithelium in a zone I (microns)

Presence of extraretinal tissue

GLC

30±0,8

1512±126

285±13

50%

NFL

29,9±0,5

1431±99

280±7

76%

Extraretinal

29,3±0,3

1294±52

239±8

90%

Table 1 Localization of retinal vessels in various clinical situations

ERG findings

We conducted a study of changes of maximal and flicker ERG in different variants of the localization of retinal vessels and the results were similar to the previous studies of ERG in children with history of ROP,6,9,13,14 however, there were no statistically significant differences in the standard amplitude-time parameters of the ERG (Table 2). However the study of AB-and glial index revealed interesting patterns (Figure 8). The glial index was within normal limits when the localization of the retinal vessels was within the GCL and/or the NFL and significantly increased when the localization was extra-retinal. The AB-index was reduced in the presence of retinal vessels in the GCL and when measured with other variants of retinal vessel localization remained within normal limits. To investigate the connection of these changes with the development of late complications in the cicatricial ROP, we examined the AB-and glial indexes at different vitreochorioretinal changes (Figures 9 & 10). When cicatricial ROP was uncomplicated, AB-index was reduced and glial index was within normal limits. In cases with atrophic changes both indexes were reduced. At the development of traction retinal detachments and retinoschisis AB-index was within normal limits and glial index was significantly increased.

GCL

NFL

Extra

Norma

a-wave amplitude

9,3±2,2

13,5±3,1

8,3±0,9

17

a-wave latency

27,9±2,3

29,5±0,9

26,4±1,6

26

b-wave amplitude

30,4±8,5

51,2±5,4

43,8±6,1

165

b-wave latency

56,4±3,2

59,0±1,4

54,6±2,9

61

flicker ERG 30 Hz

6,5±2,3

8,0±0,8

4,5±0,5

16

Table 2 Standard amplitude-time parameters of the ERG in different variants of the localization of retinal vessels

Figure 8 The incidence of vitreochorioretinal changes in different variants of the localization of retinal vessels.

Figure 9 Glial and AB-indexes at different variants of the localization of blood vessels (p<0.05). Green line-normal value of AB-index. Orange lines-range of normal values of glial index.

Figure 10 Glial and AB-indexes at different vitreochorioretinal changes (p<0.05). Green line-normal value of AB-index. Orange lines-range of normal values of glial index.

Discussion

The outer layers of the retina are supplied by choroidal blood vessels while the inner layers of the retina are supplied by retinal blood vessels.18 Displacement of the retinal vessels may cause degenerative processes in the retina. Factors contributing to the displacement of retinal vessels are unknown. In our opinion, a possible theoretical basis for this displacement exists. For example, immaturity of retinal structures due to the aborted embryogenesis and retinal thinning, could lead to the eventual “expulsion” of blood vessels due to a mismatch between the biomechanics of the tissue. Also pathological neovascularization (with eventual vitreoretinal proliferation) may cause tightening, pre-expulsion, and if unchecked, expulsion of the retinal vessels from the retinal surface. In our opinion, the theoretical basis of this displacement can be immaturity of retinal structures in connection with the aborted embryogenesis, thinning of the retina, leading to the “expulsion” of blood vessels, due to mismatch of biomechanical characteristics of the tissue, pathological neovascularization and vitreoretinal proliferation causing “tightening” of the retinal vessels to the retinal surface. Analysis of the correlation of the degree of the displacement of vessels, gestational age and body weight showed that the degree this shift does not depend on the degree of prematurity of a child (p>0.05). The study of correlation between the position of vessels and thickness of the central retina showed that extraretinal localization was characterized by significant thinning of the retina (p<0.01). In other variants of the location of vessels significant deviation from the physiological retinal thickness was absent. Investigation of the depth of the vascular bedding and the presence of extraretinal tissue showed marked direct correlation between these parameters. Analysis of late complications in children with cicatricial ROP revealed a relationship between frequency and nature of vitreochorioretinal changes and depth of retinal vascular bedding. Atrophic changes are common to all variants of the localization, but the incidence of tractional retinal detachments and retinoschisis increases with increasing degree of the displacement vessels.

The method of calculation of glial index, described by Zueva MV and Tsapenko IV, was based on the fact that Muller cells contribute to the b-wave of a single flash ERG,19 but these cells cannot produce rhythm faster than 2 Hz. Therefore, they suggested a glial index as the ratio of the single flash ERG b-wave amplitude to the 12 Hz FERG amplitude. Considering changes in the periphery of the retina (avascular zones, coagulates etc.) that could significantly affect the results of the study, using FERG at 12 Hz for the calculation of the glial index in patients with cicatricial ROP is not appropriate in our opinion, because 12 Hz ERGs are depressed by interactions between ON and OFF retinal pathways,20 which could be changed in eyes with ROP.21 30 Hz FERG, in contrast, is more stable and easy to use, because requires no changes to the standard examination protocol. This interconnection between frequency and nature of vitreochorioretinal changes and depth of retinal vascular bedding is supported by electrophysiological studies-changes of AB-and glial indexes. These parameters were decreased at the presence of atrophic changes and considerably increased (especially glial index) at the development of traction retinoschisis. The study of these parameters in different variants of the localization of retinal vessels showed a tendency to growth of both indexes with the increasing degree of displacement of the vascular bedding, which corresponds to the nature and frequency of late complications in cicatricial ROP.

Conclusion

The analysis of retinal vessels in children with ROP revealed a shift of the vascular bedding to the inner retinal layers with a tendency to extraretinal growth and interdependence of the degree of this displacement to the presence of extraretinal tissue and thickness of the retina. The study showed interconnection between the localization of retinal vessels, changes of AB-and glial ERG indexes and the development of late complications in cicatricial ROP. Thus, these parameters and test results may represent important indicators of the severity of the cicatricial ROP disease process. If determined to be reproducible, these results may indicate a potentially reliable signal of a pre-clinical negative trend in cicatricial ROP.

Summary

This study was based on using modern methods of OCT and ERG (including calculation of different indexes). The study allowed defining displacement of retinal vessels bedding and electrophysiological criterions of later complications of regressive ROP (atrophic changes, tractional retinal detachment etc.).

Acknowledgments

None.

Conflicts of interest

No conflict of interest. No financial disclosure. Presentations at ISCEV 2012 symposium and World ROP Congress III.

References

  1. Gilbert C, Fielder A, Gordillo L, et al. Characteristics of infants with severe retinopathy of prematurity in countries with low, moderate, and high levels of development: implications for screening programs. Pediatrics. 2005;115(5):e518−e525.
  2. An International Classification of Retinopathy of Prematurity. An international classification of retinopathy of prematurity. The Committee for the Classification of Retinopathy of Prematurity. Arch Ophthalmol. 1984;102(8):1130−1134.
  3. An International Classification of Retinopathy of Prematurity. An international classification of retinopathy of prematurity. Int Ophthalmol. 1985;8(1):3−10.
  4. An International Classification of Retinopathy of Prematurity. An International Classification of Retinopathy of Prematurity: II. The Classification of Retinal Detachment. The International Committee for the Classification of the Late Stages of Retinopathy of Prematurity. Arch Ophthalmol. 1987;105(7):906−912.
  5. An International Classification of Retinopathy of Prematurity. The International Classification of Retinopathy of Prematurity revisited. Arch Ophthalmol. 2005;123(7):991−999.
  6. Berezovsky A, Moraes NS, Nusinowitz S, et al. Standard full-field electroretinography in healthy preterm infants. Doc Ophthalmol. 2003;107(3):243−249.
  7. Fulton AB, Hansen RM. Photoreceptor function in infants and children with a history of mild retinopathy of prematurity. J Opt Soc Am A Opt Image Sci Vis. 1996;13(3):566−571.
  8. Mactier H, Dexter JD, Hewett JE, et al. The electroretinogram in preterm infants. J Pediatr. 1988;113(3):607−612.
  9. Mets MB, Smith VC, Pokorny J, et al. Postnatal retinal development as measured by the electroretinogram in premature infants. Doc Ophthalmol. 1995;90(2):111−127.
  10. Neroev VV, Gundorova RA, Zyeva MV, et al. [Electroretinography in the evaluation of vitreoretinal proliferative changes due to penetrating shell injury to the eye]. Vestn Oftalmol. 2007;123(4):36−40.
  11. Neroev VV, Sarygina OI, Zueva M V, et al. [Impact of ozone therapy on the electrophysiological parameters of the retina in patients operated on for its rhegmatogenous detachment]. Vestn Oftalmol. 2007;123(5):33−36.
  12. Zueva MV, Tsapenko IV, Riabina MV, et al. [Electroretinography in the diagnosis and monitoring of treatment for neovascular age-related macular degeneration: Communication 1]. Vestn Oftalmol. 2009;125(4):51−54.
  13. Perlman I. Relationship between the amplitudes of the b wave and the a wave as a useful index for evaluating the electroretinogram. Br J Ophthalmol. 1983;67(7):443−448.
  14. Bankhead P, Scholfield CN, McGeown JG, et al. Fast retinal vessel detection and measurement using wavelets and edge location refinement. PLoS One. 2012;7(3):e32435.
  15. Cheung CS, Butty Z, Tehrani NN, et al. Computer-assisted image analysis of temporal retinal vessel width and tortuosity in retinopathy of prematurity for the assessment of disease severity and treatment outcome. J AAPOS. 2011;15(4):374−380.
  16. Wilson CM, Cocker KD, Moseley MJ, et al. Computerized analysis of retinal vessel width and tortuosity in premature infants. Invest Ophthalmol Vis Sci. 2008;49(8):3577−3585.
  17. Duke-Elder S, Wybar T. System of Ophthalmology. (Vol II) The Anatomy of the Visual System. St.Louis: Mosby, 1961. 534 p.
  18. Saint-Geniez M, D’Amore PA. Development and pathology of the hyaloid, choroidal and retinal vasculature. Int J Dev Biol. 2004;48(8−9):1045−1058.
  19. Robson JG, Frishman LJ. Dissecting the dark-adapted electroretinogram. Doc Ophthalmol. 1998–1999;95(3−4):187−215.
  20. Kondo M, Sieving PA. Primate photopic sine-wave flicker ERG: vector modeling analysis of component origins using glutamate analogs. Invest Ophthalmol Vis Sci. 2001;42(1):305−312.
  21. Luu CD, Koh AHC, Ling Y. The ON/OFF-response in retinopathy of prematurity subjects with myopia. Doc Ophthalmol. 2005;110(2−3):155−161.
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