Electrophysiology as a prognostic indicator of visual recovery in diabetic patients undergoing cataract surgery

Type 2 diabetes is one of the most common diseases in older populations and is the major cause of blindness in young adults. Diabetic retinopathy (DR) and optic neuropathy are potentially irreversible sight-threatening complications, with an increased risk of cataracts. The potential benefits of cataract surgery are difficult to predict if fundus examination is obscured, and the management of such cases can be challenging [1, 2].

Full-field electroretinography (ffERG) and flash visual evoked potential (flash VEP) provide objective electrophysiological evaluations of retinal and optic nerve function, respectively [3, 4]. ffERG has been used in the assessment of retinal function associated with microvascular changes in type 2 diabetes [5] and has also been used in patients with cataracts [6, 7]. However, the value of the electrophysiological assessment of retinal and optic nerve function in diabetic patients with cataracts has yet to be established. Thus, the main aim of this study was to determine whether ffERG and flash VEP measures of retinal and optic nerve function are prognostic indicators of visual recovery in diabetic patients with significant lens opacities prior to cataract surgery.

This study adhered to the Declaration of Helsinki principles. The Human Ethics Committees of Southwest Hospital approved the protocol, numbered KY2020054, and all subjects gave their written informed consent.

All subjects underwent routine clinical and pre-operative checks, including visual acuity testing, intraocular pressure assessment, slit-lamp examination, optometry, ophthalmology ultrasound B scans, intraocular lens-master (IOL-Master) examination, or ophthalmology ultrasound A scans to ensure the presence of moderate or severe cataracts and suitability for the study. Each subject also received blood pressure, electrocardiogram, and routine blood tests that included red and white blood cell and platelet, hemoglobin, blood glucose, glycosylated hemoglobin (HbA1c), and glycated albumin (GA) assessments.

The inclusion criteria included male or female patients with moderate or severe cataracts (C2N3P0-C3N3P3 in LOCS scoring) [8] deemed suitable for cataract surgery and aged between 50 and 80 years with type 2 diabetes and well-controlled blood glucose levels. The control group was age-matched non-diabetic patients with cataracts, and normal post-surgical best-corrected visual acuity (BCVA) (logMAR ≤ 0.1) was inclusion criteria for controls. The exclusion criteria included severe hypertension or other systemic diseases; a history of significant eye trauma, keratitis, high myopia, glaucoma, uveitis, retinal detachment, or other severe eye disease; and the inability to complete ophthalmic and electrophysiological examinations.

ffERG was performed in accordance with the International Society for Clinical Electrophysiology of Vision (ISCEV) 2015 standard [9], including dark-adapted (DA) 0.01 ERG, DA 3.0 ERG, DA 3.0 oscillatory potentials (OPs), DA 10.0 ERG, light-adapted (LA) 3.0 single flash ERG, and LA 30 Hz flicker ERG. The pupils were dilated to at least 7 mm in diameter in all cases. Oxybuprocaine hydrochloride eye drops (Santen Pharmaceutical Co., Ltd) were used as a topical anesthesia, and a jet electrode was used as the corneal electrode. Monocular flash VEP (Espion, Diagnosys, USA) recordings were made in accordance with the ISCEV 2016 standard [10] without mydriasis.

The pre-surgery examination, including ffERG and fVEP recording, and other examinations were performed one to 3 days before surgery, and the BCVA post-surgery values were recorded at 1 month ± 3 days following cataract surgery.

The diabetic patients were classified into one of three post-surgical groups on the basis of their BCVA values 1 month after cataract surgery: mild (LogMAR visual acuity, ≤ 0.1), moderate (0.1 < logMAR < 0.5), or severe (LogMAR visual acuity, ≥ 0.5). A fourth group included non-diabetic patients with cataracts. The amplitude and peak times of the main electrophysiological response components were measured, and the data was subdivided into the four post-surgical groups (Table 1) and compared by an analysis of variance (ANOVA).

All statistical analyses were performed using SPSS software (version 25.0; SPSS, Inc., Chicago, IL, USA). One-way ANOVA with Bonferroni correction was used to compare the electrophysiological parameters in the different groups. The post hoc testing was performed using the LSD method in SPSS, and statistical significance was set at P < 0.05. Post hoc testing was performed for conditions with significant effects (Bonferroni correction P_adj < 0.05) in the preceding ANOVA. Spearman’s rank correlation analysis was used to explore the correlation between the key electrophysiological parameters and the post-surgical logMAR BCVA values.

This study examined the value of standardized electrophysiological techniques in the assessment of retinal function in diabetic patients with cataracts. The detailed quantification of full-field ERG parameters enabled the objective assessment of retinal dysfunction and the identification of several ERG components of prognostic value in predicting post-surgical visual outcomes.

Several DA and LA ffERG components were found to be prognostic in predicting BCVA following cataract surgery, and a similar utility of electrophysiology has been reported in evaluations of non-diabetic patients pre- and post-cataract surgery [11, 12]. It is notable that the significant differences between the outcome groups in the current study were greatest in terms of the dark-adapted strong flash (DA 10.0) ERG a-wave. The value of the DA 10.0 ERG a-wave in this context may relate to the retinal response approaching a maximum amplitude irrespective of the media opacity, whereas less-saturated responses to dimmer flashes could be more affected by a reduction in light transmission. The DA 10.0 ERG a-wave normally receives a far greater contribution from the rods than the cones. Although BCVA is normally cone-mediated, the rod-dominated DA 10.0 ERG a-wave may have given the most sensitive indication of underlying diffuse retinal dysfunction and retinopathy in these study patients, which was related to their visual outcomes following surgery. In moderate and severe cases, there may be macular oedema or macular lesions [13, 14], which are likely to influence BCVA irrespective of the ERG findings. The inclusion of a few such macular oedema or macular lesions cases highlights the prognostic value of the ERG, which shows strong correlations despite this potentially confounding variable. The mfERG has been used to assess macular and posterior pole cone system function pre-cataract surgery, but such recordings are likely to be influenced by cataract [12, 15]. A hand-held ffERG device was used to assess diabetic retinopathy, and significant correlations were found between the DR and ffERG waves [16, 17]. In this study, we also found significant correlations between the DR and ffERG waves in the cataract patients, with the DA 10.0 as a new-found more effective mode than other modes in cataract patients.

Optic neuropathy is a potentially irreversible sight-threatening complication of diabetes, but routine assessment may also be confounded by the presence of cataracts. Flash VEP are generally less sensitive than pattern VEP to optic nerve dysfunction and are far less sensitive to the effects of optical degradation [18]. Significant cataract precludes the reliable pre-surgical use of a pattern VEP, but the presence of normal flash VEP peak times and amplitudes in the current series helped to exclude marked optic nerve dysfunction as an exacerbating cause of vision loss.

In spite of the limited number of participants in this study, highly significant differences were observed. A limitation of this study is that the post-surgery retinal structure examinations were performed for each patient; however, the photographic data was incomplete. However, the representative eye structure examination results are shown in Supplementary Figure S2. The evaluation of some of the patient examinations indicated a relationship between the diabetic retinopathy severity and pre-surgery ffERG and post-surgery visual acuity results. Thus, the post-surgery retinal structure parameters might be used to analyze the correlations between the pre-surgery ffERG parameters in the future.

This study shows that pre-surgical, international-standard ffERGs are of value in the management of patients with diabetic retinopathy and cataracts. Multiple ffERG components are related to post-surgical visual outcomes and highlight a relationship between the severity of retinal dysfunction and visual prognosis, which is consistently revealed by the dark-adapted strong flash (DA 10.0) ERG a-wave amplitude, OP2 component, and LA 3.0 a- and b-wave amplitudes. Normal pre-operative flash VEP help exclude marked post-retinal dysfunction as a cause of visual pathology and highlight the value of comprehensive electrodiagnostic testing.