Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-24T15:29:01.542Z Has data issue: false hasContentIssue false

Electroretinography in psychiatry: A systematic literature review

Published online by Cambridge University Press:  01 January 2020

Peter Youssef
Affiliation:
Bachelor of Health Sciences Program, McMaster University, Hamilton, Ontario, Canada
Siddharth Nath
Affiliation:
MD/PhD Program, McMaster University, Hamilton, Ontario, Canada
Gary A Chaimowitz
Affiliation:
Department of Psychiatry and Behavioural Neurosciences, McMaster University, Hamilton, Ontario, Canada Forensic Psychiatry Program, St. Joseph’s Healthcare Hamilton, Hamilton, Ontario, Canada
Sebastien S. Prat*
Affiliation:
Department of Psychiatry and Behavioural Neurosciences, McMaster University, Hamilton, Ontario, Canada Forensic Psychiatry Program, St. Joseph’s Healthcare Hamilton, Hamilton, Ontario, Canada
*
*Corresponding author at: Forensic Psychiatry Program, St. Joseph’s Healthcare Hamilton, Hamilton, ON L8N 3K7, Canada. E-mail address: [email protected] (S.S. Prat).

Abstract

This review aims to consolidate the available information on use of electroretinography as a diagnostic tool in psychiatry. The electroretinogram (ERG) has been found to have diagnostic utility in cocaine withdrawal (reduced light-adapted b-wave response), major depressive disorder (reduced contrast gain in pattern ERG), and schizophrenia (reduced a- and b-wave amplitudes). This review examines these findings as well as the applicability of ERG to substance use disorder, Alzheimer’s disease, autism spectrum disorder, panic disorder, eating disorders, attention deficit hyperactivity disorder, and medication use. While there have been promising results, current research suffers from a lack of specificity. Further research that quantifies anomalies in ERG present in psychiatric illness is needed.

Type
Review / Meta-analyses
Copyright
Copyright © European Psychiatric Association 2019

1. Introduction

Diagnosis of mental illness is often a lengthy and involved process. As definitions and categorizations of diseases become increasingly complex, a search for objective biomarkers of mental illness is underway to facilitate swift and accurate clinical assessment [Reference Lavoie, Maziade and Hébert1]. Because the retina uses neurotransmitters for phototransduction, it is hypothesized that the deregulation of neurotransmitter physiology present in many mental illnesses may be detectable through assessment of retinal function.

The electroretinogram (ERG), is a non-invasive diagnostic test that measures electrical activity generated by neuronal and non-neuronal cells within the retina and has shown utility in the assessment of psychiatric illnesses [Reference Lavoie, Maziade and Hébert1Reference Brown3]. It measures electrical impulses through a contact lens which can detect summation of retinal electrical activity at the corneal surface. In mouse models, it has been shown that alterations in retinal dopaminergic and serotonergic neurotransmission parallel abnormalities observed in ERG recordings [Reference Lavoie, Illiano, Sotnikova, Gainetdinov, Beaulieu and Hébert2].

The ERG outputs multiple waveforms, which represent different components of retinal electrophysiology [Reference McCulloch, Marmor and Brigell4]. Of these, two waveforms have been shown to be especially important in the setting of psychiatry: the a-wave and the b-wave. The a-wave is representative of photoreceptor function and is measured as the height of the baseline electrical activity before flash onset to the trough of the first wave. The b-wave reflects bipolar cell function and is measured from the trough of the a-wave to the peak of the second wave [Reference McCulloch, Marmor and Brigell4]. Examples of ERG waveforms are shown in Fig. 1.

Fig. 1. fERG, PERG, and mfERG waveforms and parameters. Waveforms based on information provided in included studies.

There exist different types of ERGs, which can assess varied components of the retina. The full-field flash ERG (fERG) assesses the electrophysiological response to a flash of light and is well-established and routinely used in ophthalmology [Reference McCulloch, Marmor and Brigell4]. It is also under investigation for applications in psychiatry. The fERG assesses retinal function under dark-adapted (scotopic) or light-adapted (photopic) settings. The scotopic fERG is usually indicative of rod function, while the photopic fERG commonly correlates with cone function [Reference McCulloch, Marmor and Brigell4]. Mixed cone/rod responses may also be elicited on scotopic ERG. In addition to fERG, pattern ERG (PERG) is also under evaluation in psychiatric populations. PERG provides information regarding macular, bipolar, and retinal ganglion cell function by stimulation with a rapidly reversing high-contrast black and white checkerboard or alternating horizontal and vertical lines, and therefore also allows for inferences of retinal contrast sensitivity [Reference Hildebrand, Fielder, Reynolds and Olitsky7, Reference Bach, Brigell and Hawlina8]. Moreover, some investigators have also begun to study the newer multifocal ERG (mfERG) in the setting of mental illness. This ERG measures the response from hundreds of points on the retina simultaneously and creates a ‘topographic map’ of retinal functioning [Reference Hood, Bach and Brigell9].

Although there remains contention with regards to the neurochemical basis of ERG waves, retinal physiology is known to be primarily dependent on glutamate [Reference Hildebrand, Fielder, Reynolds and Olitsky7]. Thus, it is hypothesized that changes to the glutamate neurotransmitter system, as are observed in many psychiatric illnesses, may manifest in different ERG profiles in varied disease states. Some groups hypothesize that the retinal endocannabinoid system, dopamine system, or the GABAergic system may also be at play, allowing for insight into psychiatric conditions resulting from aberrant functioning of these signaling pathways [Reference Lavoie, Illiano, Sotnikova, Gainetdinov, Beaulieu and Hébert2, Reference Schwitzer, Schwan, Angioi-Duprez, Giersch and Laprevote5, Reference Ladien, Levett and Clarke6].

This review explores variations in ERG waveforms across several different psychiatric populations and highlights potential applications for ERG in the detection and assessment of mental illness.

2. Material and methods

2.1 General methods

The present review was conducted in line with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement [Reference McInnes, Moher and Thombs10].

2.2 Literature search

We performed a systematic search of the Web of Science electronic database using the following keywords: ‘electroretinogram’, ‘electroretinography’, and [‘electroretinography’ + psychiatry (topic)]. To ensure we captured all available evidence in the field, our sole eligibility criteria was that ERG was used on human subjects for diagnosis or assessment of mental illness. We excluded articles not investigating psychiatric conditions, articles with the keyword ‘ophthalmology’, as well as wet lab research and animal studies. Our electronic search was supplemented by reviewing the references of included articles. For the purposes of our review, Alzheimer’s disease was considered a psychiatric condition and was thus included, while epilepsy was considered a neurological condition and was excluded. We included both full reports and conference proceedings, provided that a subsequent article had not been published.

2.3 Data collection

We downloaded the complete articles of all included studies. We created data extraction forms with fields for: population studied, type of ERG (fERG, PERG, mfERG), study design, and ERG results.

3. Results

3.1 General results

Our literature search yielded 9,195 results, from which 55 articles met our inclusion criteria (Fig. 2). Articles covered a spectrum of psychiatric illnesses including substance use, depressive disorders, schizophrenia, panic disorder, and eating disorders. Most articles focused on the applicability of ERG to substance use, depressive disorders, and schizophrenia, with a minority investigating panic disorder and eating disorders. Distribution of psychiatric illnesses amongst the articles is shown in Fig. 3.

Fig. 2. PRISMA flow diagram. The selection process for identifying eligible studies is shown.

Fig. 3. Number of articles by specific psychiatric illness and topic.

Included articles covered over 30 years of research and a timeline of how the landscape of the field has evolved is shown in Fig. 4. Notably, there has been increased interest in the applicability of ERG to psychiatric illness. Use of ERG as a diagnostic tool has had an early start in the scientific literature, however, there has been little success in establishing it for clinical use. As shown, there are also periods with little research progress, concordant with periods of plateauing in technological innovation.

Fig. 4. Timeline of the literature on applications of ERG in psychiatry stratified by specific illness and topic.

3.2 Substance use

We found 15 articles evaluating the effects of various substances on ERG [Reference Ladien, Levett and Clarke6, 11Reference Kim, Yun, Kim, Oh and Huh24]. Of these, nine studied the effects of cocaine, three studied cannabis, two studied alcohol, and one studied mixed drug use. A complete summary of the included studies and their findings is shown in Table 1.

Table 1 Articles on substance use.

Notes: CI = confidence interval; CSF = cerebrospinal fluid; ERG = electroretinogram; fERG = flash electroretinogram; mfERG = multifocal electroretinogram; PERG = pattern electroretinogram.

In the setting of cocaine use, it was noted that there was decreased light-adapted b-wave amplitude on fERG. Moreover, cocaine craving was observed to correlate with a depression in the b-wave amplitude [Reference Roy, Smelson and Roy12, Reference Roy, Roy, Smelson, Brown and Weinberger14, Reference Roy, Roy, Berman and Gonzalez17, Reference Smelson, Roy and Roy18]. Variable levels of correlation were noted across studies, with calculated r-values ranging from 0.35 to 0.9.

Studies reporting on cannabis use presented varied parameters. Two articles [Reference Schwitzer, Schwan, Angioi-Duprez, Giersch and Laprevote5, Reference Schwitzer, Schwan and Albuisson23] reported an increase in implicit time, with Schwitzer et al. [Reference Schwitzer, Schwan, Angioi-Duprez, Giersch and Laprevote5] reporting a sensitivity of 78.6% (95% CI 60.5–89.8) and a specificity of 75.0% (95% CI 55.1–88.1) for an N95 implicit time longer than 93.15 ms for PERG.

For alcohol consumption, one study [Reference Ladien, Levett and Clarke6] found a reduced dark-adapted b-wave amplitude on fERG.

3.3 Alzheimer’s disease

Four studies evaluating differences in ERG waveforms in Alzheimer’s disease met our inclusion criteria [Reference Katz, Rimmer, Iragui and Katzman25Reference Strenn, Dal-Bianco, Weghaupt, Koch, Vass and Gottlob28], all of which used PERG. No studies were able to determine a statistically significant difference in PERG in patients with Alzheimer’s disease, however, a trend was noted towards a reduced b-wave amplitude. Details of studies investigating Alzheimer’s disease are shown in Table 2.

Table 2 Articles on Alzheimer’s disease.

Notes: PERG = pattern electroretinogram.

3.4 Autism spectrum disorder

Similar to Alzheimer’s disease, four articles studying ERG in the context of autism spectrum disorder were included in our review [Reference Ritvo, Creel, Realmuto, Crandall and Freeman29Reference Constable, Gaigg, Bowler, Jägle and Thompson32]. Three articles [Reference Ritvo, Creel, Realmuto, Crandall and Freeman29, Reference Realmuto, Purple, Knobloch and Ritvo30, Reference Constable, Gaigg, Bowler, Jägle and Thompson32] used a fERG while one used a PERG [Reference van Elst, Bach, Blessing, Riedel and Bubl31]. Articles using a fERG found a decreased b-wave amplitude (rod function) in patients with autism spectrum disorder, however, quantitative analyses were not provided. Realmuto et al. [Reference Realmuto, Purple, Knobloch and Ritvo30] showed a similar reduction in a families of patients with four siblings and two fathers affected, congruent with the neurodevelopmental origin of autism. Results from studies in this group are shown in Table 3.

Table 3 Articles on autism spectrum disorder.

Notes: fERG = flash electroretinogram; PERG = pattern electroretinogram.

3.5 Depressive disorders

12 articles evaluating ERG in depressive disorders were eligible [33Reference Hébert, Beattie, Tam, Yatham and Lam44]. Seven of these studied seasonal affective disorder (SAD) and the remaining five major depressive disorder (MDD). There was little consistency in protocol across studies, making cross-comparisons difficult. For MDD, a trend was noted towards decreased contrast gain on PERG, especially for moderate-to-severe depression, although Fam et al. [Reference Fam, Rush, Haaland, Barbier and Luu42], were unable to replicate these findings. Notably, studies also evaluated the impact of interventions on MDD and found that ERG abnormalities resolved with treatment. Similarly, studies evaluating SAD showed variable results on ERG, although there was normalization of irregularities with light therapy or during the summer months [Reference Lavoie, Lam and Bouchard36]. Details of the studies investigating depressive disorders are shown in Table 4.

Table 4 Articles on depressive disorders.

Notes: BDI = Beck Depression Inventory; ERG = electroretinogram; fERG = flash electroretinogram; HAM-D = Hamilton Depression Rating Scale; MDD = major depressive disorder; PERG = pattern electroretinogram; SAD = seasonal affective disorder; SSAD = sub-syndromal seasonal affective disorder.

3.6 Schizophrenia

In total, 11 articles investigating ERG in the context of schizophrenia were eligible [45Reference Demmin, Davis, Roché and Silverstein55]. All but one of the articles used the fERG [45Reference Silverstein, Demmin, Erickson, Thompson and Paterno53, Reference Demmin, Davis, Roché and Silverstein55], with the remaining article implementing PERG [Reference Laprevote, Bernardin, Schwitzer and Schwan54]. Hébert et al. [Reference Hébert, Mérette and Paccalet50] noted an increase in implicit time in patients with schizophrenia. Across articles, there was also a trend of reduced a- and b-wave amplitudes in schizophrenia. Interestingly, Gerbaldo et al. [Reference Gerbaldo, Thaker, Tittel, Layne-Gedge, Moran and Demisch46] failed to find this reduction, although their study population differed from that of other articles as it included individuals with a history of sungazing. The most powered study in this group, by Hébert et al. [Reference Balogh, Benedek and Kéri48], showed reductions in both a- and b-wave amplitudes. Notably, Demmin et al. [Reference Demmin, Davis, Roché and Silverstein55] also provided data on photopic negative response, noting that the schizophrenia group demonstrated attenuated negativity in comparison to healthy controls. Full details of articles investigating ERG in schizophrenia are available in Table 5.

Table 5 Articles on schizophrenia.

Notes: ERG = electroretinogram; fERG = flash electroretinogram; PANSS = Positive and Negative Syndrome Scale; PERG = pattern electroretinogram.

3.7 Panic disorder

Two articles evaluating the diagnostic ability of fERG in participants with panic disorder were included in our review [Reference Pieraccini, Bossini and Martinucci56, Reference Bossini, Padula, Valdagno and Castrogiovanni57]. Both articles found decreased b-wave amplitudes in patients, and reduced differences between right and left eyes in the b-wave amplitudes. The details of these two studies are discussed in Table 6.

Table 6 Articles on panic disorder.

Notes. fERG= flash electroretinogram.

3.8 Eating disorders

Only two studies evaluating ERG in the context of eating disorders met our inclusion criteria [Reference Nasser, Parigi, Merhige, Wolper, Geliebter and Hashim58, Reference Moschos, Moustafa, Gonidakis and Papageorgiou59]. Nasser et al. [Reference Nasser, Parigi, Merhige, Wolper, Geliebter and Hashim58] discussed oral food stimulation in the setting of binge eating, while the study by Moschos et al. [Reference Moschos, Moustafa, Gonidakis and Papageorgiou59] discussed anorexia nervosa. An increase in b-wave amplitude in response to brownie consumption and a correlation between the Gormally Binge Eating Scale and increased b-wave amplitude (r = 0.68) was noted on fERG for binge eating. Moreover, the authors noted that there was a similar increase in b-wave amplitude following administration of methylphenidate [Reference Nasser, Parigi, Merhige, Wolper, Geliebter and Hashim58]. In anorexia nervosa, a decreased P1 retinal response density amplitude was found for ring 1 using mfERG [Reference Moschos, Moustafa, Gonidakis and Papageorgiou59]. Complete details of studies in this group are available in Table 7.

Table 7 Articles on eating disorders.

Notes. fERG= flash electroretinogram; mfERG= multifocal electroretinogram.

3.9 Attention deficit hyperactivity disorder

One article discussing attention deficit hyperactivity disorder (ADHD) was eligible, and it utilized the PERG [Reference Bubl, Werner and Liang60]. Treatment with methylphenidate was also discussed. The authors found that there was increased background noise on PERG in patients and that this normalized with treatment. Table 8 includes details of the article investigating ERG in ADHD.

Table 8 Articles on ADHD.

Notes. ADHD= attention deficit hyperactivity disorder; PERG= pattern electroretinogram.

3.10 Medication

Five articles assessed the effects of medication on healthy participants by ERG [Reference Filip and Balik61Reference Fornaro, Perossini, Placidi, Dell’Osso, Tassi and Castrogiovanni65]. Two articles found that perphenazine decreased b-wave amplitudes, while bromocriptine increased them [Reference Fornaro, Bandini and Cestari62, Reference Perossini and Fornaro63]. Several dopamine antagonists such as haloperidol, chlorpromazine, fluphenazine, and metoclopramide, reduced b-wave amplitudes, although these decreases were not quantified [Reference Perossini and Fornaro63, Reference Holopigian, Clewner, Seiple and Kupersmith64]. Details of studies in this group are discussed in Table 9.

Table 9 Articles on medication use.

Notes: fERG = flash electroretinogram; NDRI = norepinephrine-dopamine reuptake inhibitor; TCA = tricyclic antidepressant.

4. Discussion

The present review aimed to evaluate the utility of ERG as a diagnostic tool within a psychiatric setting in a systematic manner. Because of the lack of consistency amongst protocols, small sample sizes, and lack of replicable findings, there remains much work that needs to be done before ERG may be used reliably in psychiatry. The major findings of our review are summarized in Table 10.

Table 10 Summary of ERG findings across psychiatric illnesses and groups.

Notes: ADHD = attention deficit hyperactivity disorder; ERG = electroretinogram; MDD = major depressive disorder; PERG = pattern electroretinogram; SAD = seasonal affective disorder.

In performing our review, we found it exceedingly difficult to make comparisons across studies and draw conclusions for specific disease groups. There was little consistency between protocols in included articles, and studies within disease groups often examined distinct forms of therapy and were conducted over drastically different timelines, leading to variable results. Moreover, many studies did not quantify their results, making it challenging to draw comparisons and eliminating any possibility of aggregating results meaningfully through a meta-analysis. While qualitative observations of waveform reductions and increases are insightful at an exploratory level, they do not provide an objective assessment of diagnostic utility.

In order for ERG to become a diagnostic modality in psychiatry, there is a need for quantifiable data that allows for determination of important measures such as sensitivity, specificity, and positive and negative predictive values in comparison to gold standard diagnostic methods. To facilitate this, we suggest that future studies implement the International Society for Clinical Electrophysiology of Vision (ISCEV) guidelines for the measurement of ERG waveforms and should quantify anomalies and calculate the magnitude of correlations with disease states. Prior studies were largely underpowered due to a small sample size. This may have been a result of requiring trained technicians and nurses to carry out pharmacological pupil dilation prior to ERG. Newer ERG technology permits gathering of data without the need for pupil dilation. Thus, authors should ensure that their studies have sufficient sample sizes and are adequately powered to assess outcomes of interest. To enrich results and minimize bias, future studies should be multi-center. At present, most of the research on a particular condition is conducted by the same authors. For instance, of 12 articles on depressive disorders, seven were from the same research group, and out of 15 articles on substance use, nine were from the same group of authors. Having multiple centers participate in studies would serve to both internally and externally validate study protocol and improve the reliability of findings.

Future studies should also consider expanding the use of ERG to yet unexplored psychiatric conditions. For example, our search did not identify any eligible studies examining bipolar disorder, indicating a gap in the present evidence.

An inherent difficulty of using ERG as a diagnostic tool in psychiatry is the limited number of detectable anomalies, restricting diagnostic specificity. For example, a reduction in b-wave amplitude on fERG may be indicative of cocaine withdrawal, autism spectrum disorder, panic disorder, perphenazine use, or intake of dopamine blockers. From a neurobiological perspective, this is perhaps due to the high degree of interconnectedness between many neurotransmitter systems [Reference Morgane, Galler and Mokler66]. Emerging research in animal suggests that ERG responses can also be affected by dopamine, accounting for observed anomalies in relevant psychiatric illnesses and medication use [Reference Lavoie, Illiano, Sotnikova, Gainetdinov, Beaulieu and Hébert2]. To be used reliably as a diagnostic tool, ERG will have to demonstrate more particular anomalies for each condition. If this proves to be unfeasible, however, then the diagnostic utility of ERG may be limited and its use in psychiatry may be better suited to measuring the effect of treatments or predicting relapse in patients.

5. Limitations

Our review is not without its limitations. We do not present quantitative analyses or a meta-analysis summarizing the results of ERG anomalies in specific psychiatric conditions as included studies did not provide such data.

Moreover, our review is at risk for publication bias as many of the studies included were conducted by a limited number of research groups and were largely single-center in design. Our review is also limited by its broad research question. There is a paucity of literature when examining the applicability of ERG to specific psychiatric illnesses, and thus we chose to look at a myriad of pathologies in order to provide the most comprehensive summary of the current evidence.

As the pace of research in this field accelerates, we anticipate future reviews will have well-refined and focused research questions and will allow for quantitative analyses.

6. Conclusions

This review systematically examined the literature on the use of ERG as a diagnostic tool in psychiatry. Although it was difficult to draw quantitative conclusions, consistent trends in ERG waveform anomalies in specific psychiatric conditions were observed across included studies. ERG is a non-invasive, quickly administered, and well-characterized test that has the potential to become an objective tool for the diagnosis of psychiatric illness. Further investigation through adequately powered multi-center studies, in concordance with the rapid pace of technological advancement, will allow for thorough evaluation of ERG in comparison to existing gold standard modalities and permit its successful integration into the diagnostic repertoire of modern psychiatry.

Funding

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

Footnotes

Abbreviations: ADHD, attention deficit hyperactivity disorder; CI, confidence interval; ERG, electroretinogram/electroretinography; fERG, flash electroretinogram/electroretinography; ISCEV, international society for clinical electrophysiology of vision; MDD, major depressive disorder; mfERG, multifocal electroretinography/electroretinogram; ms, millisecond; pERG, pattern electroretinogram/electroretinography; PRISMA, preferred reporting items for systematic reviews and meta-analyses

References

Lavoie, J., Maziade, M., Hébert, M., The brain through the retina: the flash electroretinogram as a tool to investigate psychiatric disorders. Prog Neuropsychopharmacol Biol Psych, 2014; 48: 129134.CrossRefGoogle ScholarPubMed
Lavoie, J., Illiano, P., Sotnikova, T.D., Gainetdinov, R.R., Beaulieu, J.M., Hébert, M., The electroretinogram as a biomarker of central dopamine and serotonin: potential relevance to psychiatric disorders. Biol Psychiatry, 2014; 75(6): 479486.CrossRefGoogle ScholarPubMed
Brown, K.T., The electroretinogram: its components and their origins. Vision Res, 1968; 8(6): 633677.CrossRefGoogle ScholarPubMed
McCulloch, D.L., Marmor, M.F., Brigell, M.G., ISCEV Standard for full-field clinical electroretinography, (2015 update) Doc Ophthalmol, 2015; 130 (1): 112.CrossRefGoogle ScholarPubMed
Schwitzer, T., Schwan, R., Angioi-Duprez, K., Giersch, A., Laprevote, V., The endocannabinoid system in the retina: from physiology to practical and therapeutic applications, Neural Plast, 2016 2016: 110.CrossRefGoogle ScholarPubMed
Ladien, K., Levett, J., Clarke, M., Effects of alcohol on electroretinogram light/dark adaptation. Drug Alcohol Depend, 1980; 6(1): 9395.CrossRefGoogle Scholar
Hildebrand, G.D., Fielder, A.R., Anatomy and physiology of the retina, Reynolds, J., Olitsky, S.E., Pediatric retina, New York: Springer-Verlag Berlin Heidelberg, 2011, 3965.CrossRefGoogle Scholar
Bach, M., Brigell, M.G., Hawlina, M., et al., ISCEV standard for clinical pattern electroretinography (PERG), 2012 update Doc Ophthalmol, 2013; 126 (1): 17.CrossRefGoogle Scholar
Hood, D.C., Bach, M., Brigell, M., et al., International society for clinical electrophysiology of vision. ISCEV standard for clinical multifocal electroretinography (mfERG) (2011 ed.). Doc Ophthalmol, 2012; 124(1): 13.CrossRefGoogle Scholar
McInnes, M.D.F., Moher, D., Thombs, B.D., et al., Preferred reporting items for a systematic review and meta-analysis of diagnostic test accuracy studies: the PRISMA-DTA statement. JAMA, 2018; 319(4): 388396.CrossRefGoogle ScholarPubMed
Pérez, J.G., Mato, M.P., García, A.S., Rey, A.D., Intraocular motility, electrophysiological tests and visual fields in drug addicts. Ophthalmic Physiol Opt, 1995; 15(5): 493498.CrossRefGoogle Scholar
Roy, M., Smelson, D.A., Roy, A., Abnormal electroretinogram in cocaine-dependent patients. Relationship to craving. Br J Psychiatry, 1996; 168(4): 507511.CrossRefGoogle ScholarPubMed
Roy, M., Roy, A., Williams, J., Weinberger, L., Smelson, D., Reduced blue cone electroretinogram in cocaine-withdrawn patients. Arch Gen Psychiatry, 1997; 54(2): 153156.CrossRefGoogle ScholarPubMed
Roy, M., Roy, A., Smelson, D., Brown, S., Weinberger, L., Reduced blue cone electroretinogram in withdrawn cocaine dependent patients: a replication. Biol Psychiatry, 1997; 42(7): 631633.CrossRefGoogle ScholarPubMed
Roy, M., Smelson, D., Roy, A., Longitudinal study of blue cone retinal function in cocaine-withdrawn patients. Biol Psychiatry, 1997; 41(2): 252253.CrossRefGoogle ScholarPubMed
Roy, A., Roy, M., Smelson, D.A., Risperidone, ERG, and cocaine craving. Am J Addict, 1998; 7(1): 90.CrossRefGoogle ScholarPubMed
Roy, A., Roy, M., Berman, J., Gonzalez, B., Blue cone electroretinogram amplitudes are related to dopamine function in cocaine-dependent patients. Psychiatry Res, 2003; 117(2): 191195.CrossRefGoogle ScholarPubMed
Smelson, D.A., Roy, A., Roy, M., The electroretinogram and neuropsychological functioning in cocaine addicts. Can J Psychiatry, 1996; 41(6): 415.CrossRefGoogle ScholarPubMed
Smelson, D.A., Roy, M., Roy, A., Santana, S., Electroretinogram in withdrawn cocaine-dependent subjects: relationship to cue-elicited craving. Br J Psychiatry, 1998; 172(6): 537539.CrossRefGoogle ScholarPubMed
Smelson, D.A., Roy, A., Roy, M., Tershakovec, D., Engelhart, C., Losonczy, M.F., Electroretinogram and cue-elicited craving in withdrawn cocaine dependent patients: a replication. Am J Drug Alcohol Abuse, 2001; 27(2): 391397.CrossRefGoogle ScholarPubMed
Schwitzer, T., Ingster-Moati, I., Angioi, K., Giersch, A., Schwan, R., Laprevote, V., Impaired retinal processing in regular cannabis users: potential benefit of electroretinogram as a biomark. Eur Psychiatry, 2014; 29(8): 529530.CrossRefGoogle Scholar
Schwitzer, T., Robert, M.P., Giersch, A., et al., Transient retinal dysfunctions after acute cannabis use. Eur Addict Res, 2016; 22(6): 287291.CrossRefGoogle ScholarPubMed
Schwitzer, T., Schwan, R., Albuisson, E., et al., Association between regular cannabis use and ganglion cell dysfunction. JAMA Ophthalmol, 2017; 135(1): 5460.CrossRefGoogle ScholarPubMed
Kim, J.T., Yun, C.M., Kim, S.W., Oh, J., Huh, K., The effects of alcohol on visual evoked potential and multifocal electroretinography. J Korean Med Sci, 2016; 31(5): 783789.CrossRefGoogle ScholarPubMed
Katz, B., Rimmer, S., Iragui, V., Katzman, R., Abnormal pattern electroretinogram in Alzheimer’s disease: evidence for retinal ganglion cell degeneration?. Ann Neurol, 1989; 26(2): 221225.CrossRefGoogle ScholarPubMed
Katz, B., Rimmer, S., Klauber, M.R., Katzman, R., The electroretinogram in Alzheimer’s disease (Reply). Ann Neurol, 1990; 28(5): 725.CrossRefGoogle Scholar
Pollock, V.E., Schneider, L.S., The electroretinogram in Alzheimer’s disease. Ann Neurol, 1990; 28(5): 724725.CrossRefGoogle ScholarPubMed
Strenn, K., Dal-Bianco, P., Weghaupt, H., Koch, G., Vass, C., Gottlob, I., Pattern electroretinogram and luminance electroretinogram in Alzheimer’s disease. J Neural Transm, 1991; 33 suppl: 7380.Google ScholarPubMed
Ritvo, E.R., Creel, D., Realmuto, G., Crandall, A.S., Freeman, B.J., Electroretinograms in autism: a pilot study of b-wave amplitudes. Am J Psychiatry, 1988; 145(2): 229232.Google ScholarPubMed
Realmuto, G., Purple, R., Knobloch, W., Ritvo, E., Electroretinograms (ERGs) in four autistic probands and six first-degree relatives. Can J Psychiatry, 1989; 34(5): 435439.CrossRefGoogle ScholarPubMed
van Elst, L.T., Bach, M., Blessing, J., Riedel, A., Bubl, E., Normal visual acuity and electrophysiological contrast gain in adults with high-functioning autism spectrum disorder. Front Hum Neurosci; 2015: 9 460.Google Scholar
Constable, P.A., Gaigg, S.B., Bowler, D.M., Jägle, H., Thompson, D.A., Full-field electroretinogram in autism spectrum disorder. Doc Ophthalmol, 2016; 132(2): 8399.CrossRefGoogle ScholarPubMed
Lam, R.W., Beattie, C.W., Buchanan, A., Mador, J.A., Electroretinography in seasonal affective disorder. Psychiatr Res, 1992; 43(1): 5563.CrossRefGoogle ScholarPubMed
Hébert, M., Dumont, M., Lachapelle, P., Electrophysiological evidence suggesting a seasonal modulation of retinal sensitivity in subsyndromal winter depression. J Affect Disord, 2002; 68(2): 191202.CrossRefGoogle ScholarPubMed
Danilenko, K.V., Plisov, I.L., Hebert, M., Kräuchi, K., Wirz-Justice, A., Influence of timed nutrient diet on depression and light sensitivity in seasonal affective disorder. Chronobiol Int, 2008; 25(1): 5164.CrossRefGoogle ScholarPubMed
Lavoie, M.P., Lam, R.W., Bouchard, G., et al., Evidence of a biological effect of light therapy on the retina of patients with seasonal affective disorder. Biol Psychiatry, 2009; 66(3): 253258.CrossRefGoogle ScholarPubMed
Bubl, E., Kern, E., Ebert, D., Bach, M., van Elst, L.T., Seeing gray when feeling blue? Depression can be measured in the eye of the diseased. Biol Psychiatry, 2010; 68(2): 205208.CrossRefGoogle ScholarPubMed
Bubl, E., Ebert, D., Kern, E., van Elst, L.T., Bach, M., Effect of antidepressive therapy on retinal contrast processing in depressive disorder. Br J Psychiatry, 2012; 201(2): 151158.CrossRefGoogle ScholarPubMed
Fornaro, M., Bandini, F., Ogliastro, C., et al., Electroretinographic assessment in major depressed patients receiving duloxetine: Might differences between responders and non-responders indicate a differential biological background?. J Affect Disord, 2011; 135(1): 154159.CrossRefGoogle ScholarPubMed
Gagné, A.M., Hébert, M., Atypical pattern of rod electroretinogram modulation by recent light history: a possible biomarker of seasonal affective disorder. Psychiatr Res, 2011; 187(3): 370374.CrossRefGoogle ScholarPubMed
Vandewalle, G., Hébert, M., Beaulieu, C., et al., Abnormal hypothalamic response to light in seasonal affective disorder. Biol Psychiatry, 2011; 70(10): 954961.CrossRefGoogle ScholarPubMed
Fam, J., Rush, A.J., Haaland, B., Barbier, S., Luu, C., Visual contrast sensitivity in major depressive disorder. J Psychosom Res, 2013; 75(1): 8386.CrossRefGoogle ScholarPubMed
Hébert, M., Mérette, C., Paccalet, T., Gagné, A.M., Maziade, M., Electroretinographic anomalies in medicated and drug free patients with major depression: tagging the developmental roots of major psychiatric disorders. Prog Neuropsychopharmacol Biol Psych, 2017; 75: 1015.CrossRefGoogle ScholarPubMed
Hébert, M., Beattie, C.W., Tam, E.M., Yatham, L.N., Lam, R.W., Electroretinography in patients with winter seasonal affective disorder. Psychiatr Res, 2004; 127(1): 2734.CrossRefGoogle ScholarPubMed
Gagrat, D., Maggiano, J., Belmaker, R.H., Effect of neuroleptic treatment in schizophrenia on the electroretinogram, electrooculogram, and color vision. Psychiatr Res, 1979; 1(1): 109.CrossRefGoogle ScholarPubMed
Gerbaldo, H., Thaker, G., Tittel, P.G., Layne-Gedge, J., Moran, M., Demisch, L., Abnormal electroretinography in schizophrenic patients with a history of sun gazing. Neuropsychobiol, 1992; 25(2): 99101.CrossRefGoogle ScholarPubMed
Warner, R., Laugharne, J., Peet, M., Brown, L., Rogers, N., Retinal function as a marker for cell membrane omega–3 fatty acid depletion in schizophrenia: a pilot study. Biol Psychiatry, 1999; 45(9): 11381142.CrossRefGoogle ScholarPubMed
Balogh, Z., Benedek, G., Kéri, S., Retinal dysfunctions in schizophrenia. Prog Neuropsychopharmacol Biol Psych, 2008; 32(1): 297300.CrossRefGoogle Scholar
Hébert, M., Gagné, A.M., Paradis, M.E., et al., Retinal response to light in young nonaffected offspring at high genetic risk of neuropsychiatric brain disorders. Biol Psychiatry, 2010; 67(3): 270274.CrossRefGoogle ScholarPubMed
Hébert, M., Mérette, C., Paccalet, T., et al., Light evoked potentials measured by electroretinogram may tap into the neurodevelopmental roots of schizophrenia. Schizophrenia Res, 2015; 162(1): 294295.CrossRefGoogle ScholarPubMed
Gagné, A.M., Paccalet, T., Jomphe, V., Lussier, D., Maziade, M., Electroertinographic response in youths at genetic risk of Schizophrenia and Bipolar Disorder and in normal controls: transversal and longitudinal differences and implication for the risk trajectory. Schizophr Bull, 2018; 44suppl. 1: 124.CrossRefGoogle Scholar
Maziade, M., Paccalet, T., Gagné, A.M., et al., Electroretinographic anomalies seen in patients affected by Schizophrenia or Bipolar Disorder are detectable early in children born to an affected parent: implications for the staging of risk status in childhood-adolescence. Schizophr Bull, 44suppl. 12018 11.CrossRefGoogle Scholar
Silverstein, S., Demmin, D., Erickson, M., Thompson, J., Paterno, D., Netser R.v7.1 Electroretinographic anomalies in Schizophrenia and their relationships with retinal structure, visual functions, clinical symptoms, and medical comorbidities. Schizophr Bull, 2018; 44 suppl. 1: 1011.CrossRefGoogle Scholar
Laprevote, V., Bernardin, F., Schwitzer, T., Schwan, R., Electroretinogram anomalies in Schizophrenia patients with visual hallucinations. Schizophr Bull, 2018; 44 suppl. 1: 169.CrossRefGoogle Scholar
Demmin, D.L., Davis, Q., Roché, M., Silverstein, S.M., Electroretinographic anomalies in schizophrenia. J Abnorm Psychol, 2018; 127(4): 417.CrossRefGoogle Scholar
Pieraccini, E., Bossini, L., Martinucci, M., et al., Assessment of photosensitivity through electroretinogram in patients with panic disorder (PD) and relationship with dopaminergic function. Eur Neuropsychopharmacol, 15suppl. 32005 5434.Google Scholar
Bossini, L., Padula, L., Valdagno, M., Castrogiovanni, P., Electroretinogram B wave amplitude, dopaminergic system and panic disorder. Eur Neuropsychopharmacol, 2008; 18 suppl. 4: 501.CrossRefGoogle Scholar
Nasser, J.A., Parigi, A.D., Merhige, K., Wolper, C., Geliebter, A., Hashim, S.A., Electroretinographic detection of human brain dopamine response to oral food stimulation. Obesity, 2013; 21(5): 976980.CrossRefGoogle ScholarPubMed
Moschos, M.M., Moustafa, G.A., Gonidakis, F., Papageorgiou, C., Retinal and choroidal alterations in patients with anorexia nervosa without vision loss. Int J Eat Disord, 2016; 49(4): 386390.CrossRefGoogle ScholarPubMed
Bubl, E., Werner, L., Liang, Y., et al., Evaluating the neurobiological correlates and impact of treatment on cognitive dysfunction in ADHD and Schizophrenia by means of the pattern electroretinogram. Schizophr Bull, 44suppl. 12018 11.CrossRefGoogle Scholar
Filip, V., Balik, J., Possible indication of dopaminergic blockade in man by electroretinography. Int Pharmacopsychiatry, 1978; 13: 151156.CrossRefGoogle Scholar
Fornaro, M., Bandini, F., Cestari, L., et al., Electroretinographic modifications induced by agomelatine: a novel avenue to the understanding of the claimed antidepressant effect of the drug?. Neuropsychiatr Dis Treat, 10 2014 907.CrossRefGoogle ScholarPubMed
Perossini, M., Fornaro, P., Electroretinographic effects induced in humans by psychopharmacologic agents. Doc Ophthalmol, 1990; 75(1): 16.CrossRefGoogle ScholarPubMed
Holopigian, K., Clewner, L., Seiple, W., Kupersmith, M.J., The effects of dopamine blockade on the human flash electroretinogram. Doc Ophthalmol, 1994; 86(1): 110.CrossRefGoogle ScholarPubMed
Fornaro, P., Perossini, M., Placidi, G.F., Dell’Osso, L., Tassi, G., Castrogiovanni, P., Electroretinography (ERG) as a tool of investigation on dopaminergic activity in man. Res Comm Psychol Psychiatr Behav, 1984; 9(3): 307323.Google Scholar
Morgane, P.J., Galler, J.R., Mokler, D.J., A review of systems and networks of the limbic forebrain/limbic midbrain. Prog Neurobiol, 2005; 75(2): 143160.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. fERG, PERG, and mfERG waveforms and parameters. Waveforms based on information provided in included studies.

Figure 1

Fig. 2. PRISMA flow diagram. The selection process for identifying eligible studies is shown.

Figure 2

Fig. 3. Number of articles by specific psychiatric illness and topic.

Figure 3

Fig. 4. Timeline of the literature on applications of ERG in psychiatry stratified by specific illness and topic.

Figure 4

Table 1 Articles on substance use.

Figure 5

Table 2 Articles on Alzheimer’s disease.

Figure 6

Table 3 Articles on autism spectrum disorder.

Figure 7

Table 4 Articles on depressive disorders.

Figure 8

Table 5 Articles on schizophrenia.

Figure 9

Table 6 Articles on panic disorder.

Figure 10

Table 7 Articles on eating disorders.

Figure 11

Table 8 Articles on ADHD.

Figure 12

Table 9 Articles on medication use.

Figure 13

Table 10 Summary of ERG findings across psychiatric illnesses and groups.

Submit a response

Comments

No Comments have been published for this article.