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TRAUMA-RELATED ACUTE MACULAR NEURORETINOPATHY. A CASE REPORT


Authors: H. Hasani;  S. Sheikhghomi;  M. Ojani
Authors place of work: Alborz University of Medical Sciences, Department of Ophthalmology, Madani Medical Center, School of Medicine, Karaj, Iran
Published in the journal: Čes. a slov. Oftal., 79, 2023, No. 2, p. 102-106
Category: Case Report
doi: https://doi.org/10.31348/2023/16

Summary

Aims: To introduce a case report and review the literature on trauma-related acute macular neuroretinopathy as an unusual etiology of acute macular neuroretinopathy.

Material and Methods: A 24-year-old man presented with unilateral paracentral scotoma following non-ocular trauma in a car accident. The relative afferent pupillary defect was negative and the best corrected visual acuities of both eyes were 10/10 (by the Snellen chart scale).

Results: Retinoscopy revealed a reduced foveal reflex, along with a small pre-retinal hemorrhage over the mid-pathway of the supranasal arteriole. OCT images showed an obvious ellipsoid zone (EZ) layer disruption in the macula of the left eye. The infrared fundus photograph of the same eye revealed a distinct hyporeflective area involving the macula. On fundus angiography, no macular vascular lesion was detected. The scotoma persisted after 3 months follow-up.

Conclusion: Non-ocular trauma including head or chest trauma without direct ocular injury accounts for most cases of trauma-related acute macular neuroretinopathy. It is important to distinguish this entity, given that there are also unremarkable findings in the retinal examination of these patients. Indeed, proper clinical suspicion leads to further suitable investigations and impedes other extraordinary images, which are the basic rules in the management of traumatic patients suffering multiple injuries and incurring medical expenses.

Keywords:

trauma – macula – Scotoma – injury

INTRODUCTION

Acute macular neuroretinopathy (AMN) is defined as the acute ischemia of deep retinal layers which is limited to the macular region. The major triggers identified for this rare condition include systemic hypotension, infections, intravenous contrast, thrombotic conditions, pre-eclampsia, caffeine consumption and the use of some drugs with sympathomimetic effects, such as ephedrine, epinephrine, etc. and those with hyper-coagulation effects, such as oral contraceptive pills (OCPs) [1-4].

The main clinical presentation of these patients is sudden onset paracentral scotomas which occur mostly unilaterally. Other symptoms including reduced central vision or metamorphopsia may coexist, depending on the foveal involvement. Eye examination including funduscopic examination usually reveals no visible lesions, except for some perifoveal teardrop-shaped preretinal or intraretinal hemorrhages which may be found in some patients. The macular changes can be detected as hyporeflective lesions in infrared or near infrared reflectance (IR or NIR, respectively) fundus photography, as well as spectral domain Optical Coherence Tomography (SD-OCT) in which outer retinal hyper-reflectivity or atrophy, depending on the duration after the onset of the disease, and ellipsoid zone disruptions are evident [3].

Despite good visual acuity in most patients, the prognosis of scotomas varies among patients and usually persists even after long-term follow-up, often with outer nuclear atrophies in their OCTs [1-4].

In this article, we present a rare case and a literature review of trauma-related AMN, an association which is seldom discussed in the literature, but needs to be reported as a reminder in encountering trauma patients who develop scotoma.

Case presentation

A 24-year-old male was transferred to our hospital following a car accident while driving. The patient was unconscious immediately after the accident, but became alert a few hours after admission. He remained in hospital due to his head, chest and limb injuries. Nevertheless, the injuries were minor and the patient was discharged without the need for surgical intervention. However, from the first day of admission, the patient complained of reduced vision in his left eye. In this regard, the patient was very agitated and claimed that he could see nothing with his left eye on the straight position and had to gaze slightly laterally to see faces well. On gross examination of his eyes, no pathologies in favor of ocular trauma were detected. The relative afferent pupillary defect was negative and the best corrected visual acuities of both eyes were 10/10 (by the Snellen chart scale).

On slit-lamp examination, the anterior segment of the left eye was normal. Retinoscopy revealed a reduced foveal reflex, along with a small pre-retinal hemorrhage over the mid-pathway of the supranasal arteriole. Other components of the posterior segments seemed intact. The examination of the right eye was totally normal.

After three weeks, no improvement in visual field impairment was reported by the patient. On OCT imaging, an obvious ellipsoid zone (EZ) layer disruption and outer retinal thinning was detected in the macula of the left eye. The IR photograph of the same eye revealed a distinct hyporeflective lesion in the same location (Figure 1). On fundus angiography, no abnormality was distinguished, apart from a localized blockage of fluorescein due to the pre-retinal hemorrhage over the supranasal arteriole (Figure 2). Autofluorescence imaging also showed unremarkable findings (Figure 3). By integrating the clinical manifestation and paraclinical findings of the patient, the diagnosis of traumatic acute macular neuroretinopathy was confirmed and the patient was observed. Unfortunately, after 3 months’ follow-up, no improvement occurred.

Figure 1. Right: Infrared Reflectance imaging’s (IR) shows a well-defined hyporeflectance macular lesion (surrounded by yellow arrows). Left: Spectral domain Optical Coherence Tomographies (SD-OCT) showing a central outer nuclear layer atrophy (red asterisks) and multiple ellipsoid and inner segment/outer segment junction disruptions (green arrows)
Figure 1. Right: Infrared Reflectance imaging’s (IR) shows a well-defined hyporeflectance
macular lesion (surrounded by yellow arrows). Left: Spectral domain Optical
Coherence Tomographies (SD-OCT) showing a central outer nuclear layer atrophy
(red asterisks) and multiple ellipsoid and inner segment/outer segment junction disruptions
(green arrows)

Figure 2. Top: Fluorescein Angiography (FA) of the right eye showing no vascular lesion. Bottom: Fluorescein Angiography (FA) of the left eye showing a localized blockage of fluorescein due to pre-retinal hemorrhage over the supranasal arteriole. No vascular abnormalities are seen in the macular region
Figure 2. Top: Fluorescein Angiography (FA) of the right eye showing no vascular lesion.
Bottom: Fluorescein Angiography (FA) of the left eye showing a localized blockage
of fluorescein due to pre-retinal hemorrhage over the supranasal arteriole. No vascular
abnormalities are seen in the macular region

Figure 3. Autofluorescence (AF) of both eyes have normal appearance
Figure 3. Autofluorescence (AF) of both eyes have normal appearance

DISCUSSION AND CONCLUSIONS

Trauma-related acute macular neuroretinopathy is an inadequately described disease in patients with impaired vision following trauma. To date, 18 cases of trauma-associated AMN have been reported in the literature. The demographic, clinical features and prognoses of these patients are all summarized in Table 1. As shown in this Table, acute macular neuroretinopathy usually occurs following non-ocular trauma in most patients. It is assumed that the raised intrathoracic pressure in non-ocular injuries may develop an ischemic retinal vasculopathy similar to Purtscher retinopathy or Valsalva retinopathy [5-8]. In addition, our patient developed a localized oval- shaped pre-retinal hemorrhage over the supranasal arteriole – a finding similar to Valsalva retinopathy – which could support this hypothesis. Therefore, it is not unexpected to see isolated or multiple retinal hemorrhages beyond the macular region in these patients.

Tab. 1. Summary of clinical and paraclinical features of all the reported patient with traumatic AMN in the literature
Summary of clinical and paraclinical features of all the reported patient with traumatic AMN in the literature

EZ – ellipsoid disruption, FA – fluorescein angiography, IR – infrared reflectance, OCT – optical coherence tomography
EZ – ellipsoid disruption, FA – fluorescein angiography, IR – infrared
reflectance, OCT – optical coherence tomography

Regarding the diagnostic modalities, both IR and OCT images are the most informative modalities for detecting macular changes in almost all patients, particularly if done in the acute phase of the disease. Over time, the involved outer retina atrophies and the dark lesions found in the infrared imaging may fade and become less distinct. Instead, reduced amplitudes revealed in the multifocal electroretinogram (mfERG) of the involved eyes may be more durable in the long term. Generally, other modalities including fluorescein angiography (FA) or autofluorescence (AF) do not identify the lesions [4-5, 9], although OCT angiography (OCTA) may show hypoperfusion of choriocapillaries, deep or superficial capillary plexus [6].

Non-ocular trauma, including head or chest trauma without direct ocular injury, accounts for nearly all cases of trauma-related acute macular neuroretinopathy [5-11]. Therefore it seems more reasonable that the term “traumatic maculopathy”, which includes a wide range of macular changes including macular hole, choroidal rupture, etc., be used for direct ocular injuries.

It is important to distinguish trauma-related AMN, given that there are also unremarkable findings in the retinal examination of these patients. Indeed, proper clinical suspicion leads to further suitable investigations and impedes other extraordinary images, which are the basic rules for the management of trauma patients suffering multiple injuries and incurring medical expenses. Moreover, the legal issues created by motor vehicle accidents may put the physician in a diagnostic dilemma, where it is not easy to differentiate from malingering due to the normal retinal examination.

The authors of the study declare that no conflict of interest exists in the compilation, theme and subsequent publication of this professional communication, and that it is not supported by any pharmaceutical company.  The study has not been submitted to another journal and is not printed elsewhere, with the exception of congress summaries and recommended procedures.

The authors declare that they have NO affiliations with or involvement in any organization or entity with any financial interest in the subject matter or materials discussed in this manuscript.

Received: December 7, 2022

Accepted: January 10, 2023

Available on-line: March 30, 2023

First author:

Hamidreza Hasani, MD

Corresponding author:

Sima Sheikhghomi, MD

Department of Ophthalmology,

Faculty of Medicine Alborz University of Medical Sciences Karaj

3149779453 Iran

E-mail: sshaikhghomi@yahoo.com


Zdroje

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