key: cord-0991907-ucdzyrf6 authors: Muro-Fuentes, Elena A.; Stunkel, Leanne title: Diagnostic Error in Neuro-ophthalmology: Avenues to Improve date: 2022-03-23 journal: Curr Neurol Neurosci Rep DOI: 10.1007/s11910-022-01189-4 sha: 5baef47c983d5751d6cb06f504fed0ccf3c50d7c doc_id: 991907 cord_uid: ucdzyrf6 PURPOSE OF REVIEW: To highlight potential avenues to reduce preventable diagnostic error of neuro-ophthalmic conditions and avoid patient harm. RECENT FINDINGS: Recent prospective studies and studies of patient harm have advanced our understanding. Additionally, recent studies of fundus photography, telemedicine, and artificial intelligence highlight potential avenues for diagnostic improvement. SUMMARY: Diagnostic error of neuro-ophthalmic conditions can often be traced to failure to gather an adequate history, perform a complete physical exam, obtain adequate/appropriate neuroimaging, and generate a complete, appropriate differential diagnosis. Improving triage and identification of neuro-ophthalmic conditions by other providers and increasing access to subspecialty neuro-ophthalmology evaluation are essential avenues to reduce diagnostic error. Further research should evaluate the relationship between misdiagnosis and patient harm, and help identify the most impactful potential targets for improvement. Medical error is estimated to be the third most common cause of death in the USA [1] , with about one in twenty experiencing preventable harm as a result [2] . Medical error has a significant economic impact, costing the USA about $19.5 billion in 2008 [3] . Diagnostic errors are the most common, expensive, and dangerous medical errors among malpractice claims [4] . An estimated 12 million Americans experience diagnostic error each year [5] . However, a recent survey of safety professionals in the US healthcare system showed that while a majority agree that diagnostic error is common and preventable, a minority had taken action to combat the issue, reflecting the need for further investigations into potential areas of improvement [6] . As demonstrated by the prevalence of misdiagnosis of stroke [7] and multiple sclerosis [8] , neurology remains susceptible to diagnostic error, arguably due to the complex and varied clinical presentations of neurologic disorders [9, 10] . Neuro-ophthalmic conditions in particular have been shown to have high rates of misdiagnosis [11] [12] [13] [14] [15] [16] [17] [18] 19 ••] that can result in preventable harm to patients [19••] . The typically complicated diagnoses and detailed clinical examination required to correctly diagnose neuro-ophthalmic conditions make them susceptible to misdiagnosis [20] , but may also may shed light on opportunities for intervention. 16-18, 24•, 26] and/or a single institution [13, 14, 16-18, 21, 23•] . Prior studies including multiple neuro-ophthalmic conditions found misdiagnosis rates up to 69% prior to neuro-ophthalmology consultation [14, 23•] . Similarly high rates of misdiagnosis have been seen in prior studies focusing on a single neuro-ophthalmic condition-up to 60% for optic neuritis [13] and 71% for optic nerve sheath meningiomas [18] . Several studies attempted to identify the cause of these diagnostic errors, and common themes were inadequate history [13, 16, 17, 22] , inaccurate performance of the physical examination or inaccurate interpretation of the examination findings [13, 17, 24•] , failure to obtain appropriate imaging to answer the clinical question [14, 22, 25] , incorrect interpretation of imaging findings [13, 14, 16, 17, 21, 22, 23•, 25] , and generation of a flawed or incomplete differential diagnosis [13, 22] . Notably, there was a dearth of prospective studies and research into whether these diagnostic errors lead to harm to patients. Similarly, all of these studies have focused on diagnostic label failure-the assignment of an incorrect diagnostic label [27] -and there has been little research into other errors involving the overall diagnostic processdiagnostic process errors [27] -such as failure to obtain a timely work-up to rule out possible critical diagnoses with appropriate urgency. More recently, additional studies have examined patient harm from diagnostic error and errors in the diagnostic approach (Table 2) . Recently, a multisite, prospective study examining all consecutive new patients referred to neuroophthalmology [19••] found that the referral diagnosis was incorrect in almost half (49%) of the 496 examined cases. Although the majority of patients (88%) had been referred appropriately, those with an inappropriate referral to neuroophthalmology were more likely to have been misdiagnosed prior to referral (76% vs 45% respectively). Neuro-ophthalmic consultation was impactful-in 2% of cases, neuroophthalmology consultation directly saved the patient's life or vision. Surprisingly, even in cases that were referred inappropriately, neuro-ophthalmology had an impact on patient care through both avoiding unnecessary tests (61%) and avoiding harmful treatment or providing an appropriate urgent referral (17%). Causes of diagnostic error were primarily due to inaccuracies in history taking, physical exam, differential diagnosis, and interpretation of testing. Those who were misdiagnosed were more likely to have received inappropriate management prior to referral (34% vs 13%). due to the misdiagnosis or delayed diagnosis, with harms including adverse effects of unnecessary medications, progression of permanent vision loss, and death (due to delay in diagnosis of a diffuse leptomeningeal glioneuronal tumor). In most of these patients (97%), the harm would potentially have been prevented by earlier access to neuro-ophthalmology. Although this study required somewhat subjective assessments, including what constitutes harm and the preventability of harm, it established a significant relationship linking misdiagnosis and harm to patients. Chung et al. [28• ] evaluated whether patients referred for suspicion of or with a final diagnosis of third nerve palsy underwent urgent imaging (defined as within 24 h of initial encounter) to rule out an intracranial aneurysm as the cause. This study primarily focused on a diagnostic process error [27] -the failure to obtain imaging in a timely manner-rather than a failure to assign the correct diagnostic label-in this case third nerve palsy. The majority of patients (64%) had not received arterial imaging within 24 h. Although a third nerve palsy was correctly suspected by the referring provider in 82% of cases, less than half (39%) of those patients received urgent imaging. Similarly, 25% of providers failed to document at least one cardinal physical examination component necessary for diagnosing a third nerve palsy, which may have contributed to misdiagnosis, as a prior study of the misdiagnosis of third nerve palsies found that misinterpretation of the physical examination was a common cause of diagnostic error in this condition [24 • ]. There was a median delay of 24 days between symptom onset and arterial imaging. Although rare, this can leave a patient susceptible to a potentially fatal aneurysmal rupture. This study also specifically evaluated patient harm, and found a case of delayed diagnosis of a metastasis in the cavernous sinus [28•] . This study showed that whether or not the correct diagnostic label is assigned, the correct diagnostic process may not be followed, leaving patients vulnerable to potential harm. Chan et al. [29••] and Mileski et al. [30] also focused on a diagnostic process error [27] -failure of patients with central retinal artery occlusion (CRAO) or branch retinal artery occlusion (BRAO) to receive an urgent stroke workup. Chan et al. retrospectively reviewed 181 patients diagnosed with an acute CRAO who had presented to either the emergency department (ED) or outpatient ophthalmology clinic at a single institution. Only 12% presented within 4.5 h of vision loss; 23% presented between 4.5 and 24 h of vision loss, and 62% presented over 24 h after vision loss. Fewer patients presenting after 24 h received an appropriate stroke workup or were admitted. Only three patients received thrombolysis. Notably, of the patients who presented within 4.5 h, nine were affected by misdiagnosis or a delayed diagnosis in the ED. As thrombolysis has the potential to improve visual outcome [31] , these diagnostic errors may have led to patient harm. The authors advocate educational campaigns, implementing institutional protocols, and making use of stroke and fundus photography to speed accurate diagnosis of CRAO and improve access to treatment within the critical window. Mileski et al. [30] surveyed 1916 optometrists and found that more than half of outpatient optometrists fail to send patients with CRAO/BRAO to the ED, and instead refer to outpatient ophthalmology, despite 77% being located within 30 min of an ED with an associated stroke center. In a related survey from 2009, only 35% of ophthalmologists referred patients with acute CRAO to the ED, compared to 86% of neuro-ophthalmologists and 73% of neurologists [32] . Improved education of both the general public and health care professionals is needed to help patients with acute CRAO/BRAO present earlier to the ED and receive an appropriate stroke workup. Altshuler et al. [33] examined errors in distinguishing pituitary adenomas versus nonadenomatous lesions on magnetic resonance imaging (MRI) as interpreted by two neurosurgeons and two neuroradiologists. Sixty-one percent (11/18) of nonadenomatous cases and 38% (8/18) of adenoma cases were incorrectly diagnosed by at least one reader. Of misdiagnosed cases, 5 of the 11 misdiagnoses of nonadenomatous and 7 of the 8 misdiagnoses of adenoma cases were due to avoidable errors, further emphasizing interpretation of imaging as a potential cause of misdiagnosis, consistent with prior studies of diagnostic error in neuroophthalmology [13, 14, 16, 17, 21, 22, 24•] , and suggesting that these errors could potentially be improved. Yuan et al. performed a retrospective review [34] of pediatric patients with suspected idiopathic intracranial hypertension (IIH). Out of 54 patients, 22% (12/54) were misdiagnosed. Alternative diagnoses were inflammatory/ infectious etiologies, malignancy, craniosynostosis, benign tumor, hydrocephalus, and retinitis pigmentosa. Missing these potential serious alternative diagnoses has the potential to lead to patient harm, although patient harm was not specifically evaluated by this study. In the majority of misdiagnosed cases (8/12), the errors were related to laboratory or radiology testing. A retrospective cohort study [35] found a misdiagnosis rate of 17% for 29 patients who had refused lumbar puncture and been diagnosed with IIH. This study emphasized the importance of a proper clinical examination, as pseudopapilledema was the correct diagnosis in all misdiagnosed cases. The study also called attention to the importance of taking an accurate history, as transient visual obscurations and tinnitus correlated with a true IIH diagnosis, and also emphasized the importance of the correct interpretation of imaging, as 3 out of 4 cardinal radiographic features of IIH on MRI [36] correlated with an accurate IIH diagnosis (Table 1) . A combined case series of two patients and literature review of 25 patients who were initially misdiagnosed with Bells palsy [37] found that alternative etiologies of facial nerve paralysis, including multiple cranial neuropathies, may be missed. Factors associated with misdiagnosis included misinterpretation of history, failure to perform or misinterpretation of examination findings, and the underlying diagnosis being a rare disease or unusual presentation. The authors emphasize that inaccurate use of the nomenclature of "Bells palsy"-without confirming that the facial nerve palsy is in fact isolated-could potentially contribute to misdiagnosis, as it implies to downstream providers that a comprehensive work up has been performed to rule out other causes. Although not designed as a study of misdiagnosis, Zheng et al. [38] described sources of delayed diagnosis in a series of 23 patients who presented with ocular symptoms (such as vision loss, proptosis, and diplopia) and were found to have extra-ocular tumors. Six patients were initially misdiagnosed-three patients with intracranial tumors were initially misdiagnosed as having primary optic atrophy, two patients with choroidal metastases were initially misdiagnosed as having central serous chorioretinopathy and exudative retinal detachment, and one with nasopharyngeal carcinoma was initially misdiagnosed as having optic neuritis. In all six cases, the initial misdiagnosis was noted to have been made by a less experienced, less specialized ophthalmologist, and subsequently corrected by a more experienced specialist. Although identifying the cause of misdiagnosis was not the focus of this study, potential sources of error were discussed, including choice of imaging modality, mild or atypical visual field patterns (only one patient had a typical symmetric homonymous hemianopia due to a suprachiasmatic aneurysm, with 3 patients having monocular hemianopia and 6 patients with incomplete hemianopia, irregular visual field defect or tunnel vision), and the provider lacking specialized knowledge in neuro-ophthalmology. Currently, the best avenue for reducing diagnostic error remains unclear [6, [39] [40] [41] (Table 3 ). Based on existing data about the causes of diagnostic error of neuro-ophthalmic conditions, potential methods to reduce misdiagnosis include improving providers' ability to gather a complete history and perform a complete and accurate physical examination to rule out serious diagnoses, in particular performing a thorough pupillary examination prior to dilation and improving ophthalmoscopy skills, providing radiologists with salient clinical information to emphasize specific areas to focus on, appropriate use of visual field testing and optical coherence tomography, expanding access to specialized providers such as neuro-ophthalmologists and neurologists, education campaigns targeted at general providers and at the public, and creating institutional protocols for how to approach specific complaints or conditions [11, 12, 29••, 30, 42] . A recent prospective study [43] highlighted the power of gathering a history. An attending neuro-ophthalmologist was able to identify the correct diagnosis in 88% of 115 consecutive patients presenting to an outpatient neuro-ophthalmology clinic based on history and chief complaint alone. (Each patient subsequently underwent an appropriate, full neuro-ophthalmology evaluation to determine the true final diagnosis.) Although this study may not be generalizable, as this was a highly experienced neuro-ophthalmology specialist, it demonstrates the pivotal role of history for correctly diagnosing neuro-ophthalmic conditions. Although experience improves a clinician's acumen, there is no established feedback system in place to inform providers of cases they have misdiagnosed, meaning that even over years of experience, learning directly from one's own misdiagnoses is rare [6, 44, 45] , and physicians may have poor insight into whether their diagnoses are accurate [46] . To provide a standardized setting in which providers can, in a sense, learn from experience to avoid diagnostic error, one group has begun to design case-based computer simulations using a library of real patient encounters with systematic, sensory-derived clinical exams, in this case AVERT (Acute Video-oculography for Vertigo in Emergency Rooms for Rapid Triage) [45] . Accurate detection of optic disc edema is essential to generate an accurate differential diagnosis and triage patients before referral to neuro-ophthalmology. As discussed above, inaccuracies in the physical examination, including inaccurate assessment for papilledema, has consistently been shown to be an important source of diagnostic error [17, 35] . Many providers, particularly neurologists, primary care providers, and ED providers, need accurate information about whether papilledema is present for optimal medical decision-making. Although ideally direct ophthalmoscopy would be performed in these settings, in practice it is often not attempted, not performed accurately, or the findings are not interpreted correctly [47] [48] [49] [50] [51] , and in these settings providers may not have access to tools such as dilating drops, indirect ophthalmoscopy, or slit lamp ophthalmoscopy, to improve accurate diagnosis of papilledema. Extensive prior research has demonstrated both the feasibility of incorporating nonmydriatic fundus photography into the ED evaluation, and that it improves detection of relevant findings [48, 49, [52] [53] [54] [55] , but until recently little was known about its feasibility in other care settings. Bursztyn et al. [56•] demonstrated that a handheld nonmydriatic camera does not require extensive training, can be operated by a provider without previous training or prior experience as an ophthalmic photographer (in the study, a medical assistant, optometrist, and resident), and can produce high quality photographs with high sensitivity for detecting optic disc edema when interpreted by fellowshiptrained neuro-ophthalmologists. The full clinical examination by a neuro-ophthalmologist was used as the standard for a diagnosis of true optic disc edema. The overall sensitivity of the photographs for detection of papilledema ranged from 71.8 to 92.2% among four graders. There were few photographs (0-8.3% per grader) that were considered ungradable, with some variation among graders, and none were thought to be ungradable by all graders. This is a promising avenue for expanding access to neuro-ophthalmology, as obtaining good-quality photographs did not require specialized training. However, in the study, the photographs were interpreted by fellowship-trained neuro-ophthalmologists, which may not be feasible in all practice settings. Irani et al. [57 •] evaluated the feasibility of incorporating nonmydriatic fundus photography into an outpatient neurology clinic. A neurologist who had received just 15 min of training with the camera obtained 505 nonmydriatic fundus photographs in 206 patients, and found that the vast majority (91%) were high quality, allowing for exclusion of subtle optic nerve and posterior pole abnormalities when graded by fellowship-trained neuro-ophthalmologists. Photographs were obtained quickly (requiring 2 min on average) with an overall high rating of ease, comfort, and speed by patients. The most common chief complaint was headache (74%), followed by known multiple sclerosis (14%), and idiopathic intracranial hypertension (IIH) (5%). Twenty-one percent of patients had an abnormal finding in at least one eye, 73% of which were neurologically relevant (optic disc pallor, edema, or drusen). The treating neurologist had the option to request photographs to incorporate into their clinical decision-making, but notably there were abnormalities found in ≥ 20% of cases whether or not providers had requested the photographs. When requested, 24% had abnormal findings, and when not requested, 20% had abnormal findings. When photographs were not requested, around half also did not have a direct ophthalmoscope examination documented, and when documented, only 22% of abnormal findings had been correctly identified. Twelve of the 13 treating neurologists agreed that optic disc assessment is essential to the neurological exam, with about half citing high confidence in their ability to detect relevant abnormalities via direct ophthalmoscopy. Notably, all preferred the non-mydriatic fundus photographs over direct ophthalmoscopy at the end of the study. Sharma et al. [58] prospectively examined the use of fundus photography in the neurological intensive care unit. In 79 patients with acute subarachnoid hemorrhage, fundus photographs were assessed for association between fundus abnormalities and poor outcome, length of neurological intensive care unit (ICU) stay, and hospital admission length. Twenty-nine had fundus abnormalities; 20 had intraocular hemorrhage. They found a significant association between intraocular hemorrhage and length of ICU stay, but not poor clinical outcome, and fundus photography in the intensive care unit was not found to outperform subarachnoid hemorrhage-specific clinical metrics already in use. A prospective study [59] evaluating the sensitivity and specificity of ocular ultrasound (OUS) called attention to the potential limitations of ocular ultrasound for differentiating papilledema from pseudopapilledema. Kohli Use of artificial intelligence is another potential avenue for combating diagnostic error [62] . Liu ] evaluated the ability of a DLS to specifically classify the severity of papilledema against three neuroophthalmologists, and found that the DLS had high rates of accuracy, sensitivity, and specificity (84%, 92%, and 74%, respectively), comparable with the neuro-ophthalmologists, and found a higher agreement score between the DLS and neuro-ophthalmologist than among the three neuro-ophthalmologists themselves. The advent of telemedicine also provides potential opportunities to improve access to neuro-ophthalmology [66] . Prior to the onset of the coronavirus disease 2019 (COVID- 19) pandemic, studies had demonstrated both the breadth of potential uses of telemedicine within the field of ophthalmology [67] and that telemedicine could be used to appropriately triage ophthalmic emergencies [68] . After the onset of the COVID-19 pandemic, the use of telemedicine in ophthalmology in general [69] , as well as neuro-ophthalmology specifically [70•, 71] , expanded due to sudden necessity. So far, available data suggest that it is safe and sustainable [69, 72••] . A prospective study [72••] examining the first 500 patients requesting emergency teleconsultation during the beginning of the COVID-19 lockdown in France demonstrated that teleconsultation can effectively manage ophthalmic emergencies. Eight of the 500 (1.6%) patients had a neuro-ophthalmic emergency, with less than a day of average delay from symptom onset to teleconsultation. All eight patients were referred to the nearest tertiary care center for physical consultation, and all but one was confirmed to have had the correct diagnosis identified via teleconsultation. Challenges of using telemedicine in neuro-ophthalmology have been noted to include technological challenges for both the patient and the provider, inability to perform IOP checks, inability to assess some of the more subtle aspects of the extra-ocular motility examination, and inability to perform funduscopic examinations [66, 69, 70•] . Overall, telemedicine has the potential to expand access to neuro-ophthalmic consultation even outside the specific circumstances of the COVID-19 pandemic [66] , which has the potential to improve diagnosis of neuro-ophthalmic conditions through more effective and accessible triage. Misdiagnosis is prevalent and leads to preventable patient harm, but so far there is limited data characterizing patient harm due to diagnostic error of neuro-ophthalmic conditions. Recent studies have documented patient harm in misdiagnosed patients [19••, 28•] , and showed that the harm may be largely preventable by earlier access to neuro-ophthalmology. To combat diagnostic error of neuro-ophthalmic conditions, improving access to trained subspecialists and neuroophthalmology consultation by incentivizing and producing more neuro-ophthalmologists would be ideal [73] . The growth of telehealth in the setting of the COVID-19 pandemic provides a nontraditional avenue for improving patient access to subspecialty trained neuro-ophthalmologists. Additionally, educational campaigns and institutional protocols to address common diagnostic process errors has the potential to improve care, and creating alternative avenues for outside specialties to obtain vital clinical data may improve diagnosis of neuro-ophthalmic conditions. Access to technology such as nonmydriatic fundus photography (fundus photographs that can be quickly and easily taken in the ED or an outpatient setting) and artificial intelligence augmented by deep learning are potential avenues to improve diagnosis of neuro-ophthalmic conditions in areas with limited access to neuro-ophthalmologists. Finally, development of standardized methods of improving physicians' diagnostic skills, such as case-based learning incorporated with real patient scenarios, has the potential to address diagnostic error throughout medicine. Of course, reducing misdiagnosis is not limited to the use of new technologies. Obtaining a proper history and clinical examination have consistently been shown to be a factor in accurate diagnosis. Further studies investigating harm due to misdiagnosis of additional neuro-ophthalmic conditions are needed, both to improve awareness and identify potential avenues of improvement. Additional studies will better establish the rate of patient harm due to misdiagnosis of neuro-ophthalmic conditions, and direct appropriate interventions and allocation of resources. Studies measuring the financial costs of diagnostic error of neuro-ophthalmic conditions may also demonstrate potential benefits of improving access to neuro-ophthalmology. The author/s do/es not have existing conflict of interest. This article does not contain any studies with human or animal subjects performed by any of the authors. Medical error-the third leading cause of death in the US Prevalence, severity, and nature of preventable patient harm across medical care settings: systematic review and meta-analysis The economics of health care quality and medical errors 25-Year summary of US malpractice claims for diagnostic errors 1986-2010: an analysis from the National Practitioner Data Bank The frequency of diagnostic errors in outpatient care: estimations from three large observational studies involving US adult populations Are health care provider organizations ready to tackle diagnostic error? A survey of Leapfrog-participating hospitals Diagnosis (Berl) Diagnostic Error in Stroke-Reasons and Proposed Solutions Misdiagnosis of multiple sclerosis: Impact of the 2017 McDonald criteria on clinical practice Emergency department consultations for patients with neurological emergencies Diagnostic accuracy of neurological problems in the emergency department Diagnostic Error of Neuro-ophthalmologic Conditions: State of the Science Diagnostic error and neuroophthalmology Incidence and Causes of Overdiagnosis of Optic Neuritis Neuroimaging in patients referred to a neuro-ophthalmology service: the rates of appropriateness and concordance in interpretation Referral Patterns in Neuro-Ophthalmology Underdiagnosis of posterior communicating artery aneurysm in noninvasive brain vascular studies Overdiagnosis of idiopathic intracranial hypertension Diagnostic Errors in Initial Misdiagnosis of Optic Nerve Sheath Meningiomas Prospective, multisite study that established a relationship between diagnostic error of neuro-ophthalmic conditions and patient harm. Almost half of patients were misdiagnosed prior to neuro-ophthalmology consultation, and 26% of misdiagnosed patients experienced harm Patient Safety: Its History and Relevance to Neuro-Ophthalmology Diagnostic management by gatekeepers is not cost effective for neuro-ophthalmology Common errors in the use of magnetic resonance imaging for neuro-ophthalmic diagnosis Characterized neuro-ophthalmology referrals and limitations of patient access to neuro-ophthalmology consultation. Almost half of patients referred to neuro-ophthalmology had been misdiagnosed Multisite study that found that misdiagnosis of third nerve palsies was primarily due to inaccurate performance or interpretation of the physical examination Papilloedema from Dural Venous Sinus Compression by Meningiomas Detection of Papilloedema Study (DOPS): rates of false positive papilloedema in the community A unified conceptual model for diagnostic errors: underdiagnosis, overdiagnosis, and misdiagnosis Retrospective study that focused on a diagnostic process error-failure to obtain urgent arterial imaging for patients with third nerves palsies-and assessed for resultant patient harm. Third nerve palsies were usually recognized by referrers Study of patients with acute CRAO that showed that presenting quickly enough after vision loss is a major barrier to receiving acute treatment and undergoing an adequate diagnostic process Survey of Optometric Practice Patterns for Patients With Acute Central Retinal Artery Occlusions. North American Neuro-Ophthalmology Society 47th Annual Meeting Intravenous Fibrinolysis for Central Retinal Artery Occlusion: A Cohort Study and Updated Patient-Level Meta-Analysis Translation of clinical studies to clinical practice: survey on the treatment of central retinal artery occlusion Imaging Errors in Distinguishing Pituitary Adenomas From Other Sellar Lesions Final Diagnoses and Diagnostic Error in Pediatric Patients with Presumed Papilledema (1770) Misdiagnosis Of Pseudotumor Cerebri In Patients With Typical Presentation Who Refused Diagnostic Lumbar Puncture (LP) Revised diagnostic criteria for the pseudotumor cerebri syndrome in adults and children Misdiagnosis of Bell's palsy: Case series and literature review Ocular symptoms as the initial clinical manifestations in patients with extraocular tumors Where Is the "Low-Hanging Fruit" in Diagnostic Quality and Safety? Qual Manag Health Care Improving Diagnosis in Health Care-The Next Imperative for Patient Safety Building a How to Minimize Diagnostic Errors. EyeNet Magazine Value of medical history in ophthalmology: A study of diagnostic accuracy Minimizing diagnostic error: the importance of follow-up and feedback The Diagnostic Performance Feedback "Calibration Gap": Why Clinical Experience Alone Is Not Enough to Prevent Serious Diagnostic Errors Physicians' diagnostic accuracy, confidence, and resource requests: a vignette study Ophthalmoscopy in the 21st century: The Feasibility of nonmydriatic ocular fundus photography in the emergency department: Phase I of the FOTO-ED study Nonmydriatic ocular fundus photography in the emergency department Nonmydriatic ocular fundus photography in neurologic emergencies The use of retinal photography in nonophthalmic settings and its potential for neurology Nonmydriatic ocular fundus photography among headache patients in an emergency department Diagnostic accuracy and use of nonmydriatic ocular fundus photography by emergency physicians: phase II of the FOTO-ED study Ocular fundus photography of patients with focal neurologic deficits in an emergency department Quality of nonmydriatic digital fundus photography obtained by nurse practitioners in the emergency department: the FOTO-ED study This study demonstrated that it is feasible to use a portable nonmydriatic fundus camera to obtain photographs of sufficient quality to identify papilledema with a high sensitivity and specificity Feasibility of a Nonmydriatic Ocular Fundus Camera in an This study demonstrated that it is feasible to obtain nonmydriatic fundus photographs in an outpatient neurology clinic, and that when interpreted by neuro-ophthalmologists, the photographs detected neurologically-relevant optic disc abnormalities missed by the treating neurologists Ocular Fundus Abnormalities in Acute Subarachnoid Hemorrhage: The FOTO-ICU Study Role of Ocular Ultrasonography to Distinguish Papilledema From Pseudopapilledema The role of orbital ultrasonography in distinguishing papilledema from pseudopapilledema The efficacy of optic nerve ultrasonography for differentiating papilloedema from pseudopapilloedema in eyes with swollen optic discs High-performance medicine: the convergence of human and artificial intelligence Demonstrated that a deep learning system has the ability to reliably detect eye laterality even in patients with abnormal optic discs Optic Disc Classification by Deep Learning versus Expert Neuro-Ophthalmologists Accuracy of a Deep Learning System for Classification of Papilledema Severity on Ocular Fundus Photographs Telemedicine for neuro-ophthalmology: challenges and opportunities The Current State of Teleophthalmology in the United States The United States Army Ocular Teleconsultation program Optimising telemedicine in ophthalmology during the COVID-19 pandemic Demonstrated that neuro-ophthalmology examinations can be performed via telemedicine, and that the examination can often provide enough information for medical decision-making The Impact of COVID-19 on Neuro-Ophthalmology Office Visits and Adoption of Telemedicine Services Teleconsultation in primary ophthalmic emergencies during the COVID-19 lockdown in Paris: Experience with 500 patients in March and How can we assure that neuro-ophthalmology will survive?