Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-10T06:20:36.383Z Has data issue: false hasContentIssue false

Advances in the diagnosis and management of acute vertigo

Published online by Cambridge University Press:  23 May 2024

David Herdman*
Affiliation:
Audiovestibular Department, St George's University Hospital NHS Foundation Trust, London, UK
*
Corresponding author: David Herdman; Email: david.herdman@stgeorges.nhs.uk
Rights & Permissions [Opens in a new window]

Abstract

Background

Patients presenting to the emergency department with acute vertigo pose a diagnostic challenge. While ‘benign’ peripheral vestibulopathy is the most common cause, the possibility of a posterior circulation stroke is paradoxically the most feared and missed diagnosis in the emergency department.

Objectives

This review will attempt to cover the significant advances in the ability to diagnose acute vertigo that have occurred in the last two decades. The review discusses the role of neurological examinations, imaging and specific oculomotor examinations. The review then discusses the relative attributes of the Head Impulse-Nystagmus-Test of Skew plus hearing (‘HINTS+’) examination, the timing, triggers and targeted bedside eye examinations (‘TiTrATE’), the associated symptoms, timing and triggers, examination signs and testing (‘ATTEST’) algorithm, and the spontaneous nystagmus, direction, head impulse testing and standing (‘STANDING’) algorithm. The most recent technological advancements in video-oculography guided care are discussed, as well as other potential advances for clinicians to look out for.

Type
Main Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of J.L.O. (1984) LIMITED

Introduction

Around 4 per cent of patients who visit the emergency department report dizziness as their primary complaint.Reference Newman-Toker, Cannon, Stofferahn, Rothman, Hsieh and Zee1 As a result, emergency physicians are frequently called upon to assess these patients in a setting where demands are high and resources are limited. Physicians are also expected to cast a wide net, given the possibility of a large variety of causes such as ontological or vestibular, cardiovascular, respiratory, psychiatric, and neurological disorders.Reference Newman-Toker, Hsieh, Camargo, Pelletier, Butchy and Edlow2

The acute vestibular syndrome refers to the presence of vertigo or dizziness, together with nausea or vomiting, imbalance and nystagmus, and accounts for 20 per cent of dizziness cases.Reference Ljunggren, Persson and Salzer3 The most likely cause is an acute unilateral vestibulopathy due to a sudden disturbance in the vestibular nerve or vestibular labyrinth on one side.Reference Strupp, Bisdorff, Furman, Hornibrook, Jahn and Maire4 However, this presentation can also be caused by brainstem or cerebellar strokes.

The other most frequent peripheral vestibular disease is benign paroxysmal positional vertigo (BPPV), characterised by vertigo that is episodic rather than continuous, induced by the migration of otoconia from the utricular macula into one or more semi-circular canal. This should be managed differently to the acute unilateral vestibulopathy, and the diagnosis is only confirmed by the presence of canal-specific nystagmus during diagnostic manoeuvres.Reference von Brevern, Bertholon, Brandt, Fife, Imai and Nuti5 Once again, however, central disorders such as posterior fossa mass lesions can ‘mimic’ BPPV, necessitating a careful examination.

The risk of life-threatening disorders motivates emergency physicians to utilise diagnostic resources, such as computed tomography (CT) and magnetic resonance imaging (MRI) of the brain, when available. This raises the question of whether physicians employ these methods out of defensiveness, or because they are truly effective and required for the assessment of patients with dizziness and vertigo.

In light of the development of many bedside examination methods, the diagnosis of acute vertigo has advanced dramatically during the past decade or two. Nonetheless, the majority of this knowledge has not yet been integrated into clinical practice. Therefore, this article presents a practical evaluation and summary of the available evidence for the clinical care of vertigo in the emergency department.

Role of neurological examination and risk factors

The ‘ABCD2’ is a stroke risk assessment tool based on five parameters (age, blood pressure, clinical features, duration and presence of diabetes) that was initially developed to stratify patients with anterior cerebral ischaemia.Reference Navi, Kamel, Shah, Grossman, Wong and Poisson6 Newman-Toker et al.Reference Newman-Toker, Kerber, Hsieh, Pula, Omron and Saber Tehrani7 examined 190 adults with acute vestibular syndrome, and found that relying on the ‘ABCD2’ score would have missed nearly 40 per cent of the stroke cases and over-diagnosed stroke in nearly 40 per cent of peripheral vestibular cases. As a result, relying on vascular risk factors is cited as a frequent error when triaging patients with vertigo and dizziness, contributing to misdiagnosis-related harms in young patients in particular.Reference Kerber and Newman-Toker8

Regardless of vascular risk factors, around 30–60 per cent of patients with posterior circulation strokes will exhibit at least one deficit on neurological examination.Reference Edlow and Newman-Toker9,Reference Edlow, Newman-Toker and Savitz10 In their meta-analysis, Shah et al.Reference Shah, Oliveira, Farah, Seisa, Balla and Christensen11 found that most neurological examination findings have low sensitivity and high specificity for a central cause, implying that the absence of typical neurological symptoms or signs should not be relied upon to exclude stroke in acute dizziness. Ten per cent of patients with a cerebellar infarct, usually in the medial branch of the posterior inferior cerebellar artery, will have isolated vertigo, without other localising findings on motor, sensory, reflex, cranial nerve or limb co-ordination examinations.Reference Lee, Sohn, Cho, Lee, Ahn and Park12

There is increasing evidence to support that truncal ataxia is an important part of the neurological examination.Reference Edlow and Newman-Toker9,Reference Lee, Sohn, Cho, Lee, Ahn and Park12,Reference Vanni, Pecci, Edlow, Nazerian, Santimone and Pepe13 Carmona et al.Reference Carmona, Martínez, Zalazar, Moro, Batuecas-Caletrio and Luis14 examined 114 patients with acute vestibular syndrome and found that patients who fell while standing upright likely had a central lesion as the cause of their acute vestibular syndrome, with a high degree of certainty (sensitivity of 67 per cent and specificity of 100 per cent). Although ataxia was less sensitive than the specific oculomotor examination, the authors argued that truncal ataxia is an easy sign that can be recognised even by physicians without specialised training. In another case series, Lee et al.Reference Lee, Sohn, Cho, Lee, Ahn and Park12 also found that 71 per cent of patients with cerebellar infarction and isolated vertigo will present with the inability to walk without support.

Another helpful vestibulospinal sign is the Babinski asynergy sign, which is the inability to sit up from a supine position without using the arms.Reference Philippon and Poirier15 Carmona et al.Reference Carmona, Martínez, Zalazar, Moro, Batuecas-Caletrio and Luis14 found that this sign had excellent sensitivity (93 per cent) and specificity (100 per cent), in the same study described previously. This seems particularly useful because it can also be administered to severely nauseous patients who are too symptomatic to walk, but the results may need replicating.

Role of imaging

Computed tomography scans are excellent at detecting intracerebral haemorrhage, but this rarely manifests as dizziness without other concerning physical signs.Reference Kerber, Burke, Brown, Meurer, Smith and Lisabeth16 The sensitivity of brain CT for posterior circulation acute ischaemic stroke ranges from 7 per cent to 42 per cent,Reference Chalela, Kidwell, Nentwich, Luby, Butman and Demchuk17Reference Ozono, Kitahara, Fukushima, Michiba, Imai and Tomiyama20 such that CT scans are typically not clinically useful and can be misleadingly reassuring.Reference Grewal, Austin, Kapral, Lu and Atzema21Reference Wasay, Dubey and Bakshi24

Magnetic resonance imaging, on the other hand, is the ‘gold standard’ for diagnosing acute ischaemic stroke. However, even an MRI with diffusion-weighted imaging sequences can miss up to 20 per cent of posterior fossa strokes in the first 48 hours,Reference Tao, Liu, Fisher, Wang, Li and Furie25,Reference Shah, Oliveira, Farah, Seisa, Kara Balla and Christensen26 which is specifically true in patients with dizziness.Reference Kattah, Talkad, Wang, Hsieh and Newman-Toker27Reference Park, Kim, Lee, Jung and Chae29 Patients may therefore require a further delayed diffusion-weighted imaging MRI or final clinical diagnosis as the gold standard.

Oculomotor examination

Specific oculomotor examinations have been found to distinguish ‘central’ and ‘peripheral’ disorders in the acute vestibular syndrome (acute-onset, prolonged dizziness or vertigo).

The Head Impulse Test is used to assess the vestibulo-ocular reflex. An abnormal vestibulo-ocular reflex is usually a sign of a peripheral vestibular disorder, while a normal vestibulo-ocular reflex with the head impulse is a strong sign of a central problem.

Spontaneous nystagmus is usually present in the acute vestibular syndrome. ‘Peripheral’ nystagmus is unidirectional and horizontal-torsional. It worsens when looking in the direction of the fast phase (according to Alexander's Law) and suppresses with fixation. However, these features can also be seen with vestibular nuclei, cerebellar or brainstem lesions.Reference Newman-Toker, Kerber, Hsieh, Pula, Omron and Saber Tehrani7,Reference Kattah, Talkad, Wang, Hsieh and Newman-Toker27,Reference Newman-Toker, Kattah, Alvernia and Wang30 On the other hand, spontaneous vertical or direction-changing nystagmus should be presumed to have a central aetiology.Reference Lee, Sohn, Cho, Lee, Ahn and Park12

The test of skew is used to look for skew deviation. Although skew deviation is not a sensitive marker of central pathology, it is specific for detecting brainstem lesions in patients with acute vestibular syndrome (15 per cent vs 98 per cent respectively).Reference Korda, Zamaro, Wagner, Morrison, Caversaccio and Sauter31,Reference Fracica, Hale and Gold32

These tests make up the component parts of the Head Impulse-Nystagmus-Test of Skew (‘HINTS’) examination, as discussed below. However, there are other classes of eye movements to consider, such as saccadic dysmetria, impaired smooth pursuit, impaired vestibulo-ocular reflex suppression, ocular lateropulsion, ocular tilt reaction, subjective visual vertical test, eye range of movement, central patterns of head-shaking and central positional nystagmus. These can all complement the Head Impulse-Nystagmus-Test of Skew examination and allow for specific topographical diagnosis of central posterior fossa lesions in acute vertigo (see Fracica et al.Reference Fracica, Hale and Gold32 for a full review).

Head Impulse-Nystagmus-Test of Skew plus hearing examination

In 2009, Kattah et al.Reference Kattah, Talkad, Wang, Hsieh and Newman-Toker27 published their seminal paper on the Head Impulse-Nystagmus-Test of Skew examination. Combining these tests addressed their individual shortcomings, as a ‘central’ finding on any of the tests leads to the assumption of central aetiology until proven otherwise. This is why it is a three-step test and not a one-step test. Another helpful acronym ‘INFARCT’ can be used to remember the dangerous signs: Impulse Normal, Fast-phase Alternating, and Refixation on Cover Test. In their analysis of consecutive patients with acute vestibular syndrome who had at least one stroke risk factor, a benign Head Impulse-Nystagmus-Test of Skew examination finding ‘ruled out’ stroke better than negative results on MRI with diffusion-weighted imaging in the first 24–48 hours after symptom onset, with excellent specificity (96 per cent).

Along with the Head Impulse-Nystagmus-Test of Skew examination, the evaluation of auditory function with finger rub was subsequently added in 2013, making up the Head Impulse-Nystagmus-Test of Skew plus hearing (‘HINTS+’) examination.Reference Newman-Toker, Kerber, Hsieh, Pula, Omron and Saber Tehrani7 This is because hearing loss, when present as part of the acute vestibular syndrome, can indicate labyrinthine ischaemia, which is usually caused by anterior inferior cerebellar artery territory strokes,Reference Lee, Sohn, Jung, Cho, Lim and Yi33 especially if otoscopy findings are normal.

Since its creation, the Head Impulse-Nystagmus-Test of Skew has been replicated, and has been reported as more sensitive than diffusion-weighted imaging MRI in several reports.Reference Kattah34 Although the Head Impulse-Nystagmus-Test of Skew is therefore useful in acute vestibular syndrome cases when the patient is still exhibiting nystagmus in the emergency department, it does not address other relevant clinical presentations. Importantly, the original paper and subsequent reports also rely on subspecialist examiners rather than general emergency physicians. In their systematic review, Ohle et al.Reference Ohle, Montpellier, Marchadier, Wharton, McIsaac and Anderson35 concluded that the HINTS examination may not be sufficiently accurate to rule out a stroke in those presenting with acute vestibular syndrome when used in isolation by emergency physicians.

Timing, triggers and targeted bedside eye examinations algorithm

Classifying patients based on dizziness ‘type’, such as vertigo versus ‘light-headedness’, is not only non-specific, but patients frequently change their description over time.Reference Newman-Toker, Cannon, Stofferahn, Rothman, Hsieh and Zee1 Instead, Newman-Toker and EdlowReference Newman-Toker and Edlow36 propose grouping patients based on the timing and triggers of dizziness. The timing, triggers and targeted bedside eye examinations (‘TiTrATE’) algorithm begins by helpfully triaging other general medical causes that are often apparent from the clinical context, co-symptoms and vital signs. The ‘timing’ is used to identify two acute syndromes (acute vestibular syndrome vs episodic), further subdivided into whether the symptoms are spontaneous or triggered, which is then used to select the appropriate targeted examination. For example, if a patient presents with an acute vestibular syndrome, which is spontaneous, the Head Impulse-Nystagmus-Test of Skew examination is performed. The result of the targeted examination then dictates the appropriate laboratory or imaging test required.

The advantage of the timing, triggers and targeted bedside eye examinations algorithm is that it helps to select the right patient for the right examination. It includes the Head Impulse-Nystagmus-Test of Skew examination for acute vestibular syndrome; however, it is much more extensive, as it is the only algorithm to consider presentations such as the acute vestibular syndrome following a traumatic or toxic exposure, or spontaneous episodic vestibular conditions such as Ménière's disease or migraine. It has been specifically designed to address the many common pitfalls observed in clinical practice.Reference Kerber and Newman-Toker8,Reference Edlow37 However, it has not yet been fully validated amongst emergency physicians.

Associated symptoms, timing and triggers, examination signs and testing algorithm

The associated symptoms, timing and triggers, examination signs and testing (‘ATTEST’) algorithm is the revised and renamed timing, triggers and targeted bedside eye examinations paradigm, adopting the timing and triggers diagnostic approach in a simpler flow diagram.Reference Edlow, Gurley and Newman-Toker38 It was created using the same evidence-based guidelines as the timing, triggers and targeted bedside eye examinations, although no clinical studies have been conducted.

Spontaneous nystagmus, direction, head impulse testing and standing protocol

Vanni et al.Reference Vanni, Pecci, Casati, Moroni, Risso and Ottaviani39 published their four-step algorithm called ‘STANDING’ (SponTAneous Nystagmus, Direction, head Impulse test, standiNG) in 2014, and found excellent levels of sensitivity (100 per cent) and specificity (94 per cent). In their full validation study in 2017, they found similarly high levels of accuracy (88 per cent), sensitivity (95 per cent) and specificity (87 per cent).Reference Vanni, Pecci, Edlow, Nazerian, Santimone and Pepe13

Similar to, but not as extensive as, the timing, triggers and targeted bedside eye examinations, the spontaneous nystagmus, direction, head impulse testing and standing protocol also includes guidelines on how to evaluate acutely dizzy patients who do not show spontaneous nystagmus, as it includes gait and positional testing. It does go further than the timing, triggers and targeted bedside eye examinations in terms of positional testing, however, as it suggests performing the Pagnini–McClure manoeuvre to assess for the horizontal canal variant before performing the Dix–Hallpike manoeuvre, which is used to identify the more commonly affected posterior canal. In their validation study, Vanni et al.Reference Vanni, Pecci, Edlow, Nazerian, Santimone and Pepe13 found a 20 per cent rate of the horizontal canal BPPV variant, a higher figure than seen in non-acute settings.

The spontaneous nystagmus, direction, head impulse testing and standing protocol also differs from the Head Impulse-Nystagmus-Test of Skew examination in its approach to the acute vestibular syndrome, as it does not include the test of skew. The reason for this is not clear, but it seems it was not thought to be necessary given that a normal Head Impulse Test finding was the best bedside predictor of stroke in the study by Kattah et al.Reference Kattah, Talkad, Wang, Hsieh and Newman-Toker27 Vanni et al.Reference Vanni, Pecci, Edlow, Nazerian, Santimone and Pepe13 also found that a negative Head Impulse Test finding, as well as altered equilibrium, were the most sensitive findings for central vertigo. The spontaneous nystagmus, direction, head impulse testing and standing protocol also omits hearing. Nevertheless, these omissions did not appear to result in unacceptable levels of sensitivity compared with final clinical diagnosis, although it should be noted that the emergency physicians performing the protocol had received extensive training. The use of emergency physicians in the validation is a particular strength of the spontaneous nystagmus, direction, head impulse testing and standing protocol, but it is not clear how the protocol will perform when implemented by less experienced examiners given that it places a relatively higher weighting on the Head Impulse Test, which probably requires the greatest level of skill and interpretation.

Table 1 provides a summary of the pros and cons of the diagnostic algorithms discussed above.

Table 1. Pros and cons of diagnostic algorithms for differential diagnosis of vertigo in the emergency department

HINTS+ = Head Impulse-Nystagmus-Test of Skew plus hearing examination; AVS = acute vestibular syndrome; TiTrATE = timing, triggers and targeted bedside eye examinations; ATTEST = associated symptoms, timing and triggers, examination signs and testing algorithm; BPPV = benign paroxysmal positional vertigo; STANDING = spontaneous nystagmus, direction, head impulse testing and standing protocol; HIT = Head Impulse Test

What does a ‘good protocol’ look like?

Comparing the Head Impulse-Nystagmus-Test of Skew examination to the timing, triggers and targeted bedside eye examinations, or the associated symptoms, timing and triggers, examination signs and testing algorithm, and the spontaneous nystagmus, direction, head impulse testing and standing algorithm, may be misleading because the Head Impulse-Nystagmus-Test of Skew examination is only concerned with acute vestibular syndrome, whereas the others include aetiologies such as BPPV. As a result, the Head Impulse-Nystagmus-Test of Skew examination should not be used in isolation for the differential diagnosis of vertigo in the emergency department.

Other protocols and pathways that have not yet been mentioned include minor modifications but adhere to similar principles, such as the one advocated by Johns and Rosenberg.Reference Johns and Rosenberg40 This algorithm, like the spontaneous nystagmus, direction, head impulse testing and standing algorithm, looks for the ability to stand or walk unaided in order to clearly identify strokes, and includes positional testing for BPPV, but incorporates the full Head Impulse-Nystagmus-Test of Skew examination in the case of the acute vestibular syndrome.

What these protocols do share is the principle that the most effective way to exclude a life-threatening disorder such as posterior cerebrovascular disease is to confirm the presence of a peripheral vestibular disorder. The spontaneous nystagmus, direction, head impulse testing and standing protocol, for example, had an excellent negative predictive value (99 per cent) but a poor positive predictive value (48 per cent), according to validation study by Vanni et al.Reference Vanni, Pecci, Edlow, Nazerian, Santimone and Pepe13 Therefore, clinical pathways should consider the tools required to recognise the most common peripheral vestibular disease resulting in acute vertigo.

Other vestibular disorders, such as vestibular migraine and Ménière's disease, may also present to the emergency department, and can be difficult to diagnose at first, even in the hands of subspecialists. As a result, emergency department physicians may need to use the bedside examination to rule out ‘clear cases’, rather than making a definitive diagnosis, to ensure patient safety. Although this would reduce specificity, it is preferable to low sensitivity.

Who should see these patients?

The success of any protocol depends on who carries it out. A common criticism of vertigo protocols is the lack of validation in non-specialist point of care emergency physicians.Reference Ohle, Montpellier, Marchadier, Wharton, McIsaac and Anderson35,Reference Nakatsuka and Molloy41 These tests are not uniquely difficult to perform, although they do require some level of subjective interpretation.

Some localised protocols utilise allied health professionals instead. For example, one study from Australia found that utilising a specialist vestibular physiotherapist led to greater diagnostic specificity.Reference Stewart, Rosbergen, Tsang, Hoffman, Kwan and Grimley42 However, there was no reference standard used to measure diagnostic accuracy, and the pathway led to higher rates of hospital admission and longer length of stay.

In the end, the ideal person to see the patient is the one who is available and the most qualified to do so, but it is unclear what training is necessary to achieve competency. Emergency physicians carried out the spontaneous nystagmus, direction, head impulse testing and standing protocol, following 5 hours of didactic and practical sessions, including 15 proctored examinations.Reference Vanni, Pecci, Casati, Moroni, Risso and Ottaviani39 This was then extended to 6-hour workshops, comprising 4-hour lectures and 2-hour demonstrations on normal volunteers, followed by 10 proctored examinations on emergency department patients and 1-month use in daily practice under the supervision of a neuro-otologist.Reference Vanni, Pecci, Edlow, Nazerian, Santimone and Pepe13

In another study, Kotwal et al.Reference Kotwal, Fanai, Fu, Wang, Bery and Omron43 found that 9 hours of deliberate practice using a case library of virtual patients significantly increased the diagnostic skills of medicine interns evaluating real-world dizziness. There is a need for putting more resources into developing condensed educational experiences, such as virtual simulation training, to enhance diagnostic education.

Role of technology

Advances in technology have provided vestibular clinicians with a number of new methods for determining vestibular function. Video-oculography allows for quantitative recording of eye movements. In addition, the introduction of the video Head Impulse Test permits objective evaluation of the vestibulo-ocular reflex in the planes of all six semi-circular canals, a so-called ‘eye ECG’.Reference Newman-Toker, Curthoys and Halmagyi44

‘AVERT’ is an ongoing randomised, controlled diagnostic strategy trial (unique identifier: NCT02483429), which is focused on comparing such a novel video-oculography guided diagnostic strategy to standard care. The goal is for a fully automated ‘eye ECG’ conducted by local providers, with backup telediagnosis made by subspecialists. However, it is worth noting that technologies such as video Head Impulse Test systems come with their own challenges and pitfalls, requiring training and careful administration. The ‘AVERT’ study utilises the services of a specialist audiological scientist, and the review is conducted by an expert otoneurologist, not accessible in most emergency departments. Again, the ability and, more importantly, the willingness of emergency physicians to use these technologies would have to be evaluated.

In future, smartphones may be used to record and evaluate oculomotor examination findings. This would have several advantages, as these are readily available, quick to complete and should be easier to administer. Early proof of concept results are very promising.Reference Otero-Millan, Parker, Badihian, Hassoon, Tehrani and Farrell45,Reference Parker, Farrell, Otero-Millan, Kheradmand, McClenney and Newman-Toker46 ‘Deep learning’ models would allow nystagmus identification and interpretation,Reference Wagle, Morkos, Liu, Reith, Greenstein and Gong47 but have some way to go before being commercially available.

Conclusion

There is compelling evidence in favour of specific bedside tests for the diagnosis of acute vertigo in the emergency department. Firstly, the neurological examination should not be overlooked, particularly when examining for signs that indicate a strong probability of stroke and are easy to look for, such as the inability to stand or sit up independently. The evidence does not support the use of CT to rule out stroke and even early MRI has limitations. Instead, the evidence is growing for protocols that utilise a targeted oculomotor examination. The Head Impulse-Nystagmus-Test of Skew and Head Impulse-Nystagmus-Test of Skew plus hearing examinations have both been well validated when used by specialists. In addition, there are now guidelines, such as the spontaneous nystagmus, direction, head impulse testing and standing protocol, the timing, triggers and targeted bedside eye examinations algorithm, and the associated symptoms, timing and triggers, examination signs and testing algorithm, for selecting the right patients for relevant bedside tests. Other than a limited number of physicians in the spontaneous nystagmus, direction, head impulse testing and standing trial, there is little in the literature suggesting the evidence for emergency physicians using these tools and reporting the required training.

  • There is compelling evidence in favour of specific bedside tests for the diagnosis of acute vertigo in the emergency department

  • Neurological examination is an important part of the assessment process

  • The evidence does not support the use of computed tomography to rule out stroke, and even early magnetic resonance imaging has limitations

  • Evidence is growing for protocols that utilise a targeted oculomotor examination

  • Some tests have been well validated when used by specialists, and there are now guidelines for selecting patients for relevant bedside tests

Advances in vestibular function testing have the potential to improve diagnostic accuracy even more, but they come with their own set of limitations. Smartphone technology, on the other hand, appears to be the most promising tool for assisting non-experts in identifying and interpreting nystagmus. More research into the training requirements and real-world applicability of these approaches is needed.

Acknowledgements

I would like to acknowledge colleagues in the Audiovestibular Department and Emergency Department at St George's Hospital, London.

Competing interests

None declared

Footnotes

David Herdman takes responsibility for the integrity of the content of the paper

References

Newman-Toker, DE, Cannon, LM, Stofferahn, ME, Rothman, RE, Hsieh, YH, Zee, DS. Imprecision in patient reports of dizziness symptom quality: a cross-sectional study conducted in an acute care setting. Mayo Clin Proc 2007;82:1329–40CrossRefGoogle Scholar
Newman-Toker, DE, Hsieh, YH, Camargo, CA Jr, Pelletier, AJ, Butchy, GT, Edlow, JA. Spectrum of dizziness visits to US emergency departments: cross-sectional analysis from a nationally representative sample. Mayo Clin Proc 2008;83:765–75CrossRefGoogle ScholarPubMed
Ljunggren, M, Persson, J, Salzer, J. Dizziness and the acute vestibular syndrome at the emergency department: a population-based descriptive study. Eur Neurol 2018;79:512CrossRefGoogle ScholarPubMed
Strupp, M, Bisdorff, A, Furman, J, Hornibrook, J, Jahn, K, Maire, R et al. Acute unilateral vestibulopathy/vestibular neuritis: diagnostic criteria. J Vestib Res 2022;32:389406CrossRefGoogle ScholarPubMed
von Brevern, M, Bertholon, P, Brandt, T, Fife, T, Imai, T, Nuti, D et al. Benign paroxysmal positional vertigo: diagnostic criteria. J Vestib Res 2015;25:105–17CrossRefGoogle ScholarPubMed
Navi, BB, Kamel, H, Shah, MP, Grossman, AW, Wong, C, Poisson, SN et al. Application of the ABCD2 score to identify cerebrovascular causes of dizziness in the emergency department. Stroke 2012;43:1484–9CrossRefGoogle ScholarPubMed
Newman-Toker, DE, Kerber, KA, Hsieh, Y-H, Pula, JH, Omron, R, Saber Tehrani, AS et al. HINTS outperforms ABCD2 to screen for stroke in acute continuous vertigo and dizziness. Acad Emerg Med 2013;20:986–96CrossRefGoogle ScholarPubMed
Kerber, KA, Newman-Toker, DE. Misdiagnosing dizzy patients: common pitfalls in clinical practice. Neurol Clin 2015;33:565–75, viiiCrossRefGoogle ScholarPubMed
Edlow, JA, Newman-Toker, D. Using the physical examination to diagnose patients with acute dizziness and vertigo. J Emerg Med 2016;50:617–28CrossRefGoogle ScholarPubMed
Edlow, JA, Newman-Toker, DE, Savitz, SI. Diagnosis and initial management of cerebellar infarction. Lancet Neurol 2008;7:951–64CrossRefGoogle ScholarPubMed
Shah, VP, Oliveira, J E Silva L, Farah, W, Seisa, MO, Balla, AK, Christensen, A et al. Diagnostic accuracy of the physical exam in emergency department patients with acute vertigo or dizziness: systematic review and meta-analysis for GRACE-3. Acad Emerg Med 2023;30:552–78CrossRefGoogle ScholarPubMed
Lee, H, Sohn, S-I, Cho, Y-W, Lee, S-R, Ahn, B-H, Park, B-R et al. Cerebellar infarction presenting isolated vertigo: frequency and vascular topographical patterns. Neurology 2006;67:1178–83CrossRefGoogle ScholarPubMed
Vanni, S, Pecci, R, Edlow, JA, Nazerian, P, Santimone, R, Pepe, G et al. Differential diagnosis of vertigo in the emergency department: a prospective validation study of the STANDING algorithm. Front Neurol 2017;8:590CrossRefGoogle ScholarPubMed
Carmona, S, Martínez, C, Zalazar, G, Moro, M, Batuecas-Caletrio, A, Luis, L et al. The diagnostic accuracy of truncal ataxia and HINTS as cardinal signs for acute vestibular syndrome. Front Neurol 2016;7:125CrossRefGoogle ScholarPubMed
Philippon, J, Poirier, J. Joseph Babinski: A Biography. Oxford: Oxford University Press, 2008CrossRefGoogle Scholar
Kerber, KA, Burke, JF, Brown, DL, Meurer, WJ, Smith, MA, Lisabeth, LD et al. Does intracerebral haemorrhage mimic benign dizziness presentations? A population based study. Emerg Med J 2012;29:43–6CrossRefGoogle ScholarPubMed
Chalela, JA, Kidwell, CS, Nentwich, LM, Luby, M, Butman, JA, Demchuk, AM et al. Magnetic resonance imaging and computed tomography in emergency assessment of patients with suspected acute stroke: a prospective comparison. Lancet 2007;369:293–8CrossRefGoogle ScholarPubMed
Hwang, DY, Silva, GS, Furie, KL, Greer, DM. Comparative sensitivity of computed tomography vs. magnetic resonance imaging for detecting acute posterior fossa infarct. J Emerg Med 2012;42:559–65CrossRefGoogle ScholarPubMed
Kabra, R, Robbie, H, Connor, SEJ. Diagnostic yield and impact of MRI for acute ischaemic stroke in patients presenting with dizziness and vertigo. Clin Radiol 2015;70:736–42CrossRefGoogle ScholarPubMed
Ozono, Y, Kitahara, T, Fukushima, M, Michiba, T, Imai, R, Tomiyama, Y et al. Differential diagnosis of vertigo and dizziness in the emergency department. Acta Otolaryngol 2014;134:140–5CrossRefGoogle ScholarPubMed
Grewal, K, Austin, PC, Kapral, MK, Lu, H, Atzema, CL. Missed strokes using computed tomography imaging in patients with vertigo: population-based cohort study. Stroke 2015;46:108–13CrossRefGoogle ScholarPubMed
Kerber, KA, Schweigler, L, West, BT, Fendrick, AM, Morgenstern, LB. Value of computed tomography scans in ED dizziness visits: analysis from a nationally representative sample. Am J Emerg Med 2010;28:1030–6CrossRefGoogle ScholarPubMed
Lawhn-Heath, C, Buckle, C, Christoforidis, G, Straus, C. Utility of head CT in the evaluation of vertigo/dizziness in the emergency department. Emerg Radiol 2013;20:45–9CrossRefGoogle ScholarPubMed
Wasay, M, Dubey, N, Bakshi, R. Dizziness and yield of emergency head CT scan: is it cost effective? Emerg Med J 2005;22:312CrossRefGoogle ScholarPubMed
Tao, WD, Liu, M, Fisher, M, Wang, DR, Li, J, Furie, KL et al. Posterior versus anterior circulation infarction: how different are the neurological deficits? Stroke 2012;43:2060–5CrossRefGoogle ScholarPubMed
Shah, VP, Oliveira, JESL, Farah, W, Seisa, M, Kara Balla, A, Christensen, A et al. Diagnostic accuracy of neuroimaging in emergency department patients with acute vertigo or dizziness: a systematic review and meta-analysis for the guidelines for reasonable and appropriate care in the emergency department. Acad Emerg Med 2023;30:517–30CrossRefGoogle ScholarPubMed
Kattah, JC, Talkad, AV, Wang, DZ, Hsieh, YH, Newman-Toker, DE. HINTS to diagnose stroke in the acute vestibular syndrome: three-step bedside oculomotor examination more sensitive than early MRI diffusion-weighted imaging. Stroke 2009;40:3504–10CrossRefGoogle ScholarPubMed
Tehrani, ASS, Kattah, JC, Mantokoudis, G, Pula, JH, Nair, D, Blitz, A et al. Small strokes causing severe vertigo: frequency of false-negative MRIs and nonlacunar mechanisms. Neurology 2014;83:169–73CrossRefGoogle Scholar
Park, MK, Kim, K-M, Lee, N, Jung, HH, Chae, SW. The usefulness of magnetic resonance imaging for acute isolated vertigo patients in the emergency department. J Int Adv Otol 2014;10:162–6CrossRefGoogle Scholar
Newman-Toker, DE, Kattah, JC, Alvernia, JE, Wang, DZ. Normal head impulse test differentiates acute cerebellar strokes from vestibular neuritis. Neurology 2008;70:2378–85CrossRefGoogle ScholarPubMed
Korda, A, Zamaro, E, Wagner, F, Morrison, M, Caversaccio, MD, Sauter, TC et al. Acute vestibular syndrome: is skew deviation a central sign? J Neurol 2022;269:1396–403CrossRefGoogle ScholarPubMed
Fracica, E, Hale, D, Gold, DR. Diagnosing and localizing the acute vestibular syndrome – beyond the HINTS exam. J Neurol Sci 2022;442:120451CrossRefGoogle ScholarPubMed
Lee, H, Sohn, S-I, Jung, D-K, Cho, Y-W, Lim, J-G, Yi, S-D et al. Sudden deafness and anterior inferior cerebellar artery infarction. Stroke 2002;33:2807–12CrossRefGoogle ScholarPubMed
Kattah, JC. Use of HINTS in the acute vestibular syndrome. An overview. Stroke Vasc Neurol 2018;3:190–6CrossRefGoogle ScholarPubMed
Ohle, R, Montpellier, R-A, Marchadier, V, Wharton, A, McIsaac, S, Anderson, M et al. Can emergency physicians accurately rule out a central cause of vertigo using the HINTS examination? A systematic review and meta-analysis. Acad Emerg Med 2020;27:887–96CrossRefGoogle Scholar
Newman-Toker, DE, Edlow, JA. TiTrATE: a novel, evidence-based approach to diagnosing acute dizziness and vertigo. Neurol Clin 2015;33:577–99CrossRefGoogle ScholarPubMed
Edlow, JA. Diagnosing dizziness: we are teaching the wrong paradigm! Acad Emerg Med 2013;20:1064–6CrossRefGoogle ScholarPubMed
Edlow, JA, Gurley, KL, Newman-Toker, DE. A new diagnostic approach to the adult patient with acute dizziness. J Emerg Med 2018;54:469–83CrossRefGoogle Scholar
Vanni, S, Pecci, R, Casati, C, Moroni, F, Risso, M, Ottaviani, M et al. STANDING, a four-step bedside algorithm for differential diagnosis of acute vertigo in the emergency department. Acta Otorhinolaryngol Ital 2014;34:419–26Google Scholar
Johns, P, Rosenberg, H. Just the facts: how to assess a patient with constant significant vertigo and nystagmus in the emergency department. CJEM 2020;22:463–7CrossRefGoogle ScholarPubMed
Nakatsuka, M, Molloy, EE. The HINTS examination and STANDING algorithm in acute vestibular syndrome: a systematic review and meta-analysis involving frontline point-of-care emergency physicians. PLoS One 2022;17:e0266252CrossRefGoogle ScholarPubMed
Stewart, V, Rosbergen, I, Tsang, B, Hoffman, A, Kwan, S, Grimley, R. Do vestibular physiotherapy and a clinical pathway in the emergency department improve management of vertigo? OTO Open 2022;6:2473974X221119163CrossRefGoogle Scholar
Kotwal, S, Fanai, M, Fu, W, Wang, Z, Bery, AK, Omron, R et al. Real-world virtual patient simulation to improve diagnostic performance through deliberate practice: a prospective quasi-experimental study. Diagnosis (Berl) 2021;8:489–96CrossRefGoogle Scholar
Newman-Toker, DE, Curthoys, IS, Halmagyi, GM. Diagnosing stroke in acute vertigo: the HINTS family of eye movement tests and the future of the “eye ECG”. Semin Neurol 2015;35:506–21Google ScholarPubMed
Otero-Millan, J, Parker, TM, Badihian, S, Hassoon, A, Tehrani, ASS, Farrell, N et al. Eye and head movement recordings using smartphone: measurements of accuracy and precision. J Vis 2022;22:3239CrossRefGoogle Scholar
Parker, TM, Farrell, N, Otero-Millan, J, Kheradmand, A, McClenney, A, Newman-Toker, DE. Proof of concept for an “eyephone” app to measure video head impulses. Digit Biomark 2021;5:18CrossRefGoogle ScholarPubMed
Wagle, N, Morkos, J, Liu, J, Reith, H, Greenstein, J, Gong, K et al. aEYE: a deep learning system for video nystagmus detection. Front Neurol 2022;13:963968CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Pros and cons of diagnostic algorithms for differential diagnosis of vertigo in the emergency department