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The Virtual Neurologic Exam: Instructional Videos and Guidance for the COVID-19 Era

Published online by Cambridge University Press:  21 May 2020

Mariam Al Hussona
Affiliation:
Division of Neurology, Department of Medicine, Postgraduate Medical Education, University of Toronto, Toronto, Ontario, Canada
Monica Maher
Affiliation:
Division of Neurology, Department of Medicine, Postgraduate Medical Education, University of Toronto, Toronto, Ontario, Canada
David Chan
Affiliation:
Division of Neurology, Department of Medicine, St. Michael’s Hospital, University of Toronto, Toronto, Ontario, Canada
Jonathan A. Micieli
Affiliation:
Department of Ophthalmology and Vision Sciences, and Division of Neurology, Department of Medicine, University of Toronto, Toronto, Ontario, Canada
Jennifer D. Jain
Affiliation:
Florida Medical Clinic, Wesley Chapel, Florida, USA
Houman Khosravani
Affiliation:
Division of Neurology, Department of Medicine, Sunnybrook Health Sciences Centre, University of Toronto, Toronto, Ontario, Canada Neurology Quality and Innovation Lab (NQIL), University of Toronto, Toronto, Ontario, Canada
Aaron Izenberg
Affiliation:
Division of Neurology, Department of Medicine, Sunnybrook Health Sciences Centre, University of Toronto, Toronto, Ontario, Canada
Charles D. Kassardjian
Affiliation:
Division of Neurology, Department of Medicine, St. Michael’s Hospital, University of Toronto, Toronto, Ontario, Canada Neurology Quality and Innovation Lab (NQIL), University of Toronto, Toronto, Ontario, Canada
Sara B. Mitchell*
Affiliation:
Division of Neurology, Department of Medicine, Sunnybrook Health Sciences Centre, University of Toronto, Toronto, Ontario, Canada Neurology Quality and Innovation Lab (NQIL), University of Toronto, Toronto, Ontario, Canada Department of Psychiatry, Sunnybrook Health Sciences Centre, University of Toronto, Toronto, Ontario, Canada
*
Correspondence to: Sara B. Mitchell, Division of Neurology, Sunnybrook Hospital, 2075 Bayview Ave., Toronto, OntarioM4N 3M5, Canada. Email: Sara.mitchell@sunnybrook.ca
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Abstract

Objective:

To outline features of the neurologic examination that can be performed virtually through telemedicine platforms (the virtual neurological examination [VNE]), and provide guidance for rapidly pivoting in-person clinical assessments to virtual visits during the COVID-19 pandemic and beyond.

Methods:

The full neurologic examination is described with attention to components that can be performed virtually.

Results:

A screening VNE is outlined that can be performed on a wide variety of patients, along with detailed descriptions of virtual examination maneuvers for specific scenarios (cognitive testing, neuromuscular and movement disorder examinations).

Conclusions:

During the COVID-19 pandemic, rapid adoption of virtual medicine will be critical to provide ongoing and timely neurological care. Familiarity and mastery of a VNE will be critical for neurologists, and this article outlines a practical approach to implementation.

Résumé :

RÉSUMÉ :

Effectuer un examen neurologique à distance : instructions vidéo et orientations à l’ère de la pandémie de coronavirus (COVID-19).

Objectif :

Mettre en évidence les caractéristiques d’un examen neurologique pouvant être effectué à distance au moyen de plates-formes de télémédecine; fournir des orientations pour passer rapidement d’évaluations cliniques en personne à des « visites virtuelles » en ces temps de pandémie de coronavirus (COVID-19), voire à plus long terme.

Méthodes :

Seront décrits en détail les aspects d’un examen neurologique complet qu’on peut aborder à distance.

Résultats :

La présentation d’un examen neurologique de dépistage mené à distance sur une grande variété de patients de même que des descriptions détaillées d’actes nécessaires selon des scénarios spécifiques (tests cognitifs, examens de troubles neuromusculaires et de troubles du mouvement).

Conclusions :

En ces temps de pandémie de coronavirus (COVID-19), l’adoption rapide de la médecine à distance est essentielle si l’on veut offrir des soins neurologiques en temps opportun et de façon continue. Le fait d’être familier avec les examens neurologiques à distance et de les maîtriser deviendra donc crucial pour les neurologues. Voilà pourquoi la présente étude entend mettre en relief une approche pratique permettant la mise sur pied de tels examens.

Type
Original 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 in any medium, provided the original work is properly cited.
Copyright
Copyright © 2020 The Canadian Journal of Neurological Sciences Inc.

Introduction

The COVID-19 pandemic has necessitated rapid and immediate changes to the way physicians deliver care. Nonurgent, face-to-face visits have all but stopped, and yet we must endeavor to provide high-quality and timely patient care.1,2 A home video visit (HVV) is one technology allowing physicians to perform new or follow-up assessments through telemedicine, incorporating video and audio interactions.

The urgency to pivot to virtual care during the pandemic poses many challenges, one of which is adapting the neurological examination to a virtual interface.Reference Ansary, Martinez and Scott3,Reference Craig, McConville, Patterson and Wootton4 The examination is an essential component of the neurological consultation, but few, if any, neurologists are trained to perform a virtual neurologic examination (VNE). The discomfort toward the VNE may be a barrier to general and subspecialty neurologists adapting HVV into practice, in turn influencing patient access to neurologists during the COVID-19 pandemic and beyond.

The purpose of this document and accompanying videos (see Supplementary Material) is to describe a VNE that can be performed on most, if not all, patients (Table 1), along with further details and maneuvers targeting specific clinical presentations (Tables 2 and 3). These recommendations are critical during this period of rapid HVV implementation, but remain useful beyond the ongoing pandemic, as the VNE can be used to assess patients who live at a distance or in underserved communities.

Table 1: Suggested screening VNE

Table 2: Expanded mental status exam

Table 3: Specific scenarios

Not all parts of the neurologic examination can be performed virtually, and the VNE cannot entirely replace an in-person examination. In situations where the clinician is concerned about a serious or potentially harmful neurologic condition, alternative means must be sought to ensure that the patient is assessed urgently in-person. Other limitations of the VNE include the inability to perform a detailed power examination (such as for a neuromuscular consultation), fundoscopy (such as for a headache consultation), and neuro-otology maneuvers (for a vertigo consultation), among others.

A Word about the Neurologic History

It is often taught that the history is the most important element in a neurological assessment and one should have a good sense of the diagnosis (or a short list of differential diagnoses) after obtaining the history. We therefore stress the importance of a detailed and thorough neurologic history, and its weight further increases during a HVV. Details on the neurologic history are beyond the scope of this publication.

The VNE

General Comments

The VNE is best performed in a standardized fashion, with the patient seated in a chair in a well-lit room, without visual obstructions between the patient and camera. An open room is ideal, so that the patient can move closer or farther from the camera during the examination, with space to observe gait. Although privacy is an important consideration during an HVV, having a family member or other third party present can aid with certain aspects of the examination including holding the camera. It is important that the assessment be performed through a secure online platform that is compliant with local privacy acts. The patient may be asked to verify their identity by providing their address or date of birth or showing photographic identification. Consent to perform the exam virtually should be obtained and documented. A translator should be present (either a family member or formal third-party translation services) if required.

Later, we provide a detailed outline of the full neurological examination, with commentary on maneuvers that can be performed virtually. Table 1 outlines a streamlined screening VNE that can be used as a framework for most patients. See the accompanying videos for demonstration of these techniques (Supplementary Material).

Mental Status Examination and Cognitive Testing

Please refer to Supplementary Video 1, for demonstration of a screening virtual mental status examination.

Begin by noting the patient’s level of alertness. Note any bradyphrenia, expressive or receptive aphasia, confusion, or inappropriate affect.

In most cases, a detailed cognitive examination is not required, but as a screen we suggest the following. Orientation can be examined by assessing place (city) and time (day, date, month, and year). The patient should be asked to look straight ahead at the camera while answering orientation questions so as to avoid the use of environmental cues (phone, calendars, and so on). To test attention, instruct the patient to state the months of the year backward or subtract backward from 100 by 7’s.

To screen fluency and recent episodic memory together, ask a question about current events (e.g., pandemic) and then note appropriateness of the answer along with the fluency of speech, the presence of phonemic or semantic paraphasic errors, or the presence of apraxia of speech. Next have the patient name one high- and one low-frequency word (such as knuckles and thumb, respectively). Test single-word repetition by having the patient repeat a word such as “mama,” and then test sentence repetition by having the patient repeat a sentence such as “no ifs ands or buts.” Next have the patient follow simple commands to test comprehension, such as “close your eyes” and then more complex tasks such as “point to the surface that you walk on.” Table 2 outlines an expanded cognitive assessment that can be used if clinically warranted.

Cranial Nerve Examination

Please refer to Supplementary Video 2 for demonstration of a screening virtual cranial nerve examination.

Cranial Nerve 1

This nerve is seldom examined, and abnormalities of smell, such as anosmia, can be screened from the history.

Cranial Nerve 2

Formal visual acuity (VA) assessment cannot be reliably performed through video, but problems with VA can be screened from the history. In addition, a simple screen for symmetry of VA between the eyes could be attempted as follows. Ask the patient to locate a book or newspaper and read the same word using each eye separately while it is held at the same distance from their face. Note that this does not provide a formal acuity value. If assessment of vision is critical, the patient can be referred to a recognized website that provides printable Snellen charts, or a Snellen chart can be mailed to the patient.5 If there is asymmetry between eyes, the patient can be asked to produce a small hole in a piece of paper to see if vision improves. Color vision can be assessed for red desaturation in each eye using any red object (e.g., pen), or using Ishihara color plates (either held up to the camera or through a smartphone application, although standardized electronic versions are lacking).Reference Yeung, Dawes and Pye6

A reliable assessment of visual fields is not possible through video, although computer-based or tablet-based fields are available and have shown good correlation with Humphrey visual fields.Reference Prea, Kong and Mehta7 The examiner may be able to screen for a gross field cut (such as a marked hemianopia) by asking the patient to position their face about 2 feet away from the monitor while looking at an object held by the examiner (e.g., pen) and then ask the patient if they can see all four corners of the monitor. This technique is only appropriate with a computer monitor or tablet (not a smartphone), and will still not adequately assess for deficits in the extremes of the peripheral fields. Pupillary constriction can be assessed by having the patient cover one eye and then uncover, followed by the other eye and watching for the appropriate response.

A major limitation of HVV is the inability to perform fundoscopy or assess for a relative afferent pupillary defect. If the patient has significant new vision loss, the risks of an in-person examination during the pandemic should be weighed against the importance of timely identification of the cause of the vision loss with respect to treatment.

Cranial Nerves 3, 4, and 6

With the patient’s face centered and close to the camera, observe for pupillary asymmetry, ptosis, ocular alignment, or abnormal eye movements such as nystagmus. To test ocular motility, ask the patient to look in the nine cardinal positions of gaze, and it may be necessary to ask the patient to manually lift their eyelids during downgaze. Ask the patient to briefly pause at each gaze position looking for nystagmus. Horizontal saccades can be tested by asking the patient to alternate their gaze between the top right and left corners of the computer screen. Similarly, vertical saccade can be tested by asking the patient to alternate their gaze between just above the computer monitor and just below it.

Cranial Nerve 5

Inspect for temporalis atrophy and ask the patient to open their mouth, looking for jaw deviation. If there is a complaint of facial sensory disturbance, the patient can check sensation over the sensory distributions of the trigeminal nerve side-to-side with a tissue or something cold (e.g., ice pack).

Cranial Nerve 7

Observe baseline facial symmetry, including reduced movement on one side of the face and flattening of the nasolabial fold. Ask the patient to raise their eyebrows, close their eyes tight, purse their lips, show their teeth, and puff out their cheeks.

Cranial Nerve 8

Hearing cannot be formally assessed, and unilateral hearing loss cannot be confirmed through video. The examiner can inquire about hearing during the history.

Cranial Nerves 9 and 10

During the history, note any speech abnormality (nasality, scanning, and spastic dysarthria), and ask patient to phonate (“pa,” “ta,” and “ka”). Depending on video quality and lighting, ask the patient to open their mouth and observe soft palate elevation.

Cranial Nerve 11

Ask the patient to expose the neck and shoulders, evaluating for atrophy of the sternocleidomastoid and trapezius muscles. Have the patient look to the right and then the left and then to shrug their shoulders to test muscle activation.

Cranial Nerve 12

Depending on video quality, observe the tongue in the mouth, looking for fasciculations or atrophy. Ask the patient to protrude the tongue, and move the tongue side to side rapidly.

Motor Examination

Please refer to Supplementary Video 3 for demonstration of a screening virtual motor examination.

Ideally, the patient should be instructed to wear shorts and t-shirt under their clothes and then change at this portion of the exam. Expose and inspect relevant areas of the upper and lower extremities (depending on the clinical concern) for muscle bulk and fasciculations (dependent on video resolution). Observe the patient with the arms at rest and then raise for abnormal movements (tremor, myoclonus, chorea, dystonia, or others). Further details of an examination for various movement disorders are beyond the scope of this document, but some aspects are noted in Table 3.

Subtle signs of pyramidal weakness can be detected by assessing for pronator drift, using the forearm rolling test, and testing of fine finger movements (tapping thumb with index finger repetitively or with each finger alternatively).

On power examination in the upper limbs at least antigravity strength can be noted by observing arm abduction, extension and flexion at the elbows, wrist and finger extension (with forearm pronated), wrist and finger flexion (with forearm supinated), finger abduction, thumb abduction, and thumb extension.

For the lower limbs, position the camera downward. While seated, ask the patient to raise each knee off the chair, to straighten the knees one at a time (knee extensors), and to dorsiflex and then plantarflex each foot. With arms crossed across the chest, ask them to stand up (requires at least Medical Research Council (MRC) grade 4/5 strength of proximal lower limb muscles). Note that the inability to perform this maneuver can also be due to other disorders that do not cause motor weakness, including Parkinsonian disorders. The patient can be asked to do 1–10 squats, to assess for fatigability or subtle proximal leg weakness. The patient should be asked to perform heel raises (dorsiflexion strength), and then do single foot toe raises (plantarflexion strength). They can also be asked to stand and hop on each leg. Axial muscle strength can be tested by asking the patient to perform sit-ups.

Tone, reflexes, and plantar responses cannot be formally assessed.

Sensory Examination

Please refer to Supplementary Video 4 for demonstration of a screening virtual sensory examination.

The sensory examination cannot be formally performed. The specific regions to test and compare will depend on the reason for referral and patient’s sensory complaints (e.g., assessing a specific peripheral nerve distribution, or for length-dependent abnormalities). For a practical screening exam, one could ask the patient to use a nearby household item to compare light touch or temperature on the index fingers of both hands and the top of the big toes. Examples of household items would include a tissue or something cold (an ice pack or a cooled spoon placed under running water). To test for sensory ataxia, the patient can raise their arms, close their eyes, and touch their nose with each index finger separately.

Coordination

Please refer to Supplementary Video 5 for demonstration of a screening virtual coordination examination.

If a family member or other third party is present, they can be asked to hold their finger out for standard finger-to-nose testing. If unavailable, ask the patient to hold an object (such as a pen) outstretched in front of them with one hand, and then with the contralateral index finger perform finger-to-object movements and then repeat on the contralateral side. Alternatively, the patient can be asked to hold their arms outstretched in front of them, and then touch their nose with each index finger. Rapid alternating movements can be checked as usual. Bradykinesia testing can be performed by having the patient perform finger taps and palm opening and closing maneuvers in both arms observing for any fatigability. Heel-to-shin testing can be performed by asking the patient to put each leg on a stool or ottoman and performing the maneuver. The patient can also be asked to perform foot tapping and heel stomping.

Gait

Please refer to Supplementary Video 6 for demonstration of a screening virtual gait examination.

There may be limitations based on camera setup or size of the room. Observe stance at rest and with the feet together. Ask the patient to walk in two directions from one side of the room to the other and then walk away from the camera, turn around, and walk back to the camera. Ask the patient to attempt five steps in either direction before turning around. Tandem gait can be assessed similarly. It is not recommended to perform the Romberg test given the risk of the patient falling without the examiner to catch them.

Other Maneuvers

Scapular winging can be assessed through video. The Phalen maneuver can also be performed (for carpal tunnel syndrome), as can be a spontaneous Spurling sign (tilt their head slightly to the symptomatic side and back) for cervical radiculopathy.

Conclusions

In this article and the accompanying videos, we demonstrate how a neurological examination can be performed virtually, including some practical guidance. Our hope is that this information will increase the confidence of neurologists (as well as internists or general practitioners) in assessing neurological complaints through HVV. Certain neurological consultations are less amenable to a virtual examination, such as concern for myelopathy or cauda equina syndrome in which formal strength, reflexes, appendicular and rectal tone, and saddle anesthesia are critical maneuvers that cannot be performed virtually. It is important to reiterate that if there is concern about a possible urgent diagnosis, then the patient should be either arranged to be seen in-person or directed to seek urgent in-person medical attention.

The quality of each individual patient–physician virtual assessment is unique and dependent on a multitude of factors including the primary neurological complaint, the quality of the technology used, the ability of the patient to manipulate the camera appropriately and follow instructions, and the presence of a third party to assist with the examination. Regardless, the VNE is a powerful tool that has the potential to help deliver care to those who would otherwise be without timely access to neurological consultation and follow-up. This resource is meant to serve as a guide for clinicians to maintain high-quality neurological care during the COVID-19 pandemic and beyond.

Acknowledgements

The authors would like to thank Dr. Felix Tyndel for his contributions to the manuscript.

Disclosures

MAH reports no disclosures. MM reports no disclosures. JAM reports no disclosures. JDJ reports no disclosures. DC reports no disclosures. AI has been on advisory boards for Genzyme, Mitsubishi Tanabe, Roche, Biogen, Alnylam, Takeda, Akcea, and Alexion. CDK has obtained honoraria or been on the advisory board for Alexion, Akcea, Sanofi Genzyme, and Takeda. SBM reports no disclosures. HK reports no disclosures.

Statement of authorship

MAH and MM contributed to the design and conceptualization of the study, development of the videos, and revisions of the manuscript. JAM and JDJ contributed to drafting and revisions of the manuscript. HK, DC, CDK, AI, and SBM contributed to design and conceptualization of the study, drafting and revision of the manuscript, and review of the videos.

Supplementary Material

To view supplementary material for this article, please visit https://doi.org/10.1017/cjn.2020.96.

Footnotes

a

These authors contributed equally to the manuscript.

b

These authors are co-senior authors in the manuscript.

References

Interim guidance for healthcare facilities: preparing for community transmission of COVID-19 in the United States [online]. Available at: https://www.cdc.gov/coronavirus/2019-ncov/hcp/guidance-hcf.html?CDC_AA_refVal=https%3A%2F%2Fwww.cdc.gov%2Fcoronavirus%2F2019-ncov%2Fhealthcare-facilities%2Fguidance-hcf.html; accessed April 3, 2020.Google Scholar
Centers for Medicare and Medicaid Services. Non-emergent, elective medical services, and treatment recommendations [online]. Available at: https://www.cms.gov/files/document/cms-non-emergent-elective-medical-recommendations.pdf; accessed May 28, 2020.Google Scholar
Ansary, AM, Martinez, JN, Scott, JD. The virtual physical exam in the 21st century. J Telemed Telecare 2019: 1357633X1987833.CrossRefGoogle ScholarPubMed
Craig, JJ, McConville, JP, Patterson, VH, Wootton, R. Neurological examination is possible using telemedicine. J Telemed Telecare 1999;5:5.CrossRefGoogle ScholarPubMed
Home eye test for children and adults [online]. American Academy of Ophthalmology. Available at: https://www.aao.org/eye-health/tips-prevention/home-eye-test-children-adults; accessed April 10, 2020.Google Scholar
Yeung, WK, Dawes, P, Pye, A, et al.eHealth tools for the self-testing of visual acuity: a scoping review. npj Digit Med. 2019;2:82.CrossRefGoogle ScholarPubMed
Prea, SM, Kong, YXG, Mehta, A, et al.Six-month longitudinal comparison of a portable tablet perimeter with the Humphrey field analyzer. Am J Ophthalmol. 2018;190:916.CrossRefGoogle ScholarPubMed
Pendlebury, ST, Welch, SJV, Cuthbertson, FC, Mariz, J, Mehta, Z, Rothwell, PM. Telephone assessment of cognition after transient ischemic attack and stroke: modified telephone interview of cognitive status and telephone Montreal cognitive assessment versus face-to-face Montreal cognitive assessment and neuropsychological battery. Stroke 2013; 44: 227–9.CrossRefGoogle ScholarPubMed
Freedman, M, Leach, L, Kaplan, E, Winocur, G, Shulman, K, Delis, DC. Clock drawing: a neuropsychological analysis. New York: Oxford University Press; 1994.Google Scholar
Abdolahi, A, Scoglio, N, Killoran, A, Dorsey, ER, Biglan, KM. Potential reliability and validity of a modified version of the unified Parkinson’s disease rating scale that could be administered remotely. Parkinsonism Relat Disord. 2013;19:218221.CrossRefGoogle ScholarPubMed
Demaerschalk, BM, Vegunta, S, Vargas, BB, Wu, Q, Channer, DD, Hentz, JG. Reliability of real-time video smartphone for assessing National Institutes of Health Stroke Scale scores in acute stroke patients. Stroke 2012;43:32713277.CrossRefGoogle ScholarPubMed
Khosravani, H, Rajendram, P, Notario, L, Chapman, MG, Menon, BK. Protected code stroke: hyperacute stroke management during the coronavirus disease 2019 (COVID-19) pandemic. Stroke [online serial] 2020. Available at: https://www.ahajournals.org/doi/10.1161/STROKEAHA.120.029838; accessed April 21, 2020.Google Scholar
Figure 0

Table 1: Suggested screening VNE

Figure 1

Table 2: Expanded mental status exam

Figure 2

Table 3: Specific scenarios

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