Dr. Viet Nguyen's clinical practice consists of: [1] Intraoperative Neurophysiologic Monitoring (IONM): Dr. Nguyen was fellowship-trained at Stanford in Clinical Neurophysiology, with an emphasis in IONM, after which he was hired as faculty to help run Stanford's IONM service. The service uses somatosensory and motor evoked potentials (SSEP, MEP), electroencephalography (EEG), electromyography (EMG), and brainstem auditory evoked potentials (BAEP) in over 1200 cases per year at SHC and LPCH, to help minimize risk in procedures that endanger the nervous system. These include surgeries and endovascular procedures for cerebral aneurysms, arteriovenous malformations (AVMs), carotid stenosis, brain and spinal tumors, spinal deformities (e.g. scoliosis, spinal stenosis), peripheral nerve injury and tumors, aortic aneurysms, trigeminal neuralgia, facial dystonia, and others. He has published, presented research, and lectured at national and international meetings on IONM topics, and is active in multiple professional organizations in the field, including the American Clinical Neurophysiology Society, Society of Clinical Neurologists, and American Academy of Neurology. [2] The Stanford Spasticity Clinic: Dr. Nguyen runs the Stanford Spasticity Clinic, treating patients with multiple sclerosis, stroke, cerebral palsy, or dystonia (cervical, facial, and limb) using EMG-guided botulinum toxin injections, medications, and physical/occupational therapy. [3] The Stanford Center for Concussion and TBI: Dr. Nguyen treats patients with concussion or traumatic brain injury (TBI), both non-sports and sports related, including varsity and professional athletes. He works to educate patients, families, and the public on properly recognizing and recovering from traumatic brain injuries.

Clinical Focus

  • Neurology
  • Monitoring, Intraoperative
  • Neurophysiology
  • Spasticity
  • Brain Concussion

Academic Appointments

Professional Education

  • Internship:Santa Clara Valley Medical Center Radiology Residency (2006) CA
  • Medical Education:Rosalind Franklin University The Chicago Medical School (2005) IL
  • Fellowship:Stanford University School of Medicine (2010) CA
  • Residency:Stanford University School of Medicine (2009) CA
  • Board Certification, American Board of Clinical Neurophysiology, Advanced Central Clinical Neurophysiology with Added Competency in Intraoperative Monitoring (2014)
  • Board Certification: Neurology, American Board of Psychiatry and Neurology (2009)

Research & Scholarship

Clinical Trials

  • Study to Assess the Efficacy, Safety, Tolerability, and Pharmacokinetics of BIIB033 in Participants With Relapsing Forms of Multiple Sclerosis When Used Concurrently With Avonex Not Recruiting

    The primary objective of the study is to evaluate the efficacy of BIIB033 in participants with active relapsing multiple sclerosis (MS) when used concurrently with Avonex. Secondary objectives of this study in this study population are to assess the safety, tolerability, and population pharmacokinetics of BIIB033 when used concurrently with Avonex.

    Stanford is currently not accepting patients for this trial.

    View full details


2017-18 Courses


All Publications

  • Retrospective Waveform Analysis of Transcranial Motor Evoked Potentials (MEP) to Identify Early Predictors of Impending Motor Deficits in Spinal Surgeries. The Neurodiagnostic journal Le, S., Nguyen, V., Ekwueme, A. C., Cho, S. C., Lee, L., López, J. 2017; 57 (1): 53-68


    Although there are guidelines analyzing transcranial motor evoked potentials (MEP) waveform criteria, they vary widely and are not applied universally during intraoperative neurophysiologic monitoring (IONM). The objective is to generate hypotheses to identify early and reliable MEP waveform characteristics prior to complete loss of MEP to predict impending motor spinal cord injuries during spinal surgeries. The ultimate goal is to enhance real-time feedback to prevent injury or detect reversible spinal cord damage.Fifteen true positive cases of persistent intraoperative MEP loss and new postoperative motor deficits were retrospectively identified from 2011 to 2013. Waveform characteristics of latency, amplitude, duration, phases, and area-under-the-curve (AUC) were measured, and an intraoperative spinal cord index (ISCI) was calculated for 5 traces prior to complete MEP loss. ISCI = [amplitude x duration x (phases+1) x AUC]/latency.Out of 22 muscles in 15 cases, latency increased in 2, duration decreased in 12, amplitude decreased in 13, AUC decreased in 13, and ISCI decreased in 14. In 11 out of 15 cases (73%), ISCI dropped > 40% in at least one muscle before MEP were completely lost. Thirteen cases had concurrent somatosensory evoked potentials (SSEP) changes, 9 out of 13 had > 50% decrease in SSEP: 2 out of 9 changed before MEP, 5 out of 9 simultaneously, and 2 out of 9 after.In these cases of motor injury, smaller and simpler MEP waveforms preceded complete loss of signal. An ISCI 40% drop could be tested as a warning threshold for impending motor compromise in future prospective studies and lead to eventual standardization to predict irreversible postoperative deficits.

    View details for DOI 10.1080/21646821.2017.1257330

    View details for PubMedID 28436812

  • Fentanyl-induced suppression of transcranial Motor Evoked Potentials (tcMEPs) Anaesthesia Cases Bican, O., López, J., Cho, S. C., Nguyen, V., Le, S., Lee, L. 2016; 0241
  • In Vivo Imaging of Human Sarcomere Twitch Dynamics in Individual Motor Units NEURON Sanchez, G. N., Sinha, S., Liske, H., Chen, X., Viet Nguyen, V., Delp, S. L., Schnitzer, M. J. 2015; 88 (6): 1109-1120


    Motor units comprise a pre-synaptic motor neuron and multiple post-synaptic muscle fibers. Many movement disorders disrupt motor unit contractile dynamics and the structure of sarcomeres, skeletal muscle's contractile units. Despite the motor unit's centrality to neuromuscular physiology, no extant technology can image sarcomere twitch dynamics in live humans. We created a wearable microscope equipped with a microendoscope for minimally invasive observation of sarcomere lengths and contractile dynamics in any major skeletal muscle. By electrically stimulating twitches via the microendoscope and visualizing the sarcomere displacements, we monitored single motor unit contractions in soleus and vastus lateralis muscles of healthy individuals. Control experiments verified that these evoked twitches involved neuromuscular transmission and faithfully reported muscle force generation. In post-stroke patients with spasticity of the biceps brachii, we found involuntary microscopic contractions and sarcomere length abnormalities. The wearable microscope facilitates exploration of many basic and disease-related neuromuscular phenomena never visualized before in live humans. VIDEO ABSTRACT.

    View details for DOI 10.1016/j.neuron.2015.11.022

    View details for Web of Science ID 000368443900008

  • Neuromonitoring: EMG, SSEP and MEP Neurosurgery Tricks of the Trade: Spine and Peripheral Nerves Nguyen, V., Lopez, J. R. edited by Nader, R., Berta, S. Thieme. 2014; 1st edition: Chapter 88
  • Peripheral Nerve Surgery A Practical Approach to Neurophysiologic Intraoperative Monitoring Nguyen, V., Jones, E. edited by Husain, A. M. Demos Medical Publishing. 2014; 2nd edition: 163–179
  • Detection of inferolateral trunk syndrome by neuromonitoring during catheter angiography with provocative testing. Journal of neurointerventional surgery Le, S., Dodd, R., López, J., Nguyen, V., Cho, S. C., Lee, L. 2013; 5 (2)


    It is not uncommon that endovascular balloon test occlusion (BTO) is performed to assess collateral blood flow and risk of injury of permanent occlusion of the internal carotid artery (ICA). This case is the first reported of detection and reversal of the inferolateral trunk (ILT) syndrome in an awake patient during provocative BTO; prompt recognition of the syndrome effectively prevented permanent neurologic deficits.The case of a 42-year-old woman is reported who had a left sphenoid wing meningioma with extension into the cavernous sinus and who underwent awake catheter angiography with provocative BTO of the ICA. Serial examinations by intraoperative monitoring neurologists and neurointerventionalists detected acute progressive left retro-orbital pressure followed by sudden inability to adduct the left eye, or a left medial rectus palsy, indicative of the ILT syndrome which led to immediate balloon deflation and resolution of the deficits. The hypothesis was that hypoperfusion of the ILT, an arterial branch of the ICA which provides blood supply to several cranial nerves (CN) III, CN V1 and CN V2, caused her acute symptoms.Although cerebral ischemia is a well known complication of endovascular procedures, CN ischemia is a rare potential risk. Knowledge of cerebrovascular anatomy and serial examinations prevented neurologic deficits; this case underscores the added utility of examinations by intraoperative monitoring neurologists and interdisciplinary collaboration.

    View details for DOI 10.1136/neurintsurg-2011-010236

    View details for PubMedID 22345146