Neuromodulation Using Vagus Nerve Stimulation Following Ischemic Stroke as Therapeutic Adjunct
Overview
- Phase
- Not Applicable
- Intervention
- Not specified
- Conditions
- Acute Ischemic Stroke
- Sponsor
- Washington University School of Medicine
- Enrollment
- 40
- Locations
- 1
- Primary Endpoint
- Interleukin - 1b - Changes and Differences in the Levels
- Status
- Completed
- Last Updated
- 6 months ago
Overview
Brief Summary
This is a randomized open-label, with blinded outcome pilot study to evaluate the effect on inflammatory laboratory values and explore clinical outcomes in patients who present with ischemic strokes due to large vessel occlusions and are treated with either current accepted management, or accepted management in addition to transcutaneous auricular vagal nerve stimulation.
Detailed Description
Stroke is a leading cause of death and disability worldwide. Approximately 80% of strokes are caused by cerebral ischemia. Although stroke is the third leading cause of death after heart disease and cancer, it leads to permanent disabilities in 80% of survivors. Large vessel occlusions (LVOs) account for up to 38% of acute ischemic strokes (AIS). LVOs represent a clinically significant subpopulation of cerebral ischemia due to their disproportionate morbidity and mortality without treatment. Up to 64% of patients without treatment of their LVO are dead or dependent at 3-6 months. Even after successful treatment (recanalization), infarcts can continue to increase in size, a process referred to as ischemia-reperfusion injury, for which even patients who are successfully treated in the acute setting can have poor outcomes. Highlighting the need for adjunct therapies to minimize ischemia progression for both post recanalized and unrecanalized patients. Neuroinflammation has long been recognized as an important element of AIS pathology. In the acute phase of AIS, non-specific inflammatory markers such as C reactive protein, and classical pro-inflammatory cytokines are elevated and have been associated with aggravating brain injury. An interesting avenue of research has now aimed to better understand, and eventually to target these inflammatory pathways to improve outcomes after AIS, with anti-inflammatory interventions trialed in humans. Although ongoing trials are occurring in AIS, the immunomodulation agents can be costly and have marked side effects, for which finding adjunct treatments that are easy to administer and with minimal side effects is of the utmost importance. Vagal nerve stimulation (VNS) has previously been established to have anti-inflammatory effects, and has been successfully demonstrated in other models of inflammatory conditions. Given these promising results in animal studies of AIS, and the established safety of the noninvasive transcutaneous auricular VNS (taVNS), the authors propose prospectively studying this non-morbid and safe intervention in our AIS patients due to LVO population at Barnes Jewish Hospital. Our central hypothesis is that implementing transcutaneous auricular vagal nerve stimulation (taVNS) in the acute period following an ischemic stroke due to a large vessel occlusion will attenuate the expected inflammatory response to the stroke and will curtail morbidity associated with inflammatory-mediated clinical endpoints (i.e., infarct progression). The investigators aim to determine if inflammatory markers in the blood are impacted in patients treated with noninvasive VNS, and as a secondary outcome track patient outcomes to better understand the impact on morbidity and mortality. Patients enrolled in the trial will be randomized to treatment with electrical stimulation to the auricular branch of the vagus nerve (intervention) or stimulation to the great auricular nerve (cervical nerve branch)(Sham) via an auricular, transcutaneous vagus nerve stimulator. All patients will be fitted with the device, the investigators will attach adhesive contacts to the left ear. Stimulation sessions will occur for 20 minutes twice daily during the inpatient period. Patients will have electricity applied to the different nerves depending on the randomization, they will be treated with stimulation with the following parameters: frequency 20 Hz, pulse width 250 µm, and a fixed intensity of 0.5 milliampere. The amplitude of stimulation may be reduced if a patient complains of discomfort at the site of stimulation. The site of stimulation will be inspected daily before and after treatment to ensure there is no redness or irritation at the site. The investigators will obtain laboratory samples on admission, day 0, and every 1.5 days till day 5 or discharge (whichever occurs first) to assess the patients inflammatory markers.
Investigators
Osvaldo J. Laurido-Soto, MD
Assistant Professor
Washington University School of Medicine
Eligibility Criteria
Inclusion Criteria
- •Adult patients who present with acute ischemic strokes due to large vessel occlusions
Exclusion Criteria
- •\<18 years old
- •patients with presumed chronic large vessel occlusions
- •pre-morbid modified Rankin score (mRS) \>2
- •unable to initiate treatment under 36 hours from symptom discovery
- •Chronic or severe infection
- •life expectancy \<3 months
- •patients' undergoing active cancer or immunosuppressive/modulating therapy
- •patients with sustained bradycardia on arrival with a heart rate \<50 beats per minute.
Outcomes
Primary Outcomes
Interleukin - 1b - Changes and Differences in the Levels
Time Frame: 5 days
The primary endpoint was change in inflammatory biomarkers from baseline to day 5, with samples obtained every 1.5 days. Interleukin-1β was the main analyte. Repeated measures were analyzed longitudinally using mixed-effects models (FDA guidance), specifying subject as a random effect to account for multiple observations. This approach accommodated irregular timing, missing data, and time-varying covariates. Models included treatment, time since last known normal, and their interaction to test group differences in biomarker trajectories. Time was modeled quadratically for cytokine and WBC outcomes to capture U-shaped temporal patterns. Interaction p-values assessed trajectory differences between taVNS and sham arms.
Interleukin - 6 - Changes and Differences in the Levels
Time Frame: 5 days
The primary endpoint was change in inflammatory biomarkers from baseline to day 5, with samples obtained every 1.5 days. Interleukin-6 was the main analyte. Repeated measures were analyzed longitudinally using mixed-effects models (FDA guidance), specifying subject as a random effect to account for multiple observations. This approach accommodated irregular timing, missing data, and time-varying covariates. Models included treatment, time since last known normal, and their interaction to test group differences in biomarker trajectories. Time was modeled quadratically for cytokine and WBC outcomes to capture U-shaped temporal patterns. Interaction p-values assessed trajectory differences between taVNS and sham arms.
Tumor Necrosis Factor Alpha - Changes and Differences in the Levels
Time Frame: 5 days
The primary endpoint was change in inflammatory biomarkers from baseline to day 5, with samples obtained every 1.5 days. Tumor necrosis factor was the main analyte. Repeated measures were analyzed longitudinally using mixed-effects models (FDA guidance), specifying subject as a random effect to account for multiple observations. This approach accommodated irregular timing, missing data, and time-varying covariates. Models included treatment, time since last known normal, and their interaction to test group differences in biomarker trajectories. Time was modeled quadratically for cytokine and WBC outcomes to capture U-shaped temporal patterns. Interaction p-values assessed trajectory differences between taVNS and sham arms.
White Blood Cell Total Count - Changes and Differences in the Levels
Time Frame: 5 days
The primary endpoint was change in inflammatory biomarkers from baseline to day 5, with samples obtained every 1.5 days. WBC count was the main analyte. Repeated measures were analyzed longitudinally using mixed-effects models (FDA guidance), specifying subject as a random effect to account for multiple observations. This approach accommodated irregular timing, missing data, and time-varying covariates. Models included treatment, time since last known normal, and their interaction to test group differences in biomarker trajectories. Time was modeled quadratically for cytokine and WBC outcomes to capture U-shaped temporal patterns. Interaction p-values assessed trajectory differences between taVNS and sham arms.
Neutrophil to Lymphocyte Ratio - Changes and Differences in the Levels
Time Frame: 5 days
The primary endpoint was change in inflammatory biomarkers from baseline to day 5, with samples obtained every 1.5 days. neutrophil to lymphocyte ratio based on blood samples was the main result of interestse. Repeated measures were planned to be analyzed longitudinally using mixed-effects models (FDA guidance), specifying subject as a random effect to account for multiple observations. This approach accommodated irregular timing, missing data, and time-varying covariates. Models included treatment, time since last known normal, and their interaction to test group differences in biomarker trajectories.
Secondary Outcomes
- Change in NIH Stroke Scale (NIHSS)(30 days)
- Modified Ranking Scale (mRS)(90 days)
- Number of Participants With Treatment-related Adverse Events as Assessed by CTCAE v4.0 - Hypotension (C143352)(5 days)
- Number of Participants With Treatment-related Adverse Events as Assessed by CTCAE v4.0 - Sinus Bradycardia (C54940)(5 days)