Applications of Non-invasive Neuromodulation for the Management of Disorders Related to COVID-19

Baptista, Abrahão Fontes; Baltar, Adriana; Okano, Alexandre Hideki; Moreira, Alexandre; Campos, Ana Carolina Pinheiro; Fernandes, Ana Mércia; Brunoni, André R.; Badran, Bashar W.; Tanaka, Clarice; Andrade, Daniel Ciampi de; Machado, Daniel Gomes da Silva; Morya, Edgard; Trujillo, Eduardo; Swami, Jaiti; Camprodon, Joan A.; Monte-Silva, Kátia; Sá, Kátia Nunes; Nunes, Isadora Sofia S.; Goulardins, Juliana Barbosa; Bikson, Marom; Sudbrack-Oliveira, Pedro; Carvalho, Priscila de; Duarte-Moreira, Rafael Jardim; Pagano, Rosana L.; Shinjo, Samuel Katsuyuki; Zana, Yossi

doi:10.3389/fneur.2020.573718

Cited by 46 publications

(38 citation statements)

References 226 publications

(266 reference statements)

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“…Therefore, activation of the NTS and the cholinergic anti-inflammatory pathway, both pharmacologically, by activating the alpha 7 nicotinic receptors, and electrically, through noninvasive brain neuromodulation and vagus nerve stimulation (VNS), as also suggested by Baptista et al [39], appear to be promising therapeutic strategies to balance the ANS and produce a balanced autonomic response [40][41][42]. Besides, Leitzke et al [43] have recently reported that these therapeutic approaches for sympathovagal balance in severe courses of COVID-19 can be achieved diagnostically by measuring HRV.…”

Section: Implications and Cholinergic Anti-inflammatory Pathwaymentioning

confidence: 99%

Is the heart rate variability monitoring using the analgesia nociception index a predictor of illness severity and mortality in critically ill patients with COVID-19? A pilot study

et al. 2021

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Introduction The analysis of heart rate variability (HRV) has proven to be an important tool for the management of autonomous nerve system in both surgical and critically ill patients. We conducted this study to show the different spectral frequency and time domain parameters of HRV as a prospective predictor for critically ill patients, and in particular for COVID-19 patients who are on mechanical ventilation. The hypothesis is that most severely ill COVID-19 patients have a depletion of the sympathetic nervous system and a predominance of parasympathetic activity reflecting the remaining compensatory anti-inflammatory response. Materials and methods A single-center, prospective, observational pilot study which included COVID-19 patients admitted to the Surgical Intensive Care Unit was conducted. The normalized high-frequency component (HFnu), i.e. ANIm, and the standard deviation of RR intervals (SDNN), i.e. Energy, were recorded using the analgesia nociception index monitor (ANI). To estimate the severity and mortality we used the SOFA score and the date of discharge or date of death. Results A total of fourteen patients were finally included in the study. ANIm were higher in the non-survivor group (p = 0.003) and were correlated with higher IL-6 levels (p = 0.020). Energy was inversely correlated with SOFA (p = 0.039) and fewer survival days (p = 0.046). A limit value at 80 of ANIm, predicted mortalities with a sensitivity of 100% and specificity of 85.7%. In the case of Energy, a limit value of 0.41 ms predicted mortality with all predictive values of 71.4%. Conclusion A low autonomic nervous system activity, i.e. low SDNN or Energy, and a predominance of the parasympathetic system, i.e. low HFnu or ANIm, due to the sympathetic depletion in COVID-19 patients are associated with a worse prognosis, higher mortality, and higher IL-6 levels.

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Section: Implications and Cholinergic Anti-inflammatory Pathwaymentioning

confidence: 99%

Is the heart rate variability monitoring using the analgesia nociception index a predictor of illness severity and mortality in critically ill patients with COVID-19? A pilot study

et al. 2021

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“…It has been hypothesized that SARS‐CoV‐2 could invade the CNS through the circulation, cerebral spinal fluid or via cranial nerves/olfactory bulb, by synapse‐connection or by direct endocytic paths (similar to ZIKA virus) (Baptista et al., 2020; Channappanavar & Perlman, 2017). Indeed, COVID‐19 is capable to invade astrocytes, neuroblasts, and neurons via the direct binding to the ACE2 receptor (Baptista et al., 2020). This would lead to the dysfunction of ACE2‐mediated cascades with potential implications in neuroinflammation, neurodegeneration, and neurotoxicity processes.…”

Section: Discussionmentioning

confidence: 99%

Prevalence and characteristics of new‐onset pain in COVID‐19 survivours, a controlled study

Soares

Kubota

Fernandes

et al. 2021

European Journal of Pain

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We assessed whether COVID‐19 is associated with de novo pain and de novo chronic pain (CP). This controlled cross‐sectional study was based on phone interviews of patients discharged from hospital after COVID‐19 compared to control group composed of individuals hospitalized during the same period due to non‐COVID‐19 causes. Patients were classifyed as having previous CP based on the ICD‐11/IASP criteria, de novo pain (i.e., any new type of pain, irrespective of the pain status before hospital stay), and de novo CP (i.e. persistent or recurring de novo pain, lasting more than 3 months) after COVID‐19. We asssessed pain prevalence and its characteristics, including headache profile, pain location, intensity, interference, and its relationship with fatigue, and persistent anosmia. Forty‐six COVID‐19 and 73 control patients were included. Both groups had similar sociodemographic characteristics and past medical history. Length of in‐hospital‐stay and ICU admission rates were significantly higher among COVID‐19 survivors, while mechanical ventilation requirement was similar between groups. Pre‐hospitalization pain was lower in COVID‐19 compared to control group (10.9% vs. 42.5%; P=0.001). However, COVID‐19 group had a significantly higher prevalence of de novo pain (65.2% vs. 11.0%, P=0.001), as well as more de novo headache (39.1%) compared to controls (2.7%, p=0.001). New‐onset CP was 19.6% in COVID‐19 patients and 1.4% (P=0.002) in controls. These differences remained significant (p=0.001) even after analyzing exclusively (COVID: n=40; controls: n=34) patients who did not report previous pain before hospital stay. No statistically significant differences were found for mean new‐onset pain intensity and interference with daily activities between both groups. COVID‐19 pain was more frequently located in the head/neck and lower limbs (P<0.05). New‐onset fatigue was more common in COVID‐19 survivors necessitating inpatient hospital care (66.8%) compared to controls (2.5%, p=0.001). COVID‐19 patients who reported anosmia had more new‐onset pain (83.3%) compared to those who did not (48.0%, P=0.024). COVID‐19 was associated with a significantly higher prevalence of de novo CP, chronic daily headache, and new‐onset pain in general, which was associated with persistent anosmia.

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“…3. Non-invasive brain stimulation (NIBS), including transcranial magnetic stimulation (TMS) and transcranial direct current stimulation (tDCS) (Baptista et al 2020;Shinjo et al 2020). tDCS is an experimental NIBS technique, which involves placing two electrodes over the head and running a low intensity current between them to either stimulate (anodal) or inhibit (cathodal) neuronal activity.…”

Section: D)mentioning

confidence: 99%

Presentation and management of anxiety in individuals with acute symptomatic or asymptomatic COVID-19 infection, and in the post-COVID-19 recovery phase

Uzunova

Pallanti

Hollander

2021

International Journal of Psychiatry in Clinical Practice

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COVID-19 is associated with neuropsychiatric complications, the most frequent one being anxiety. Multiple biological and psychosocial factors contribute to anxiety in COVID-19. Among the biological factors, stress, genetics, gender, immune system, resilience, anosmia, hypogeusia, and central nervous system infection with SARS-CoV-2 are key. Anxiety is a complication of COVID-19 that may exacerbate the infection course, and the infection may exacerbate anxiety. We present the mechanisms of anxiety in symptomatic or asymptomatic COVID-19. We discuss the presentation of anxiety in patients without or with prior psychiatric illness, and with co-morbidities. Timely diagnosis and management of anxiety in COVID-19 patients is important. Given the frequent complication of COVID-19 with Acute Respiratory Distress Syndrome and Intensive Care Unit stay, anxiety may be a long-term complication. We review the diagnostic tools for anxiety in COVID-19, and summarise pharmacologic and non-pharmacologic treatments. We provide recommendations for diagnosis, treatment, prevention and follow up of anxiety in COVID-19. KEY POINTS Patients with COVID-19 (symptomatic or asymptomatic) exhibit a high frequency of neuropsychiatric complications with highest percentage attributed to anxiety. Multiple biological and psychosocial risk factors for anxiety exist in COVID-19-ill individuals. Biological risk factors include stress, resilience, genetics, gender, age, immune system, direct infection of the central nervous system (CNS) with SARS-CoV-2, comorbid psychiatric and general medical illnesses, ARDS and ICU stay. Anosmia and hypogeusia are COVID-19-specific anxiety risk factors. Knowledge of the anxiety risk factors is essential to focus on timely interventions, because anxiety may be a complication of and exacerbate the COVID-19 course. An inverse correlation exists between resilience and anxiety because of COVID-19, and therefore efforts should be made to increase resilience in COVID-19 patients. In COVID-19, important anxiety mechanism is neuroinflammation resulting from activation of the immune system and an ensuing cytokine storm. The general approach to management of anxiety in COVID-19 should be compassionate, similar to that during trauma or disaster, with efforts focussed on instilling a sense of hope and resilience. In selecting pharmacological treatment of anxiety, the stress response and immune system effects should be key. Medications with cardio-respiratory adverse effects should be avoided in patients with respiratory problems. Anxiety is a disorder that will require for long-term follow up at least one month after COVID-19.

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Applications of Non-invasive Neuromodulation for the Management of Disorders Related to COVID-19

Cited by 46 publications

References 226 publications

Is the heart rate variability monitoring using the analgesia nociception index a predictor of illness severity and mortality in critically ill patients with COVID-19? A pilot study

Is the heart rate variability monitoring using the analgesia nociception index a predictor of illness severity and mortality in critically ill patients with COVID-19? A pilot study

Prevalence and characteristics of new‐onset pain in COVID‐19 survivours, a controlled study

Presentation and management of anxiety in individuals with acute symptomatic or asymptomatic COVID-19 infection, and in the post-COVID-19 recovery phase

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