dysautonomia – Page 7 – American ME and CFS Society

Autonomic dysfunction in long-COVID syndrome: a neurophysiological and neurosonology study

Dear Sirs,

A significant proportion of patients infected from SARS-CoV-2 experience new, recurring, or ongoing symptoms usually 3 months after infection that may last for weeks or months and comprise the so-called Long-COVID Syndrome (LCS). Most frequent neurological symptoms include fatigue, memory/attention deficits, sleep disorders, myalgias and hyposmia [1]. The occurrence of LCS is not associated with the severity of foregoing acute COVID-19 nor have specific predisposing factors been identified so far. LCS shares common features with two other diseases, Fibromyalgia (FM) and Chronic Fatigue Syndrome (CFS): young women are predominantly affected, the etiology is unknown, although a previous viral infection is suspected, and both conditions have symptoms similar to those of LCS. Autonomic Nervous System (ANS) maladaptation has been proposed as a possible pathogenetic underlying mechanism. [2, 3]

Hence, a case–control study was conducted to investigate if ANS dysfunction may contribute to LCS. Consecutive, adult patients, with history of laboratory-confirmed COVID-19 without hospitalization, presenting with persistent LCS symptoms for > 3 months from COVID-19 onset, including fatigue, cognitive impairment (brain fog), orthostatic dizziness, palpitations, breathlessness or gastrointestinal symptoms, were evaluated at a referral center in Athens, Greece (“Attikon” University Hospital) between September 2021 and December 2021. LCS patients with cardiovascular complications or diabetes were excluded. Controls included colleagues, nursing staff and volunteers without history of SARS-COV-2 infection, cardiovascular diseases, diabetes and ANS disorders. Evaluation of ANS function was performed by Sympathetic Skin Response (SSR) to investigate the Sympathetic Nervous System (SNS), and the cross-sectional area (CSA) of the Vagus Nerve (VN) was assessed by ultrasound to investigate the Parasympathetic Nervous System (PNS) [4]. A detailed description of the methods is available in the online-only supplement. The study was approved by the Institutional Research Bioethics. Informed consent was obtained by all participants. Statistical analysis was performed using the Statistical Package for Social Science (SPSS Inc., version 24.0 for Windows; IBM, Armonk, NY, USA). Descriptive statistics are given as the mean and standard deviation, frequency, and percentage. Statistical comparisons between different groups were performed using the chi-square test (or exact test) for binary outcomes, and Student’s t test or Mann–Whitney U test for continuous variables as appropriate.

Read the full article HERE.

Source: Papadopoulou M, Bakola E, Papapostolou A, Stefanou MI, Gaga M, Zouvelou V, Michopoulos I, Tsivgoulis G. Autonomic dysfunction in long-COVID syndrome: a neurophysiological and neurosonology study. J Neurol. 2022 May 10:1–2. doi: 10.1007/s00415-022-11172-1. Epub ahead of print. PMID: 35536408; PMCID: PMC9086662. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9086662/ (Full text)

Autonomic dysfunction and post-COVID-19 syndrome: A still elusive link

Editorial:

Infection from severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is causing the long-lasting pandemic coronavirus disease 2019 (COVID-19), with dramatic clinical, social, and economic implications. Importantly, evolving experience consistently shows that, in addition to issues related to the acute phase, patients who recover from COVID-19 may present a wide variety of bothersome symptoms, which may be debilitating and significantly impair their quality of life. This condition, when it persists beyond 12 weeks after recovery, is defined as “post–COVID-19” or “long COVID-19” syndrome.1

Some of the symptoms, including tachycardia/palpitations, chest pain, fatigue, and dyspnea with reduced effort tolerance, suggest a possible cardiovascular cause, whereas others (eg, muscle and/or joint pain, headache, memory loss, nausea, mood disturbances) suggest involvement of other systems. Symptoms may occur independently of the severity of COVID-19, although patients with more severe symptoms in the acute phase experience a higher rate of symptom persistence during follow-up.1 ^, 2

Importantly, careful diagnostic assessment usually fails to identify specific causes of post–COVID-19 syndrome. However, it has been suggested that at least some post–COVID-19 symptoms, including those of potential cardiovascular origin, might be related to abnormalities of the autonomic nervous system (ANS).3 The pathophysiological mechanisms responsible for ANS impairment remain speculative and might include direct damage of the ANS (ganglia and/or nerve terminations) by the virus, a toxic effect of inflammatory cytokines released during the acute infection, and an immune-mediated response triggered by some viral component(s).1 ^, 3 Independent of the mechanism, the possibility of ANS involvement in SARS-CoV-2 infection is supported by the frequent occurrence of neurologic symptoms (eg, anosmia, dysgeusia) as well as the sporadic occurrence of clinical conditions typically related to ANS dysfunction (eg, orthostatic hypotension, orthostatic tachycardia) in post–COVID-19 syndrome.3 Furthermore, patients with COVID-19, compared to healthy subjects, have been found to show reduced heart rate variability (HRV) parameters 20 weeks after recovery from the illness.4 However, a pathogenetic relationship between dysautonomia and post–COVID-19 syndrome remains to be demonstrated. Establishing such a relationship would be of importance because it might help guide the management of this clinical condition.

The study by Ladlow et al5 in this issue of Heart Rhythm Journal is welcome because it attempts to clarify whether any association exists between dysautonomia and symptoms, as well as objective evidence of exercise intolerance, in patients with post–COVID-19 syndrome. In their study, Ladlow et al enrolled 205 patients referred to a post–COVID-19 clinic who fulfilled specific eligibility criteria (hospitalization and desaturation ≤95% on a Harvard step test or chest pain with electrocardiographic [ECG] changes during acute illness and life-limiting symptoms persisting for >12 weeks). All patients underwent bicycle cardiopulmonary exercise testing (CPET) and were divided into 1 of 2 groups according to evidence or no evidence of dysautonomia.

Dysautonomia was diagnosed based on 3 heart rate (HR) parameters that Jouven et al6 found to be associated with total mortality and sudden death in a population of asymptomatic subjects: (1) resting HR >75 bpm; (2) increase in HR during exercise <89 bpm; and (3) HR reduction <25 bpm during the first minute of recovery from peak exercise. HRV was also assessed by calculating the root mean square of the squared differences of adjacent RR intervals (RMSSD) on a 1-minute 12-lead ECG at rest and on 30-second ECGs during the first 3 minutes of recovery after peak exercise.

Patients were studied 183 ± 77 days (∼6 months) from COVID-19 disease, and dysautonomia was found in 51 patients (25%). Per definition, these patients had higher HR at rest (95 ± 12 bpm vs 81 ± 12 bpm; P <.001) and lower HR increase during CPET (75 ± 12 bpm vs 96 ± 13 bpm; P <.001) and HR recovery after peak exercise (17 ± 4 bpm vs 31 ± 17 bpm; P <.001) compared to those without dysautonomia.

Patients with dysautonomia were older, had a higher body mass index (BMI) (P = .013) and waist circumference (WC) (P = .003), and had a lower basal RMSSD (P <.001). Furthermore, at rest, dysautonomic patients showed a higher breathing rate (P = .006) and lower forced vital capacity (P = .031), forced expiratory volume in 1 second (P = .036), and ventilatory efficiency (Ve/Vco ₂) (P = .036).

When assessing symptoms that showed prevalence >25%, a significant association with dysautonomia was found for low mood (P = .007), headache (P = .026), and poor attention (P = .047). However, other symptoms, including some of potential cardiovascular origin (eg, shortness of breath, fatigue), showed no significant association with dysautonomia.

Patients with dysautonomia, however, showed a lower performance on CPET. In particular, HR at peak exercise (170 ± 13 bpm vs 177 ± 15 bpm; P = .003), maximal work rate (219 ± 37 W vs 253 ± 52 W; P <.001), and maximal oxygen consumption (V⋅O2) (30.6 ± 5.5 mL/kg/min vs 35.8 ± 7.6 mL/kg/min; P <.001) all were significantly lower in patients with dysautonomia than in those without dysautonomia, suggesting a role of ANS dysfunction in their physical limitation.

Ladlow et al5 should be congratulated for performing this large study on post–COVID-19 syndrome. However, possible alternative interpretations of the data suggest caution in deriving definitive conclusions from their results.

Although the study shows the lack of significant relationship between dysautonomia and most post–COVID-19 symptoms, including, in particular, some symptoms of possible cardiovascular origin, the method applied to identify patients with an impairment of ANS function presents some limitations. Both higher HR at rest and lower HR recovery after exercise suggest an imbalance of sympathovagal tone toward adrenergic predominance in their patients with dysautonomia. However, rather than reflecting a primary impairment of the ANS, these findings simply might have been related to differences between the 2 groups with regard to some basal clinical characteristics, including higher BMI/WC, lower efficiency in respiratory function, and lower mood in dysautonomic patients. In addition, the lower increase in HR during maximal exercise in patients with dysautonomia might have been a mere consequence of their having a higher HR at rest and, given their older age, a lower maximal theoretical HR for age. The percent of predicted maximal HR for age achieved during CPET, in fact, did not differ between the 2 groups. The possibility that the differences in HR behavior might have not been related to a primary abnormality of the ANS is also suggested by the fact that, despite the basal difference, RMSSD values were similar during exercise recovery in the 2 groups of patients, suggesting a similar ANS response to exercise interruption in the 2 groups.

Future studies should clarify whether different results regarding the relationship between ANS dysfunction and post–COVID-19 symptoms might be obtained using more comprehensive and better validated methods for the diagnosis of ANS dysfunction, such as standard tests of autonomic function7 and HRV assessed from its multiple (short-term and long-term) components.8

Of note, although the results of CPET in the study by Ladlow et al5 suggest lower performance by patients classified with dysautonomia, exercise tolerance was largely normal in these subjects, who achieved >100% of the predicted maximal oxygen consumption and an average maximal work rate of 219 W, with only small differences compared to patients without dysautonomia, possibly explained, again, and at least in part, by some demographic (age) and clinical (BMI, respiratory function) differences.

In conclusion, the study by Ladlow et al5 provides interesting data on the clinical characteristics and objective physical performance of patients with post–COVID-19 syndrome. However, the role of ANS in determining symptoms (particularly those of potential cardiovascular origin) and physical limitation in these patients still has not been fully elucidated by their data, making necessary further studies applying more comprehensive and valuable methods for the assessment of ANS function.

Source: Lanza GA. Autonomic dysfunction and post-COVID-19 syndrome: A still elusive link. Heart Rhythm. 2022 Apr;19(4):621-622. doi: 10.1016/j.hrthm.2021.12.027. Epub 2021 Dec 28. PMID: 34968741; PMCID: PMC8712711. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8712711/ (Full study)

Small fiber neuropathy underlying dysautonomia in COVID-19 and in post-SARS-CoV-2 vaccination and long-COVID syndromes

Letter:

We eagerly read the excellent editorial by Gemignani and the corresponding original article by Abrams et al. about the suspected involvement of small fibers (small fiber neuropathy [SFN]) in acute severe, acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infections and in long-coronavirus disease (COVID) syndrome.^1, 2 It was speculated that at least some of the clinical manifestations of long-COVID syndrome could be attributed to involvement of small nerve fibers by the viral infection. The authors believe that studies are needed that investigate the role of autonomic dysfunction in long-COVID syndrome and the prevalence of SFN by means of the 13-item SFN symptom inventory questionnaire. The papers are appealing but raise some concerns that require discussion.

I do not agree with the notion that long-COVID syndrome is the same as post-COVID syndrome.¹ Acute COVID-19 usually lasts one to 4 wk. Subacute COVID-19 lasts 5 to 12 wk. When clinical manifestations of COVID-19 persist beyond 12 wk, the condition is termed post-COVID syndrome. Both subacute COVID-19 and post-COVID syndrome are included under the overarching term long-COVID-syndrome. Differentiating long-COVID syndrome from post-COVID-syndrome is crucial for their management and for assessing long-term outcomes.

An issue not addressed in the paper is Guillain-Barre syndrome (GBS) due to an infection with SARS-CoV-2.³ There is ample evidence that the immune response to the virus can trigger autoimmune reactions, including those that are involved in the development of GBS. There is evidence accumulating that mRNA- and vector-based anti-SARS-CoV-2 vaccines can trigger the development of GBS.⁴ GBS can affect not only motor and sensory fibers, but also peripheral autonomic fibers, particularly in the GBS subtype of acute motor and sensory axonal neuropathy (AMSAN). There is a subtype of GBS that may exclusively affect autonomic fibers and present with pure dysautonomia.⁵ Because GBS may be mild, it can go unrecognized; because patients often have a long recovery time, autonomic manifestations in long COVID syndrome could be explained by incomplete recovery from autonomic involvement in abortive GBS.

Not addressed in the articles is the involvement of the central autonomic nervous system (ANS). There are several reports demonstrating that a SARS-CoV-2 infection can be complicated by hypophysitis.⁶ Furthermore, patients with a pre-existing pituitary micro- or macro-adenoma have an increased risk of pituitary apoplexy during SARS-CoV-2 infection.⁷ Accordingly, the hypophysial-pituitary-adrenergic axis can be impaired,⁸ thus leading to autonomic dysfunction.

Autonomic dysfunction may not always be recognized by those involved in the management of COVID-19 patients. Thus, patients with SARS-CoV-2 infection are often not investigated sufficiently for their symptoms of autonomic dysfunction, such as insomnia, fatigue, cognitive impairment, hypersensitivity to light, blurred vision, dry eyes or mouth, drooling, palpitations, syncope, orthostatic dizziness, hot flashes, dysphagia, bowel or bladder dysfunction, sexual dysfunction, changes in skin, hair, and nails, or abnormalities of sweating. Studies that may be performed to assess ANS involvement are a contrast-enhanced magnetic resonance imaging (MRI) of the pituitary gland, determination of releasing factors, pituitary stimulating hormones, and hormones of peripheral endocrine organs, and diagnostic testing for involvement of the peripheral ANS. Several of the latter tests are not widely available and their sensitivity and specificity may be low if portions of the peripheral ANS are tested that are not affected.

Not addressed was the role of anti-COVID-19 drugs in the development of SFN. There is increasing evidence that some of the compounds administered to infected patients are neurotoxic and can be responsible for polyneuropathy. Some of these compounds, such as lopinavir, ritonavir, daptomycin, and linezolid, may also damage autonomic fibers.

I agree that there is a need to investigate the involvement of the central and peripheral ANS in some patients with acute SARS-CoV-2 infections or long-COVID syndrome. Such patients should be investigated not only by use of questionnaires and the Quantitative Sudomotor Axon Reflex Test (QSART) but particularly by quantitative sensory testing (QST), micro-neurography of C-fibers of the superficial peroneal nerve, sensory stimulation tests, the deep breathing test, the Valsalva maneuver, tilt testing, cerebral blood flow velocity measurements, pain-related evoked potentials (PREP), laser speckle contact analysis (LASCA), laser Doppler flowmetry, laser Doppler imaging, contact heat-evoked potentials (CHEP), corneal confocal microscopy (CCM), and proximal or distal skin biopsy stained with protein gene product (PGP) 9.5. Furthermore, hormone levels should be determined and autopsy of COVID-19 patients should include histological investigations of central and peripheral autonomic pathways.

Source: Finsterer J. Small fiber neuropathy underlying dysautonomia in COVID-19 and in post-SARS-CoV-2 vaccination and long-COVID syndromes. Muscle Nerve. 2022 Apr 6. doi: 10.1002/mus.27554. Epub ahead of print. PMID: 35385125. https://onlinelibrary.wiley.com/doi/10.1002/mus.27554 (Full text)

Long-COVID and the Autonomic Nervous System: The journey from Dysautonomia to Therapeutic Neuro-Modulation, Analysis of 152 Patient Retrospectives

This article is available in PDF format only. You can read it HERE.

Review of the Midbrain Ascending Arousal Network Nuclei and Implications for Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS), Gulf War Illness (GWI) and Postexertional Malaise (PEM)

Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS and Gulf War Illness (GWI) share features of post-exertional malaise (PEM), exertional exhaustion, or postexertional symptom exacerbation. In a two-day model of PEM, submaximal exercise induced significant changes in activation of the dorsal midbrain during a high cognitive load working memory task (Washington 2020) (Baraniuk this issue). Controls had no net change. However, ME/CFS had increased activity after exercise, while GWI had significantly reduced activity indicating differential responses to exercise and pathological mechanisms.

These data plus findings of the midbrain and brainstem atrophy in GWI inspired a review of the anatomy and physiology of the dorsal midbrain and isthmus nuclei in order to infer dysfunctional mechanisms that may contribute to disease pathogenesis and postexertional malaise. The nuclei of the ascending arousal network were addressed. Midbrain and isthmus nuclei participate in threat assessment, awareness, attention, mood, cognition, pain, tenderness, sleep, thermoregulation, light and sound sensitivity, orthostatic symptoms, and autonomic dysfunction and are likely to contribute to the symptoms of postexertional malaise in ME/CFS and GWI.

Source: James N. Baraniuk. Review of the Midbrain Ascending Arousal Network Nuclei and Implications for Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS), Gulf War Illness (GWI) and Postexertional Malaise (PEM) Brain Sci. 2022, 12(2), 132; https://doi.org/10.3390/brainsci12020132 (registering DOI) https://www.mdpi.com/2076-3425/12/2/132/htm (Full text)

Multisystem Involvement in Post-acute Sequelae of COVID-19 (PASC)

Abstract:

Objective: To describe cerebrovascular, neuropathic and autonomic features of post-acute sequelae of COVID-19 (PASC).

Methods: This retrospective study evaluated consecutive patients with chronic fatigue, brain fog and orthostatic intolerance consistent with PASC. Controls included postural tachycardia syndrome patients (POTS) and healthy participants. Analyzed data included surveys and autonomic (Valsalva maneuver, deep breathing, sudomotor and tilt tests), cerebrovascular (cerebral blood flow velocity (CBFv) monitoring in middle cerebral artery), respiratory (capnography monitoring) and neuropathic (skin biopsies for assessment of small fiber neuropathy) testing and inflammatory/autoimmune markers.

Results: Nine PASC patients were evaluated 0.7±0.3 years after a mild COVID-19 infection, treated as home observations. Autonomic, pain, brain fog, fatigue and dyspnea surveys were abnormal in PASC and POTS (n=10), compared to controls (n=15). Tilt table test reproduced the majority of PASC symptoms. Orthostatic CBFv declined in PASC (-20.0±13.4%) and POTS (-20.3±15.1%), compared to controls (-3.0±7.5%,p=0.001) and was independent of end-tidal carbon dioxide in PASC, but caused by hyperventilation in POTS. Reduced orthostatic CBFv in PASC included both subjects without (n=6) and with (n=3) orthostatic tachycardia. Dysautonomia was frequent (100% in both PASC and POTS) but was milder in PASC (p=0.013). PASC and POTS cohorts diverged in frequency of small fiber neuropathy (89% vs. 60%) but not in inflammatory markers (67% vs. 70%). Supine and orthostatic hypocapnia was observed in PASC.

Interpretation: PASC following mild COVID-19 infection is associated with multisystem involvement including: 1) cerebrovascular dysregulation with persistent cerebral arteriolar vasoconstriction; 2) small fiber neuropathy and related dysautonomia; 3) respiratory dysregulation; 4) chronic inflammation.

Source: Novak P, Mukerji SS, Alabsi HS, Systrom D, Marciano SP, Felsenstein D, Mullally WJ, Pilgrim DM. Multisystem Involvement in Post-acute Sequelae of COVID-19 (PASC). Ann Neurol. 2021 Dec 24. doi: 10.1002/ana.26286. Epub ahead of print. PMID: 34952975. https://pubmed.ncbi.nlm.nih.gov/34952975/

Stellate ganglion block reduces symptoms of Long COVID: A case series

Abstract:

After recovering from COVID-19, a significant proportion of symptomatic and asymptomatic individuals develop Long COVID. Fatigue, orthostatic intolerance, brain fog, anosmia, and ageusia/dysgeusia in Long COVID resemble “sickness behavior,” the autonomic nervous system response to pro-inflammatory cytokines (Dantzer et al., 2008). Aberrant network adaptation to sympathetic/parasympathetic imbalance is expected to produce long-standing dysautonomia. Cervical sympathetic chain activity can be blocked with local anesthetic, allowing the regional autonomic nervous system to “reboot.” In this case series, we successfully treated two Long COVID patients using stellate ganglion block, implicating dysautonomia in the pathophysiology of Long COVID and suggesting a novel treatment.

Source: Liu LD, Duricka DL. Stellate ganglion block reduces symptoms of Long COVID: A case series. J Neuroimmunol. 2021 Dec 8;362:577784. doi: 10.1016/j.jneuroim.2021.577784. Epub ahead of print. PMID: 34922127. https://www.jni-journal.com/article/S0165-5728(21)00311-8/fulltext (Full text)

Reduced Parasympathetic Reactivation during Recovery from Exercise in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome

Abstract:

Although autonomic nervous system (ANS) dysfunction in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS) has been proposed, conflicting evidence makes it difficult to draw firm conclusions regarding ANS activity at rest in ME/CFS patients. Although severe exercise intolerance is one of the core features of ME/CFS, little attempts have been made to study ANS responses to physical exercise. Therefore, impairments in ANS activation at rest and following exercise were examined using a case-control study in 20 ME/CFS patients and 20 healthy people.

Different autonomous variables, including cardiac, respiratory, and electrodermal responses were assessed at rest and following an acute exercise bout. At rest, parameters in the time-domain represented normal autonomic function in ME/CFS, while frequency-domain parameters indicated the possible presence of diminished (para)sympathetic activation. Reduced parasympathetic reactivation during recovery from exercise was observed in ME/CFS.

This is the first study showing reduced parasympathetic reactivation during recovery from physical exercise in ME/CFS. Delayed HR recovery and/or a reduced HRV as seen in ME/CFS have been associated with poor disease prognosis, high risk for adverse cardiac events, and morbidity in other pathologies, implying that future studies should examine whether this is also the case in ME/CFS and how to safely improve HR recovery in this population.

Source: Van Oosterwijck J, Marusic U, De Wandele I, Meeus M, Paul L, Lambrecht L, Moorkens G, Danneels L, Nijs J. Reduced Parasympathetic Reactivation during Recovery from Exercise in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome. J Clin Med. 2021 Sep 30;10(19):4527. doi: 10.3390/jcm10194527. PMID: 34640544; PMCID: PMC8509376. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8509376/ (Full text)

Autonomic dysfunction post-acute COVID-19 infection

Introduction:

SARS-CoV-2 infection which causes the disease COVID-19 is most known for its severe respiratory complications. However, a variety of extrapulmonary effects have since been described, with cardiovascular complications being amongst the most common [ 1 ]. Those who recover from the acute phase of COVID-19 may be left with residual symptoms such as chest pain and dyspnea, resulting in a decreased quality of life and a syndrome sometimes described as “long COVID”[ 2 ].

Recent evidence suggests that survivors with some of these chronic symptoms may have autonomic dysfunction with features of postural orthostatic tachycardia syndrome (POTS) and/or inappropriate sinus tachycardia (IST)3 , 4. POTS is characterized by symptoms that occur with standing, an increase in heart rate of ≥30 beats per minute (or heart rate >120 bpm) when moving from a supine to a standing position, and the absence of orthostatic hypotension[ 5 ]. IST is defined as a sinus heart rate >100 beats per minute at rest without an identifiable cause of sinus tachycardia[ 6 ]. Cardiac manifestations of autonomic dysfunction lie on a wide spectrum and can therefore be classified as either POTS, IST, or other unspecified symptoms such as tachycardia and palpitations without a clear, single underlying pathological mechanism.[ 7 ]

The treatment of these arrhythmias includes nonpharmacologic management, such as increasing salt and fluid intake, as well as the use of oral medications. Beta-blockers or off label use of ivabradine have used reported to be used in both syndromes with the goal of controlling heart rate to reduce the symptoms 8 , 9. Other therapies more common in POTS include fludrocortisone, midodrine, pyridostigmine, and alpha-2 agonists[ 8 ].

There is a need to understand the patient characteristics and risk factors for developing AD as a sequela of COVID-19. Furthermore, there is limited management information specific to patients suffering from AD following COVID-19. It is unclear how treatment of these patients and their prognoses may differ from other cases of POTS or IST. In this study, we investigated a small cohort of patients diagnosed with suspected AD post SARS-CoV-2 infection to elucidate possible risk factors and treatment strategies in this population.

Source: Desai AD, Boursiquot BC, Moore CJ, Gopinathannair R, Waase MP, Rubin GA, Wan EY. Autonomic dysfunction post-acute COVID-19 infection. HeartRhythm Case Rep. 2021 Nov 27. doi: 10.1016/j.hrcr.2021.11.019. Epub ahead of print. PMID: 34868880; PMCID: PMC8626157. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8626157/ (Full text)

Post COVID-19 Syndrome in Patients with Asymptomatic/Mild Form

Abstract:

Post COVID-19 Syndrome (PCS) is a complex of various symptoms developing a month or more after the acute phase of the disease. The cases of PCS development among patients with asymptomatic/mild forms are frequently reported; however, the pathogenesis of PCS in this group of patients is still not completely clear. The publications about COVID-19 which were published in online databases from December 2019 to September 2021 are analyzed in this review. According to the analysis, PCS develops on average in 30-60% of patients, mainly among women. Fatigue, shortness of breath, cough, and anosmia were reported as the most common symptoms. The possible association between the described PCS symptoms and brain damage was revealed.

We assume the possibility of an alternative course of COVID-19, which develops in genetically predisposed individuals with a stronger immune response, in which it predominantly affects the cells of the nervous system, possibly with the presence of an autoimmune component, which might have similarity with chronic fatigue syndrome or autoimmune disautonomia. Thus, the gender (female) and the presence of anosmia during an asymptomatic or mild course of the disease can be predictive factors for the development of PCS, which can be caused by autoimmune damage to neurons, glia, and cerebral vessels.

Source: Malkova A, Kudryavtsev I, Starshinova A, Kudlay D, Zinchenko Y, Glushkova A, Yablonskiy P, Shoenfeld Y. Post COVID-19 Syndrome in Patients with Asymptomatic/Mild Form. Pathogens. 2021 Oct 30;10(11):1408. doi: 10.3390/pathogens10111408. PMID: 34832564. https://pubmed.ncbi.nlm.nih.gov/34832564/