key: cord-0911351-nszzxe19 authors: Do, Toan; Diamond, Sarah; Green, Caitlin; Warren, Malissa title: Nutritional Implications of Patients with Dysautonomia and Hypermobility Syndromes date: 2021-09-12 journal: Curr Nutr Rep DOI: 10.1007/s13668-021-00373-1 sha: 68de6226366d25c2c95dd90c12f5e8ea8de407fc doc_id: 911351 cord_uid: nszzxe19 PURPOSE OF REVIEW: Dysautonomia and hypermobility syndrome are two distinct but often overlapping clinical conditions that are recognized for their complex multiorgan system afflictions. The purpose of this review is to investigate dietary strategies to reduce symptoms and augment quality of life in this growing patient population. RECENT FINDINGS: There is increasing evidence supporting dietary modifications to include food rich in probiotics and prebiotics, along with fiber supplements to reduce gastrointestinal symptoms. Adequate salt and fluid intake may reduce orthostatic hypotension symptoms. Dietary supplements may help with osteoarticular, musculoskeletal, and fatigue symptoms. SUMMARY: Individualized diet strategies and supplements can reduce the multiorgan system symptoms observed in dysautonomia and hypermobility syndrome. Hypermobility syndromes are connective tissues disorders that often present with autonomic dysfunction [1] [2] [3] . Autonomic dysfunction, also called dysautonomia, is any change in the autonomic nervous system (ANS) that adversely affects health [4, 5] . Autonomic dysfunction can impact major organ systems including nervous, circulatory, respiratory, endocrine, and digestive and excretory systems [6] [7] [8] . This patient population is increasingly recognized for their complex gastrointestinal symptoms. Further understanding of the nutritional implications in this subgroup of patients will be integral in providing optimal multidisciplinary care and improving quality of life, while reducing morbidity and healthcare utilization. Dysautonomia is associated with several diseases that can be categorized into primary versus secondary. Primary conditions of dysautonomia include neurogenic syncope, postural orthostatic tachycardia syndrome (POTS), familial dysautonomia (FD), and multiple system atrophy. Of the four major conditions of primary dysautonomia, postural orthostatic tachycardia syndrome (POTS) appears to have the most impact on the gastrointestinal system and nutritional status [9] . Several diseases are associated with secondary dysautonomia including gastrointestinal conditions such as inflammatory bowel disease, celiac, and eosinophilic esophagitis; neurological and autoimmune conditions such as Parkinson's, muscular sclerosis, and lupus; and infections such as HIV, Lyme disease, and COVID-19 [2, 5, 10−16] . Further studies are required to elucidate the pathophysiology and clinical impact of dysautonomia in these conditions. Hypermobility syndromes are a complex and multisystemic spectrum of conditions. Hypermobility can be asymptomatic or can present with joint manifestations (arthritis, arthralgia) and soft tissue injuries. When associated with clinical symptoms, the condition is termed joint hypermobility syndrome (JHS) [17] . The symptoms of JHS are considered benign and distinguished from other potentially life-threatening connective tissue disorders such as Marfan syndrome and Ehlers-Danlos syndrome (EDS) [18] . EDS is a group of heritable disorders, characterized by non-inflammatory conditions of connective tissue that present with musculoskeletal symptoms, hyperflexible joints, and hyperelastic skin [19] . Recent literature suggests that clinically, JHS is similar to a subgroup called Ehlers-Danlos syndrome hypermobility type (EDS-HT) [2] . Extra-articular manifestations of JHS include skin laxity and fragility, ocular ptosis, varicose veins, Raynaud's phenomenon, developmental motor delay, fibromyalgia, and low bone density [20, 21] . Postural orthostatic tachycardia syndrome (POTS), recognized in 1993 by Ron Schndorf and Phillip Low, is among the most common causes of chronic orthostatic intolerance [9, 22] . POTS is diagnosed when positional change from supine to upright posture results in a sustained heart rate increase of > /30 beats per minute (or > /40 in patients < 19 years of age) with symptoms of orthostatic intolerance (dizziness, lightheadedness, blurry vision, tremulousness, weakness) [23−25] . The symptoms need to be chronic (> /3 months) and the observed tachycardia should be in the absence of orthostatic hypotension (> /20/10 mm Hg). POTS afflicts approximately 500,000 Americans, most of whom are of white race (93%) and female sex of child bearing age (94%) [26, 27] . The condition can result in significant financial cost to the individual. In a study of 4468 individuals (> /18 years old) diagnosed with POTS, about 75% reported inability to work for at least a week and 67% had to modify their employment responsibilities due to symptoms [28] . The prevalence of joint hypermobility syndrome (JHS) varies in literature due to differing diagnostic criteria. It is generally recognized that the condition is more prevalent in those of Asian or African descent, children and adolescents, and in females [29] [30] [31] . A study of 655 subjects (482 females) US college students estimated that 12.5% have generalized joint hypermobility [32] . Although the prevalence of JHS differs across races and age, this condition is likely underdiagnosed, and the number of individuals impacted by this condition is expected to be higher. Similar to JHS, Ehlers-Danlos syndrome is considered an underdiagnosed condition. It is estimated that 1 in 5000 individuals have Ehlers-Danlos syndrome (all types) [33] . The association between hypermobility conditions and dysautonomia is increasingly demonstrated in literature and recognized clinically. Possible mechanisms to explain dysautonomia in EDS include adreno-receptor hyperresponsiveness, peripheral neuropathy, and molecular defect in blood vessel connective tissues [2, 18, 34] . A study of 48 subjects with JHS (1998 Brighton criteria) demonstrated 78% (21/27) experienced orthostatic intolerance compared with 10% (2/21) of controls [2] . Subjects with JHS also reported greater increase in systolic blood pressure after cold pressor test (10 ± 10 mm Hg vs 11 ± 13 mm Hg) with evidence of β-adrenergic and α-adrenergic hyperresponsiveness compared to controls. Celletti et al. demonstrated in 25 individuals diagnosed with JHS or Ehlers-Danlos syndrome hypermobility type (EDS-HT), 48.6% subjects showed postural orthostatic tachycardia on head-up tilt table test and 31.4% had symptoms of orthostatic intolerance [35] . At resting state, these JHS/EDS-HT subjects also showed significantly higher baroreflex sensitivity compared to controls. A study of 84 subjects with EDS-HT showed these subjects had lower total peripheral resistance and higher heart rate at head-up tilt (70 degree) tests [36] . There is increasing literature reporting the concurrent diagnoses and overlapping symptoms of POTS and EDS-HT. Wallman et. al. reviewed 109 medical records and demonstrated that in subjects with POTS, about 18% also had EDS compared to 0.02% in the general population [37] . The odds ratio of EDS in POTS versus non-POTS patients is 4.9. Individuals with POTS and JHS present with symptoms at an earlier age (23 years old ± 13 versus 41 years old ± 12) compared to individuals with POTS without JHS [38] . Beyond dysautonomia, individuals with JHS/EDS-HT have a range of symptoms that overlap with other conditions such as chronic pain syndromes, chronic fatigue syndrome, anxiety disorder, pelvic floor dysfunction, and exocrine gland dysfunction [39] . Gastrointestinal (GI) symptoms are highly prevalent in individuals with JHS/EDS-HT and contribute to significant functional debility and adverse nutritional consequences. In a pilot study in 2010, Castori et al. found 18/21 (86%) subjects with JHS/EDS-HT reported GI symptoms that included constipation/diarrhea (33.3%), abdominal pain/discomfort (61.9%), gastroesophageal reflux (57.1%), and dyspepsia (66.7%) [40] . The same year, Zarate et al. reported frequent GI symptoms in 21 subjects with JHS/EDS-HT, including dysphasia (14.3%), gastroesophageal reflux (52.4%), bloating (57.1%), vomiting (57.1%), recurrent abdominal pain 85.7%, and constipation/diarrhea (76.2%) [41] . Zarate et. al. also found abnormal esophageal manometry (33.3%), abnormal 24-h pH-ambulatory monitoring (33.3%), delayed gastric emptying (80%), abnormal small bowel manometry (44.4%), and abnormal colorectal transit (100%). Fikree and colleagues reported that subjects with JHS were found to have an odds ratio (OR) 1.66 for heartburn, OR 2.02 for water brash, and OR 1.74 for postprandial fullness compared to non-JHS controls [42] . A positive, linear correction between the severity of JHS and GI symptoms were observed in this population. In a recent retrospective review, Zhou et al. found that 35% of EDS-HT patients who underwent breath testing had small intestinal bacterial overgrowth (SIBO), of which 92% were methane positive, while only 35% were hydrogen positive. Unlike SIBO in the general population, EDS-HT patients with SIBO were more likely to be constipated compared to EDS patients without SIBO (50.00 vs. 26.53%, p = 0.042) [43] . Dysautonomia further exacerbates GI complications in EDS-HT individuals. The autonomic nervous system controls the "fight or flight" versus "rest and digest" response [44] . An imbalance of this binary state causes individuals with EDS-HT an inability to be in the "rest and digest" state when appropriate. There is increasing literature demonstrating that dysautonomia is a major factor to a spectrum of GI complaints [41−45] . Dysbiosis and dysregulation of gutrelated immune function may be linked to a higher prevalence of food allergies and inflammatory or autoimmune disorders observed in EDS-HT individuals [46, 47] . Identifying and correcting nutritional deficiencies is the cornerstone of nutritional management for patients with dysautonomia and/or JHS/EDS-HT. Although literature on nutritional management of this population is limited, the spectrum of symptoms observed in this population have been demonstrated to be significantly influenced by nutritional status and dietary intake. Primary nutrition recommendations most often include diet modification, nutrition support therapies, and micronutrient supplementation to improve or maintain nutrition status when symptoms have resulted in suboptimal oral intake, altered utilization of nutrients, and significant weight loss [48••] . As with any chronic disorder, a thorough nutrition assessment that includes dietary history, weight history, past medical and surgical history, medication/supplement review, GI function, and a comprehensive nutrition focused physical exam is necessary to determine appropriate nutrition therapies. There is theorizing in the literature that alternative therapies including modified diets and nutritional supplements may improve symptoms related to dysautonomia and JHS/ EDS-HT; however, given the extrapolative nature and lack of empirical investigation, these nutritional suggestions should be considered low-level recommendations [39] . An individualized plan of nutritional management that includes careful monitoring of symptoms with a multidisciplinary approach that includes gastroenterology, nutrition, psychiatry, and pain management, and neurology is likely to yield the best results [49••] . The spectrum of gastrointestinal symptoms experienced by individuals with dysautonomia and JHS/EDS-HT can be ameliorated through various nutritional supplements and avoidance of specific foods (Table 1 ). These recommended modifications may not have been studied in patients with dysautonomia but are extrapolated from studies in subjects with conditions that have similar symptoms as those with dysautonomia and JHS/EDS-HT. Diarrhea and constipation are two common GI symptoms of individuals with dysautonomia and HMS/EDS-HT. Soluble fiber supplements not only reduce diarrhea but have also demonstrated long-term protective effects against metabolic disorders, cardiovascular disease, and colon cancer along with promoting bowel regularity [11, 50] . A low FODMAP (fermentable oligo, di, mono-saccharides, and polyol) diet has been shown to reduce symptoms of diarrhea, bloating, and flatulence in individuals with irritable bowel syndrome (IBS) by 50-80% [51] . Similarly, a gluten-free diet has been demonstrated to reduce diarrhea and abdominal discomfort in some individuals with IBS [52] . Probiotics such as Lactobacillus GG and Bifidobacterium lactis can also reduce frequency of diarrhea [53] . For individuals who experience constipation, fiber supplementation has been demonstrated to increase stool frequency [54] . It should be noted that the impact of fiber on stool consistency and pain with defecation is marginal. Optimization of the gut microbiome may promote digestion and reduce GI symptoms in this population. The gut microbiome plays an increasingly recognized role in digestion, gut inflammation, and absorption of nutrients [55, 56] . These beneficial bacteria in the gut assist in the digestion of resistant starches and lipids, synthesis short-chain fatty acid, and absorption of essential fat soluble vitamins (A, [63, 64] . Avoidance of certain foods may prevent dysbiosis. Processed foods, including refined carbohydrates, and those high in salt such as cured meats, contribute to dysbiosis [65] . Artificial sweeteners may promote harmful gut organisms like Proteobacteria, and contribute to gut inflammation, glucose intolerance, and breakdown of the GI intestinal barrier that result in a "leaky gut" [66−68] . A dysfunctional GI intestinal barrier that allows "leakage" of material in and out of the body has been linked to several GI symptoms including bloating, cramps, food allergies, gas, and headaches [69••] . A "leaky gut" may be associated with multiple sclerosis, inflammatory bowel disease, depression and other mood disorders, and autoimmune conditions. Similarly, a diet high in fructose and alcohol consumption has been linked to dysbiosis and increased gut permeability [70, 71] . Various nutritional strategies can be appliedto reduce orthostatic symptoms experienced by individuals with primarydysautonomia or JHS/EDS-HT. Mathias et al. demonstrated that water intake of 2-2.5L/day and salt ingestion >8g (150 mmol/day) can improve orthostatichypotension [72] . Adequate water intake can reduce changes in blood pressureand heart rate in subjects with severe orthostatic hypotension [73] .Subjects who drank 480 mL of tap water at room temperature within 5 min demonstratedless blood pressure decrease (22±10/12±5 mm Hg) compared to those withoutdrinking water (43±36/20±13 mm Hg) with position change. This is believed to besecondary to a rapid pressor response in individuals with autonomic failure. Puvi-Rajasingham et al. demonstrated that in subjects with primary chronicautonomic failure, having 6 smaller meals instead of three larger mealsresulted in fewer symptoms of dizziness and lightheadedness with positionalchanges [74] . Increasing salt intake in individuals withorthostatic hypotension has been recommended by the 2017 ACC/ AHA/HRS guidelineand the American Family Physician, although with varying amounts [75 ••, 76-77] . Low (2008) and colleagues studied subjects with neurogenic orthostatichypotension and reported that salt supplementation is essential [78] .After checking 24-h urinary sodium, individuals with value <170 mmol can besupplemented with 1-2g of sodium tablets three times a day. Figueroa et al. proposed salty soup and approximately 8 oz. serving of fluid over half a day or2 g salt tablets three times a day with a minimum of eight 8-oz serving offluid over a day to reduce orthostatic decompensation [79] .It should be recognized that there is low-quality evidence that increased saltintake reduces orthostatic intolerance [77] .A meta-analysis of 14 studies with 391 subjects demonstrated that increase saltintake resulted in higher systolic blood pressure by 12 mmHg and fewer reportedsymptoms of orthostatic intolerance. Although long-termempirical investigation is needed in subjects with dysautonomia to assess thefull impact of dietary salt on symptoms, increasing the quantity of salt indiet may reduce the frequency and severity of orthostatic hypotension in this population. Individuals with EDS-HT and dysautonomia areat risk for micronutrient deficiencies, due to limitations in dietary intakeand bacterial overgrowth and may require either oral or parenteralsupplementation. EDS-HT patients are known to have low vitamin D serum levels [80, 81] . It is recommended that EDS-HT individuals take 5000U daily of vitamin D3(cholecalciferol) year-round or at a minimum during non-summer months. Toreduce complications of skin fragility and promote wound healing, individualswith EDS-HT should take 750-1000 mg/day vitamin C and 1500 mg/day of methylsulfonylmethane (MSM)plus silica 3 mg/day [82] . Vitamin C, also called ascorbic acid, is a cofactor in collagen synthesis and is rapidly consumed in the wound healing process [83] .It is also an antioxidant and suppressor of proinflammatory processes.Individuals with POTS have been shown to be deficient in B12 and B1. B12deficiency was proven to be significantly lower in children with POTS and B12supplements may reduce orthostatic symptoms in this population [84] . Vitamin B1 (thiamine), is a water-soluble vitamin that is integral to energymetabolism. Thiamine supplement in individuals with experiencing dysautonomiacan help promote cell growth, function, and development [10] . In some instances, despite optimized medicaltherapy, patients with primary dysautonomia or JHS/EDS-HT are unable to meettheir nutrition and hydration needs orally. Individuals with poor nutritionstatus may require intravenous hydration, enteral nutrition or even parenteralnutrition support. In a retrospective cohort study of 332 subjects at atertiary care hospital, patients with POTS were followed for 7 years [49 ••] . In the cohort, a subset of 32 patients required nutrition support, of which 66%required intravenous fluids, 59% required enteral nutrition, and 28% required parenteral nutrition. Six of the 32 patients required all three forms of nutrition support throughout the study period. Severe GI symptoms, such asnausea and vomiting, diarrhea, constipation and abdominal pain, were more prevalent in patients receiving nutrition support and GI transit studies were more likely to indicate delayed gastric emptying, indicating that GIdysmotility is a significant factor in need for nutrition support. Individuals with JHS/EDS-HT commonlyexperience joint symptoms that result in functional impairment, often requiringanalgesic use and corrective surgery [85] .Musculoskeletal pain is derived from acute, recurrent, or chronic inflammationof soft tissues leading to bursitis, synovitis, fasciitis, or tendinitis [42, 86] .Castori et al. demonstrated that the prevalence of arthralgias and back pain inEDS individuals increased from approximately 30% in children to >/80% inadults over 40 years old [87] . The frequency and severity of MSK pain is dependent ongeneral lifestyle, physical activity, trauma/surgery, and co-morbidities [88] .The natural history of JHS/EDS begins with sprains, dislocations, growing painwhich progresses to recurrent arthralgias, back pain, radiographicosteoarthritis, and spondylosis. In the third to fourth decade of life, chronicarthralgias, back pain, tendon/ ligament degenerations, and widespread rigidityis common. In early stage, pain is commonly localized at small to large jointsand in sensed by nociceptors. With recurrent and progressive injury,individuals with JHS become unable to localize their pain. In advanced forms ofJHS/EDS-HT, analgesic medication alone is insufficient to manage pain. Nutritional therapies for osteoarticularjoint pain in individuals with JHS/EDS-HT are wide ranging. For joint injuryand arthritis, 1500 mg/day of glucosamine is recommended [89, 90] .Glucosamine is a sugar-related nutrient used by the body to synthesize complexmolecules, which are necessary to maintain, support, and repair connectivetissue and joints. Glucosamine or chondroitin have demonstrated reduction injoint space narrowing [89] [90] [91] , Although not yet studied in JHS/EDS-HT individuals,chondroitin sulfate (1200 mg/day) and manganese ascorbate (228 mg/day) may reduce degenerative joint disease of knee or low back. Musculoskeletal pain is common and presentwithin the first decade with exertional or post-exertional myalgia/cramps andmild hypotonia in JHS/EDS-HT. In the second to third decade of life, recurrentmyalgias and focal muscle hyperalgesia may progress to chronic myalgias,fibromyalgia, and muscle weakness [88] .Neuropathic pain can present as peripheral paresthesia, allodynia, generalizedmuscle hyperalgesia (including fibromyalgia), and dysesthesias. For general muscle weakness and fibromyalgia, a supplement of 250 mg/day of carnitine and 100 mg/day coenzyme Q10 (CoQ10) can improve symptoms [92, 93] . Carnitine is a natural compound that is an essential cofactorin fatty acid metabolism. CoQ10 is a cofactor for production of adenosinetriphosphate (ATP), an integral compound providing energy to cells such asmuscles. In a meta-analysis of 12 studies with 75 subjects, CoQ10 supplementsignificantly reduced statin-associated muscle weakness, cramp, fatigue, andpain [94] . For general inflammation, y-linolenic acid at 240 mg/dayis recommended [88] . Y-linolenic acid is an essential fatty in cell membranesand a precursor to eicosanoids [95] .Eicosanoids are compounds integral to the development and maturation of theimmune system and inflammatory response. Supplement of y-linolenic acid mayprovide the necessary precursors to repair the inflammatory and gut microbiomedysfunction. Fatigue is common in patients withJHS/EDS-HT. It may present in the first decade of life and progress to poorsleep and post-exertional dyspnea [88] .Fatigue can progress to severe post-exertional malaise and disabling morningfatigue. Supplements such as CoQ10, magnesium, nicotinamide adeninedinucleotide (NADH), and alpha-lipoic acid may ameliorate fatigue [96] .A meta-analysis demonstrated improvement in fatigue with CoQ10 supplementationamong heart failure, multiple sclerosis, fibromyalgia, and healthy individuals [97] .In subjects with chronic fatigue syndrome, NADH taken in combination with CoQ10has also been proven to improve fatigue [92] .Magnesium levels have been shown to be lower in individuals with chronicfatigue syndrome compared to controls [98] . Furthermore, Cox et al. demonstrated in a randomized, double-blind study thatintramuscular magnesium sulphate weekly for 6 weeks resultedin less pain, improved emotional state, and overall higher energy levelscompared to placebo. Dysautonomia and JHS/EDS-HT are independent but often overlapping conditions that are increasingly recognized clinically for the multisystem complexity in their presentation and symptoms. Among the range of ailments, gastrointestinal, orthostatic, osteoarticular, musculoskeletal pain, and fatigue are the most prevalent and debilitating. While there are pharmacologic therapies to address specific symptoms, nutritional management remains a cornerstone of optimizing this patient population's overall nutritional status and quality of life (Table 1) . GI symptoms such as diarrhea and constipation can be reduced with increasing soluble fiber, food rich in pre and probiotics, FODMAP, or gluten-free diet. Furthermore, these modifications will promote normobiosis of the gut resulting in improved absorption and reducing leaky intestinal barrier. Orthostatic hypotension can be ameliorated with salt (6-10 g per day) and drinking (1.5-3L) fluids per day. Supplements such as glucosamine, carnitine, CoQ10 can reduce systemic symptoms of osteoarticular inflammation, musculoskeletal pain, and severe fatigue, respectively. These recommendations may be extrapolated from studies in populations afflicted by similar symptoms as those with dysautonomia, and further investigations are required to elucidate the pathophysiology of symptoms and specific benefits of nutritional support in individuals with dysautonomia and hypermobility syndrome. Data Availability Data derived from public domain resources. Conflict of Interest None. Human and Animal Rights and Informed Consent. This article does not contain any studies with human or animal subjects performed by any of the authors. Ethics approval This literature review has not been submitted to more than one journal for consideration. To the best of authors' knowledge, all data have been cited by the original publisher to maintain integrity of scientific discovery. 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