Emily M. Garland

The hemodynamic and neurohumoral phenotype of postural tachycardia syndrome

Background: Previous studies of patients with postural tachycardia syndrome (POTS) have been hampered by relatively small cohorts, failure to control medications and diet, and inconsistent testing procedures. Methods: The Vanderbilt Autonomic Dysfunction Center Database provided results of posture studies performed in 165 patients and 66 normal controls after dietary and medication restrictions. All posture studies were performed after an overnight fast and ≥30 minutes of supine rest. Results: In both the supine and standing positions, heart rate (HR) and plasma concentrations of norepinephrine (NE), epinephrine, and dopamine were higher in patients with POTS compared with the healthy controls. Supine diastolic blood pressure (BP) was also elevated in POTS, whereas supine plasma l-3,4-dihydroxyphenyalanine was reduced. In an analysis of patient subgroups with either an upright plasma NE ≥ 3.54 nM (high NE) or an upright plasma NE < 3.54 nM (normal NE), HR and BP were greater in the patient subgroup with high NE. In addition to these significant differences in hemodynamic and catechol measurements, we demonstrated that supine and standing plasma aldosterone and the aldosterone/renin ratio were decreased in patients with POTS. Plasma renin activity (PRA) tended to be higher in patients, and standing HR for those in the highest PRA quartile was significantly greater than for those in the lowest PRA quartile. Conclusions: Our results from larger cohorts of patients and controls than previously studied confirm published findings and contribute additional evidence of sympathetic activation in postural tachycardia syndrome (POTS). Abnormalities in the renin–angiotensin–aldosterone system may also contribute to the POTS phenotype.

Clinical Assessment of Norepinephrine Transporter Blockade Through Biochemical and Pharmacological Profiles

Background— To assess the sensitivity of biochemical, physiological, and pharmacological markers of peripheral norepinephrine (NE) transporter (NET) function, we chronically antagonized NET by a range of doses of duloxetine [(+)-N-methyl-3-(1-naphthalenyloxy)-2 thiophenepropanamine], which blocks the NE reuptake process. Methods and Results— Duloxetine was administered in a randomized, placebo-controlled study in 15 healthy volunteers. Plasma from duloxetine-treated subjects (ex vivo effect) dose-dependently decreased radioligand binding to human NET (maximum inhibition was 60%) (P =0.02). The dose of intravenous tyramine required to raise systolic blood pressure by 30 mm Hg (PD30) increased dose-dependently with duloxetine and was significant at the end of the 120-mg/d dosage (P <0.001). The plasma dihydoxyphenylglycol to NE (DHPG/NE) ratio was reduced significantly at 2 weeks of treatment with 80 mg/d duloxetine (11.3 at baseline, 3.4 at 240 mg/d, P <0.001). Plasma NE was significantly increased starting at 120 mg/d duloxetine. Urine results (corrected for 24-hour creatinine excretion) showed a dose-dependent change from the baseline urinary excretion for NE, DHPG, and the DHPG/NE ratio. The most sensitive measure, the DHPG/NE ratio, was significant at the 80-mg dose. Urinary NE excretion was significantly raised after 2 weeks of treatment with 80 mg/d duloxetine (P <0.001), the lowest dose used in the study. Conclusions— These findings suggest that the degree of NET blockade can be assessed with the plasma or urine DHPG/NE ratio and the pressor effect of tyramine. Also, the DHPG/NE ratio is more sensitive at the lower end of NET inhibition, whereas tyramine exhibits a linear relation, with NET inhibition commencing at a higher dose.

Vesicular Acetylcholine Transporter Density and Alzheimer’s Disease

We have evaluated the vesamicol analogue meta-[125I]iodobenzyltrozamicol {(+)-[125I]MIBT} as a probe to assess cholinergic terminal integrity in the human temporal cortex. Saturation binding analysis, using 5-aminobenzovesamicol (ABV) to define nonspecific binding, revealed a high-affinity binding site with a Kd value of 4.3 +/- 1.2 nM in the temporal cortex of the young control subjects. Similar affinity values were observed for (+)-[125I]MIBT binding in aged control subjects (Kd = 3.4 +/- 0.5 nM) and AD patients (Kd = 3.0 +/- 0.8 nM). In contrast, Bmax values for young subjects, aged controls and AD patients were 31.2 +/- 6.3, 17.0 +/- 2.0 and 9.4 +/- 1.6 pmol/g, respectively, clearly reflecting significant reductions in (+)-[125I]MIBT binding site density with aging and age-related neuropathology. Moreover, the decrease in (+)-[125I]MIBT binding was correlated with choline acetyltransferase activities (r = 0.72) in the AD temporal cortex. These results suggest that when selective ligands are used, the vesicular acetylcholine transporter can be a useful marker protein for assessing the loss of cholinergic projections in AD and related disorders.

Familial Orthostatic Tachycardia Due to Norepinephrine Transporter Deficiency

Abstract: Orthostatic intolerance (OI) or postural tachycardia syndrome (POTS) is a syndrome primarily affecting young females, and is characterized by lightheadedness, palpitations, fatigue, altered mentation, and syncope primarily occurring with upright posture and being relieved by lying down. There is typically tachycardia and raised plasma norepinephrine levels on upright posture, but little or no orthostatic hypotension. The pathophysiology of OI is believed to be very heterogeneous. Most studies of the syndrome have focused on abnormalities in norepinephrine release. Here the hypothesis that abnormal norepinephrine transporter (NET) function might contribute to the pathophysiology in some patients with OI was tested. In a proband with significant orthostatic symptoms and tachycardia, disproportionately elevated plasma norepinephrine with standing, impaired systemic, and local clearance of infused tritiated norepinephrine, impaired tyramine responsiveness, and a dissociataion between stimulated plasma norepinephrine and DHPG elevation were found. Studies of NET gene structure in the proband revealed a coding mutation that converts a highly conserved transmembrane domain Ala residue to Pro. Analysis of the protein produced by the mutant cDNA in transfected cells demonstrated greater than 98% reduction in activity relative to normal. NE, DHPG/NE, and heart rate correlated with the mutant allele in this family. Conclusion: These results represent the first identification of a specific genetic defect in OI and the first disease linked to a coding alteration in a Na+/Cl−‐dependent neurotransmitter transporter. Identification of this mechanism may facilitate our understanding of genetic causes of OI and lead to the development of more effective therapeutic modalities.

Renal Impairment of Pure Autonomic Failure

Supine hypertension is difficult to manage in patients with pure autonomic failure (PAF), because treatment can worsen orthostatic hypotension. Supine hypertension in PAF has been associated with left ventricular hypertrophy, but end organ damage in the kidney has not been assessed. We reviewed hemodynamic and laboratory data of 64 male patients with PAF who were 69±11 (mean±SD) years old. Systolic blood pressure fell by 67±40 mm Hg within 10 minutes of standing, with an inappropriately low 13±11-bpm increase in heart rate. Plasma norepinephrine levels were below normal (0.62±0.32 nmol/L supine and 1.28±1.25 nmol/L standing). A control data set of 75 men (67±12 years) was obtained from a deidentified version of the Vanderbilt University Medical Center electronic medical chart database. Compared with controls, PAF patients had lower hemoglobin (8.3±0.9 versus 9.3±0.8 mmol/L; P<0.001), packed cell volume (0.40±0.04 versus 0.45±0.04; P<0.001), and red blood cell count (4.4±0.5×1012 versus 5.0±0.5×1012 cells/L; P<0.001). Serum creatinine and blood urea nitrogen levels were elevated in patients. Forty-eight percent of patients with PAF had supine hypertension (supine systolic blood pressure: ≥150 mm Hg). Serum creatinine was higher in patients with supine hypertension (133±44 versus 106±27 &mgr;mol/L; P=0.021) and estimated glomerular filtration rate was lower (57±22 versus 70±20 mL/min per 1.73 m2; P=0.022) compared with patients who did not have supine hypertension. These findings may indicate that renal function is diminished in PAF in association with supine hypertension.

Chiari I malformation as a cause of orthostatic intolerance symptoms: a media myth?

There is much interest in a putative relationship between Chiari I malformation and symptoms of orthostatic intolerance. It has been reported at scientific meetings that a number of patients with chronic fatigue syndrome or fibromyalgia have Chiari I malformation, or hindbrain compression in the absence of Chiari, and that they experience improvement after decompression surgery. Many of these patients have symptoms of orthostatic intolerance. A connection between Chiari I malformation and these conditions has been discussed in newspaper articles and on national television programs. Patients have also had access to much information on this topic via the Internet. Unfortunately, the Chiari I malformation and orthostatic intolerance connection is almost entirely unsupported by peer-reviewed literature. The purpose of this article is to provide an objective review of the available information.

Diagnosing postural tachycardia syndrome: comparison of tilt testing compared with standing haemodynamics.

POTS (postural tachycardia syndrome) is characterized by an increased heart rate (ΔHR) of ≥30 bpm (beats/min) with symptoms related to upright posture. Active stand (STAND) and passive head-up tilt (TILT) produce different physiological responses. We hypothesized these different responses would affect the ability of individuals to achieve the POTS HR increase criterion. Patients with POTS (n=15) and healthy controls (n=15) underwent 30 min of tilt and stand testing. ΔHR values were analysed at 5 min intervals. ROC (receiver operating characteristic) analysis was performed to determine optimal cut point values of ΔHR for both tilt and stand. Tilt produced larger ΔHR than stand for all 5 min intervals from 5 min (38±3 bpm compared with 33±3 bpm; P=0.03) to 30 min (51±3 bpm compared with 38±3 bpm; P<0.001). Sn (sensitivity) of the 30 bpm criterion was similar for all tests (TILT10=93%, STAND10=87%, TILT30=100%, and STAND30=93%). Sp (specificity) of the 30 bpm criterion was less at both 10 and 30 min for tilt (TILT10=40%, TILT30=20%) than stand (STAND10=67%, STAND30=53%). The optimal ΔHR to discriminate POTS at 10 min were 38 bpm (TILT) and 29 bpm (STAND), and at 30 min were 47 bpm (TILT) and 34 bpm (STAND). Orthostatic tachycardia was greater for tilt (with lower Sp for POTS diagnosis) than stand at 10 and 30 min. The 30 bpm ΔHR criterion is not suitable for 30 min tilt. Diagnosis of POTS should consider orthostatic intolerance criteria and not be based solely on orthostatic tachycardia regardless of test used.

Fragile X gene premutation in multiple system atrophy

Previous reports have suggested that expansion of the CGG repeat located in the fragile X mental retardation 1 (FMR1) gene might be responsible for a significant number of patients with the multiple system atrophy (MSA) phenotype. Analysis of 65 MSA patients found only 4.6% displayed CGG expansions in the suspected range. This is similar to the frequency reported in the normal population, suggesting that this expansion does not play a major role in the MSA phenotype.

A cross-sectional study contrasting olfactory function in autonomic disorders

Objective: To compare odor identification function in patients with peripheral or central autonomic neurodegeneration and in patients with intact autonomic neurons but undetectable norepinephrine. Methods: Olfactory function was evaluated with the University of Pennsylvania Smell Identification Test (UPSIT) in 12 patients with pure autonomic failure, 10 patients with multiple system atrophy, and 4 patients with dopamine β-hydroxylase deficiency. Blood pressure and catecholamine data were also compared. Results: Odor identification was significantly impaired in patients with pure autonomic failure relative to patients with multiple system atrophy or dopamine β-hydroxylase deficiency. Out of 40 odors, the patients correctly identified mean (95% confidence interval) 19.2 (14.1 to 24.2), 34.4 (32.2 to 36.6), and 31.7 (29.4 to 34.1) (p < 0.001). The difference between patients with pure autonomic failure and those with multiple system atrophy or dopamine β-hydroxylase deficiency persisted after adjustment for age (p = 0.001). Patients with pure autonomic failure also had a greater orthostatic fall in blood pressure and lower plasma norepinephrine levels than patients with multiple system atrophy. Conclusions: Olfactory function was relatively intact in patients with dopamine β-hydroxylase deficiency, who have intact noradrenergic neurons but lack norepinephrine. Odor identification was impaired in pure autonomic failure but not in multiple system atrophy, suggesting that 1) peripheral noradrenergic innervation is important for olfactory identification but norepinephrine is not essential and 2) UPSIT may be useful in the differential diagnosis between these disorders.

Postural Tachycardia Syndrome: Beyond Orthostatic Intolerance

Postural tachycardia syndrome (POTS) is a form of chronic orthostatic intolerance for which the hallmark physiological trait is an excessive increase in heart rate with assumption of upright posture. The orthostatic tachycardia occurs in the absence of orthostatic hypotension and is associated with a >6-month history of symptoms that are relieved by recumbence. The heart rate abnormality and orthostatic symptoms should not be caused by medications that impair autonomic regulation or by debilitating disorders that can cause tachycardia. POTS is a “final common pathway” for a number of overlapping pathophysiologies, including an autonomic neuropathy in the lower body, hypovolemia, elevated sympathetic tone, mast cell activation, deconditioning, and autoantibodies. Not only may patients be affected by more than one of these pathophysiologies but also the phenotype of POTS has similarities to a number of other disorders, e.g., chronic fatigue syndrome, Ehlers-Danlos syndrome, vasovagal syncope, and inappropriate sinus tachycardia. POTS can be treated with a combination of non-pharmacological approaches, a structured exercise training program, and often some pharmacological support.