disorders ofgastrointestinal motility in neurologic diseases · disorders ofgastrointestinal...
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Subject Review
Disorders of Gastrointestinal Motilityin Neurologic Diseases
MICHAEL CAMILLERI, M.D., Gastroenterology Research Unit
Neurologic diseases can affect the bowel at several levels of innervation-bY alteringthe electrical activity that controls smooth muscle, the enteric nervous system, or theextrinsic neural pathways to the gut. This review concentrates on disorders ofmotility that occur in conjunction with diseases of the extrinsic neural supply (fromthe level of the brain to the postganglionic fibers) and those generalized disordersthat affect gut smooth muscle. Modern technology, such as gastrointestinal scintigraphy and manometric techniques that measure esophageal, gastroduodenal, andanorectal motility (intraluminal pressures), has provided better methods to study thepathophysiologic aspects of gut motility in diseases of the nervous system. Distinguishing the neuropathies of the extrinsic nervous system from those of the intrinsic(enteric) nervous system is not always possible because the available techniquesevaluate only the end-organ-that is, the motor function of the gut. Degenerative orinfiltrative (myopathic) disorders of gut smooth muscle, however, can be distinguished from such neuropathies, and careful and systematic evaluation ofautonomicfunction can often identify the level of disordered function in the neural-gut axis.
The intimate relationship between neurologicfunction and gastrointestinal motility has beenknown for decades. Langley and associates-"noted that intractable diarrhea developed inanimals subjected to ganglionectomy. The inhibitory role of the sympathetic extrinsic supplyto gut smooth muscle and its excitatory effectson gut sphincters are well known; nevertheless,clinicians rarely associate gastrointestinal dysfunction with disturbances in sympathetic control. In contrast, the effects of surgical or traumatic neural lesions are fully appreciated in
This work was supported in part by the Mayo DigestiveDiseases Core Center (Grant DK 34988, National Institutesof Health, Public Health Service).
Address reprint requests to Dr. Michael Camilleri, Gastroenterology Research Unit, Mayo Clinic, Rochester, MN55905.
clinical practice, as in postvagotomy gastric stasis or diarrhea and acute transient ileus aftertransection of the spinal cord.
This review addresses the disorders that affect the extrinsic neural supply to the gut andgeneralized muscle disorders that involve themotor function of the gut. The emphasis is ongastric, small bowel, and colonic motility, inasmuch as discussions of deranged oropharyngeal,esophageal, or anorectal motility in neurologicdisorders are readily available in standard texts"or recent reviews."
A practical classification of these disorders isproposed, based on the anatomic level of theneural or muscular disease. Examples of suchdisorders are provided for each anatomic level,with additional detail for the more commonconditions such as diabetic neuropathy. Thediscussion is focused on general neuromuscular
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disorders rather than disturbances ofthe myenteric plexus alone because the latter were extensively reviewed in the recent literature.5 Foreach neurologic disease discussed, the salientclinical features, pathophysiologic characteristics, and histologic evidence of gut involvementare described. In several areas, the literature islimited to case reports or observations of fewcases, a reflection of the rarity or the relativelyunexplored nature of some neurologic disordersthat may affect the gut. In contrast, the morecommonly observed effects of surgical vagotomyand pudendal nerve injury are not discussed. Apractical approach for the identification of extrinsic neurologic disease in patients with symptoms suggestive of gastrointestinal motor dysfunction is included at the end of this review. Adiscussion of treatment is beyond the scope ofthis article.
Whereas the morphologic features of themyenteric plexus and smooth muscle in patientswith intestinal pseudo-obstruction have beenstudied extensively," histologic and physiologicevaluations rarely have assessed the extrinsicneural control in such patients. Extrinsic denervation may be associated with a disturbance ofthe myenteric plexus, such as in experimentalisoniazid-induced damage of the myentericplexus" and in many conditions discussed in thisreview.
Before the clinical syndromes are considered,it is necessary to point out that diverse methodsand terms are used to measure and describe"motility." Moreover, pressure activity, myoelectric activity, and transit data do not necessarily correspond to one another. There is also aplethora of overlapping terms, and purely descriptive terms, such as "bursts" of phasic pressure activity or "interdigestive motor complexlike activity," are used. An attempt has beenmade to use uniform terminology throughoutthis article. "Bursts" are defined as a series or acluster of phasic contractions that last morethan 2 minutes, usually unassociatedwith propagation and sometimes associated with tonicchanges in baseline pressure. "Interdigestivemotor complex-like activity" refers to a postprandially propagated activity front with the
same propagation velocity and maximal frequency of contractions as in phase III of theinterdigestive motor complex.
INTERACTIONS BETWEEN EXTRINSICNERVOUS SYSTEM AND GUTBrain and gut interactions have been exploredexperimentally in animals, and recently inhumans, by using vestibular and central autonomic stimuli.I-" Perhaps these neural-gut interactions are best demonstrated by the disturbances of motor function of the gut in neurologicdisease. In recent years, better methods havebeen developed to study gastrointestinal motility (by manometry and transducers that recordintraluminal pressures) and transit (by radioscintigraphy) in health and disease, includingthose conditions that affect its neuromuscularfunction. Other investigators have studied themorphologic features of the myenteric plexusneurons in gastrointestinal motor dysfunctionand have drawn attention to derangements ofthe enteric plexuses in disease." In general, noetiologic distinction can be made when myenteric plexus neurons have a similar histologicappearance.
A practical classification of neuromusculardisorders that affect gut motility is proposed inthis article; it is based on the proven or likelyanatomic level ofthe lesion (Table 1). The citedexamples of disease processes at various levelsaffecting the motor function of the gut suggestthat an anatomic approach should provide auseful framework for the clinical evaluation ofpatients with disorders of gut motility in whomneurologic disease is suspected. Assessment ofthe function of the autonomic nervous systemand the histopathologic changes in the gut andits neural connections may provide clues to thecause and mechanisms ofgastrointestinal symptoms and may lead to novel therapeutic strategies in the future. Although some of the available literature concerns only small numbers ofpatients or single cases, a thorough examinationof these reports provides a framework that supports our strategy to classify and evaluate suchconditions clinically on an anatomic basis fromthe level of the brain to the postganglionic fi-
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Table I.-Neuromuscular Disorders AffectingGastrointestinal Motility
Enteric nervous systemIdiopathic, degenerative, or inflammatory disorders of
the myenteric plexusSome disorders of the enteric nervous system may be
associated with diseases that affect extrinsic neuralcontrol
Extrinsic nervous systemPeripheral nerves
Acute (for example, Guillain-Barre syndrome)Chronic (for example, diabetes mellitus,
amyloidosis)Autonomic nervous system degenerations (for
example, idiopathic orthostatic hypotension,pandysautonomia)
Spinal cord (for example, injury, multiple sclerosis)Brain stem (for example, tumor)Higher centers (for example, epilepsy)
Smooth muscleInfiltration of muscle by generalized disease (for
example, amyloidosis, scleroderma)Generalized muscle disease affecting the gut (for
example, dermatomyositis, dystrophia myotonica,other muscular dystrophies)
bers (extrinsic), myenteric plexus, or smoothmuscle.
NORMAL GASTROINTESTINALMOTOR FUNCTIONEsophageal motility is characterized by an organized propagation of phasic contractionsthrough the esophagus with each swallow. Inthe upper and lower sphincters, relaxation occurs with swallowing, and subsequent contraction occurs with arrival at the sphincter of thepressure wave that is propagated through thepharynx or esophagus. Such contractions resultin peristalsis of solid and liquid boluses and, tosome extent, the prevention of reflux throughthe sphincters.
Normal motor function of the foregut andmidgut is characterized by the occurrence ofcyclic motor activity during fasting and thedevelopment of triturating, mixing, and propulsive activity postprandially. The fasting phaseis characterized by the interdigestive motorcomplex (Fig. 1), which commences in the gastroduodenal region and propagates for a variable distance down the small bowel. 10 This cyclic
activity consists ofthree phases: phase I, quiescence; phase II, intermittent phasic pressureactivity (contractile activity that is unassociatedwith alterations in muscle tone); and phase III,an "activity front" during which regular repetitive contractions occur at the maximal frequencytypical of each region. The interdigestive motorcomplex propagates a variable distance downthe gut and has been likened to a "housekeeper,"sweeping residual products of digestion andfasting debris toward the colon. There is alsoevidence that similar, albeit less regular, cyclicmotor activity occurs in the colon. Postprandially, gastric and small bowel contractions ofvariable amplitude occur irregularly (Fig. 1)although fairly consistently, depending on thesize and the nutrient content of the meal. Thesecontractions result in the trituration of solid foodin the stomach and the steady propulsion ofsolids and liquids through the stomach and smallbowel.
Colonic motility is characterized by fastingcyclic activity, intermittent irregular contractions, and mass movements. This last characteristic is associated with giant migrating contractions that result in bolus movements throughthe normal ileum and expulsion during defecation. For defecation, an integrated relaxation ofthe anal sphincter and the puborectal muscle isnecessary.
Symptoms of gastrointestinal motor dysfunction are thought to originate from the regionalabnormalities in contractile activity. Gastricemptying may be delayed as a result ofimpairedtrituration of solid food (antral hypomotility) orimpaired aboral flow of chyme (intestinal dysmotility) from the stomach.P:"constipation maybe attributable to impaired colonic contractileactivity, and incontinence results from dysfunction of the anal sphincter.
CONTROL OF GASTROINTESTINALMOTILITYIn order to understand the basis for disturbances in motor function ofthe gut due to extrinsic neuropathies, the factors that control gastrointestinal motility will be considered briefly.Gastrointestinal motility and normal transit are
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Proxlm.1 Jejunum
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Fig. 1. Normal fasting and postprandial motility in healthy human volunteer. Note cyclic interdigestivemigrating motor complex (left panel) and sustained, high-amplitude but irregular pressure activity aftermeal (right panel). Antroduodenal ports are separated by 1 em; small bowel ports are each 10 em apart.(From Malagelada and associates.")
the end results of an intricately balanced seriesof control mechanisms: the electrical and contractile properties of the smooth muscle cell andcontrol by the intrinsic nervous system, extrinsic neural pathways (sympathetic and parasympathetic), and gastrointestinal neuropeptides(which may act as neurotransmitters as well ashaving hormonal or paracrine functions).
The electrical properties ofthe smooth muscleof the gut!" are the result of transmembranefluxes of ions, which, as in other excitable tissues, alter the membrane potential. Spontaneous fluctuations in membrane potential lead toan inward calcium flux by altering calciumchannels, and they serve to trigger muscle contraction.
Some regions of the gut (such as the outerlamella of jejunal circular muscle-? and the internal anal sphincter-") generate transmembranepotential differences (slow waves) that are unassociated with a rapid action potential (or "spike").Nevertheless, contractile activity may be seen.Other regions demonstrate both a slow wave andan action potential (for example, gastric andinner lamella of jejunal circular muscle-"), andthe contractile response occurs only when spikes
are generated (Fig. 2). The significance of thesedifferences in myoelectric activity is unclear.Infiltrative or degenerative processes that affectthe smooth muscle of the gut (see subsequentmaterial) prevent the occurrence of normalcontractions and result in disorders of gastrointestinal motility.
The intrinsic or enteric nervous system14
contains about 108 neurons, approximately thenumber present in the spinal cord. This integrative system differs in form and is separate fromthe sympathetic and parasympathetic portionsof the autonomic nervous system. This systemhas sensory receptors (for example, mechanoreceptors and chemoreceptors), interneurons thatprocess this sensory input and that control effector units, and motor neurons that serve as theprimary effector cells involved in motor activityof the gut. An integrative synaptic circuitryserves to control the coordinated behavior of theentire gastrointestinal tract. The synaptic pathways in the gut have been compared to a seriesof preprogrammed circuits that are capable ofself-adjustment on the basis of sensory input;moreover, they can be altered by extrinsic control from the central nervous system.
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Contractile response with each slow wave
Contractile response with spike potentials
Electrical
Electrical
Mechanical
ly demonstrated by their involvement in the intrinsic and extrinsic neural control.
The extrinsic innervation of the gut15 consists of the parasympathetic vagal and sacralnerves (S-2, 3, and 4) by means of the pelvicnerves and the sympathetic outflow from theintermediolateral column of the spinal cord,between the levels of the fifth thoracic and thirdlumbar segments (Fig. 3). The sympatheticnerves synapse in the celiac, superior mesenteric, and inferior mesenteric ganglia, and theterritories of neural supply in the gut generallycorrespond to the vascular supply of the respective arterial trunks. Extrinsic nerves are intimately involved in the control of the striatedmuscle portions of the esophagus and the external anal sphincter. Although the smooth muscleportion of the gut can function fairly normallywithout the extrinsic nerves, the latterare knownto modulate the intrinsic neural circuits and tointegrate activity in widely separated regions ofthe gastrointestinal tract. Furthermore, extrinsic nerves exert more important control in certain regions (for example, the stomach and distal portion of the colon) than in others (such asthe small bowel).
Fig. 2. Relationship between electrical control activity andcontractile response of gastrointestinal smooth muscle. Insome tissues (for example, antrum or inner circular muscleof jejunum), contractions occur only in conjunction withthe development of spike potentials (upper tracings); inother tissues (for example, internal anal sphincter), eachslow wave is associated with a mechanical response (lowertracings).
As in other regions of the nervous system,neurochemical transmission at the cell bodies ofenteric neurons involves excitatory and inhibitory, fast and slow postsynaptic potentials. Eachtype of postsynaptic potential has a specificneurotransmitter (or neurotransmitters) andionic mechanism. For example, slow excitatorypostsynaptic potentials (mediated by serotonin,substance P, and possibly other neurotransmitters) result in receptor-mediated decreases inthe resting membrane conductance for potassium ions. They seem to be responsible foractivation of a network of effector (for example,motor) neurons, such as the simultaneous development of a "slow wave" in smooth muscle cells.This "electromyogram of the gut" encompassesthe entire circumference of a segment of thegastrointestinal tract. Slow excitatory postsynaptic potentials probably also facilitate theneuromodulation of conduction by other neuralsynaptic input and by paracrine and endocrinefactors. 14
The integration between the enteric and theautonomic extrinsic nervous systemoccurs partlythrough the excitatory vagal pathway. Thispathway is composed of preganglionic cholinergic fibers that synapse with myenteric cholinergic neurons, which in tum excite smooth muscle.A second integrative mechanism is provided bythe sympathetic supply, which inactivates neural circuits that generate motor activity whileallowing continuous activity of intrinsic inhibitory innervation ofthe musculature. Extrinsicvagal fibers also synapse with nonadrenergicinhibitory intramural neurons in the gut. Thispresynaptic inhibition is mediated by severaltransmitters, including norepinephrine (at (lzadrenergic receptors), serotonin, opioid peptides,acetylcholine (at presynaptic muscarinic receptors), and histamine (at presynaptic H3 receptors). Loss ofthis inhibitory influence would beexpected to result in excessive or uncoordinatedphasic pressure activity in the gut. Indeed, aswill be apparent throughout this review, patients with intrinsic or extrinsic neurologic disorders have such uncoordinated pressure activity.
The roles of biogenic amines and peptides inthe control of gastrointestinal motility are clear-
830 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES
Sympathetic
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Parasympathetic
Fig. 3. Extrinsic innervation of the gut. CG =celiac ganglion; HN =hypogastric nerves;IMG = inferior mesenteric ganglion; IMN = inferior mesenteric nerve; LCN = lumbarcolonic nerves; PN = pelvic nerves; SCG = superior cervical ganglion; SMG = superiormesenteric ganglion; X = vagal nuclei.
EXTRINSIC NEUROLOGIC DISORDERSCAUSING GUT DYSMOTILITYAlthough disturbed gut motility may result fromalterations in the contractility or electrical control activity of the gut muscle cell, enteric nervous system, or extrinsic nerve supply, the intimate interrelationships among these threelevels of control often make it difficult to determine the predominant disturbance along thepathway. In many instances, however, it is possible to distinguish the following (Table 1): disorders that affect the gut muscle ("myopathicdisorders"); those of the myenteric plexus, usually in the form of an idiopathic, chronic intestinal pseudo-obstruction;" and diseases of theextrinsic pathways that supply the gut. Nevertheless, some diseases affect both intrinsic andextrinsic neural controL Because this reviewconcentrates mainly on diseases of extrinsiccontrol, those illnesses that affect both extrinsicand intrinsic neural function are considered inthis section on extrinsic neurologic disorders.
AcutePeripheraINeuropathy.-Autonomicdysfunction associated with certain acute viral
infections may result in nausea, vomiting, abdominal cramps, constipation, or a clinical picture of pseudo-obstruction, as shown by reviewof several individual case reports. Thus, in theGuillain-Barre syndrome, visceral involvementmay include gastric dilatation!" or adynamicileus."? Persistent gastrointestinal motor disturbances may also occur in association withinfections with herpes zoster.!" Epstein-Barrvirus.!? or botulism B.20 Whether these infections result in an intrinsic or extrinsic neuropathy that affects the gut is uncertain; however,some investigators have shown that intestinalpseudo-obstruction may result from cytomegalovirus infection of the myenteric plexus." Noformal motility studies have substantiated thegastrointestinal motor dysfunction in these situations, and perhaps different viruses affect different levels of gut neural control but result inthe same clinical picture.
Chronic PeripheralNeuropathy.-Chronicperipheral neuropathy, predominantly due todiabetes mellitus or amyloidosis, is the mostcommonly encountered extrinsic neurologic dis-
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order that results in gastrointestinal motordysfunction.
Diabetes Mellitus.-Diabetic autonomicneuropathy of the gut has been studied extensively during the past decade." Gastrointestinal symptoms are exceedingly common in patients with diabetes; in one study, 76% of 136unselected outpatients with diabetes reportedhaving nausea and constipation." Gastric emptying of digestible or nondigestible solids in patients with diabetes mellitus and gastrointestinal symptoms ("gastroparesis") is abnormal;however, little is known about the pathogenesisor treatment of this relatively common disorder.Studies in humans have demonstrated the paucity of antral contractions in the distal portion ofthe stomach during phase III of the interdigestive motor complex and during the postprandialperiod.v' Other potentially important pathophysiologic changes (Fig. 4) in gastroparesis aredecreased postprandial duodenojejunal phasicpressure activity, nonpropagated uncoordinatedbursts of contractions in the proximal portion ofthe small bowelv" and pylorospasm."
Constipation is a frequent, although oftenunreported, symptom in patients with diabetes,23 but little is known about its pathogenesis.In contrast, diarrhea or fecal soiling (or both)may result from several mechanisms: dysfunction of the anorectal sphincter or abnormal rectal sensation that leads to incontinence.Fv"osmotic diarrhea from bacterial overgrowth dueto small bowel stasis or rapid transit from uncoordinated small bowel motor activity;" or associated gluten-sensitive enteropathy'" or pancreatic exocrine insufficiency.I" For treatment thatis rational and effective, the underlying mechanism must be identified.
Histopathologic studies of the vagus nerve ina patient with diabetes revealed a severe reduction in the density of unmyelinated axons and asmall caliber of the surviving axons" In patients with diabetic diarrhea, the sympatheticnervous system demonstrates giant sympatheticneurons, dendritic swelling of postganglionicneurons in prevertebral and paravertebral ganglia," and reduced fiber density in the splanchnic nerves.:" Although histologic studies of the
myenteric plexus in the gut of humans withdiabetes demonstrated no abnormalities.rv" thestreptozocin-treated rat had a reduction insympathetic fibers in the myenteric plexus."Studies in such rats also showed abnormal release of acetylcholine in response to administration of veratridine"? and abnormal release ofvasoactive intestinal polypeptide and calcitoningene-related peptide in response to electricalfield stimulation from myenteric plexus neurons.:" The same authors also noted selectivedamage of neurons that contained calcitoningene-related peptide in the myenteric plexus ofrats with diabetes." The abnormal voltagetension curves ofdiabetic gastric smooth musclestudied in vitro (Szurszewski JH: Unpublishedobservation) suggest an abnormality in neuralcontrol. The earlier report of hyaline bodies ofunknown origin in gut smooth muscle'" has notbeen confirmed by other groups.
Peripheral cholinergic agonists such as metoclopramide.r' bethanechol.v' and cisapride,"! aswell as agents that affect the adrenergic nervesupply to the gut such as the a 2-adrenergicagonist clonidine;" have been used to treat diabetic gut neuropathy. A complete understanding of the mechanism of these complications islacking, however, inasmuch as all availabletherapeutic options have resulted in only transient relief.43,44 Measures that reverse the metabolic derangement in diabetic nerves, such asaldose reductase inhibition.v" provide anotherapproach, one that may correct abnormal peripheral nerve conduction in short-term" andlong-term studies'" and increase the number ofregenerating myelinated fibers. 46,48 This strategy is clearly important because glucose controlalone does not substantially improve peripheralnerve function in patients with diabetes."
Amyloid Neuropathy.-Amyloid neuropathy may lead to diarrhea and steatorrhea.t" incontrast, some patients with amyloidosis haveinfiltration of gut smooth muscle and a lowamplitude pressure profile" that commonly leadsto a myopathic pseudo-obstruction or constipation.51-54 Patients with amyloid neuropathydemonstrate uncoordinated nonpropagatedphasic pressure bursts in the small bowel'" that
832 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES
Fasting Fed
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Antroduodenum, 1 ,
2
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dll' ,,,11
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Fig. 4. Classic abnormalities in manometric profile of diabetic gut dysmotility. Positionof manometric ports as in Figure 1. Note absence (leads 1 through 5) of antral componentof fasting interdigestive motor complex and abnormal propagation of activity front (phaseIII) through proximal small bowel (retrograde propagation between leads 6 and 7). Inpostprandial period, frequency of antral contractions is reduced, phasic and tonicpressure activity is prominent at level of pylorus, and meal fails to inhibit interdigestivemotor complex. (From Colemont LJ, Camilleri M: Chronic intestinal pseudo-obstruction:diagnosis and treatment. Mayo Clin Proc 64:60-70, 1989.)
are similar to the intestinal myoelectric disturbances in animals that have been subjected toganglionectomy.56 Familial amyloidosis mayalso affect the gut.51-59 Severe reduction innumber or degeneration of ganglion cells occurswithout extensive deposition of amyloid in theenteric plexus in familial cases.'" the mechanism of this degenerative process is unclear.
Manometric studies and monitoring of theacute effects of cholinomimetic agents'" candistinguish between neuropathic (uncoordinatedbut normal-amplitude pressure activity) andmyopathic (low-amplitude phasic pressure activity) types of amyloid gastroenteropathy. 55
Such approaches may also indicate which patients should respond to cholinomimetic agents.
Chronic Autonomic Neuropathy WithNeuronal Intranuclear Inclusions.-A rarefamilial, autosomal recessive disorder known as
chronic autonomic neuropathy with neuronalintranuclear inclusions''? can be associated withgut dysmotility. Some patients have autonomicdysfunction that affects the eyes, sweat glands,and heart. Other patients have impaired spinocerebellar function and, less commonly, extrapyramidal features. The 3- to Itl-um-diameterprotein intranuclear inclusions occur in themyenteric plexus and various other regions inthe nervous system." Thus, the same diseaseprocess may affect the neural control of gut motility at more than one level; identification of alesion ofthe myenteric plexus does not exclude aconcomitant disorder of the extrinsic pathways.
Chronic Sensory and Autonomic Neuropathy of Unknown Cause.-A nonfamilialform of slowly progressive neuropathy affectingvarious autonomic functions has recently beenreported." A sensory neuropathy also devel-
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oped in this patient after about 20 years. Duringlife, abnormalities of the postganglionic sympathetic and parasympathetic systems were detected; at postmortem examination, degenerative changes were detected in the posterior roots,dorsal columns of the spinal cord, peripheralnerves, sympathetic trunk, vagal nerve, andmyenteric plexus. In contrast, neurons in theintermediolateral columns of the spinal cordwere preserved. Patients may have only a chronicautonomic disturbance present for many yearsas a gastrointestinal dysfunction before involvement ofthe sensory nerves becomes apparent orin the absence of peripheral nerve dysfunction. 62In most patients, however, cardiovascular orsweating abnormalities precede involvement ofthe gut.5 5
Other investigators have reported familialcases of intestinal pseudo-obstruction with degeneration ofthe myenteric plexus and evidenceof sensory or motor neuropathies (or both) affecting peripheral or cranial nerves.63,64 The autonomic supply to other viscera was not assessedin these reports.
Neurofibromatosis.-VonRecklinghausen'sdisease affects the motor function of the gutpredominantly because of a lesion of the myenteric plexus'":"? rather than the usual neurofibromas along the nerves. It has been associatedwith megacolon, which may be congenital'" ormay occur in the early infantile period'" or laterin adult life. 67,68 More commonly, however,gastrointestinal tumors occur in these patients,and 10% of patients with von Recklinghausen'sdisease in a study at the Massachusetts GeneralHospital'" had pathologically proven gastrointestinal neurofibromatosis. In approximately7% of patients, neurofibromas or leiomyomaswere identified, most commonly in the jejunumand stomach. Gastrointestinal symptoms shouldlead to a search for a mass lesion in the gut beforethese symptoms are attributed to myentericplexiform neuropathy. Jejunal manometricstudies performed in one patient with this condition could not distinguish an intrinsic from anextrinsic gut neuropathy;" no signs of a masslesion or mechanical obstruction were evidenton small bowel roentgenography or manometry.
The histopathologic changes observed areangiomatosis.s" a plexiform pattern on the dendritic processes of the ganglion cells in themyenteric plexuses." and neuronal intestinaldysplasia." Whereas these reports confirm thederangement ofthe enteric nerves in neurofibromatosis, they provide no information on theextrinsic nerves that supply the gut. There is,however, some evidence that the latter may beaffected. In a patient with an achalasia-likedisorder of the esophagus due to neurofibromatosis,?? the lower (smooth muscle) portion of theesophagus was hypertrophic and contained fewganglion cells in the myenteric plexus, whereasmuscle atrophy of the proximal third of theesophagus was attributable to vagal perineuralfibrosis, findings that suggested an extrinsicneuropathy.
Paraneoplastic Neuropathy.-Autonomicneuropathy and gastrointestinal symptoms havebeen reported in association with carcinoma ofthe lung9,71.73 or pulmonary carcinoid. 73 In thelargest series (seven patients), all suffered constipation, six had gastroparesis, four had esophageal dysmotility suggestive of spasm or achalasia, and two had other evidence of autonomicneuropathy that affected bladder and bloodpressure control." Recently, my colleagues andI examined two patients with paraneoplasticintestinal pseudo-obstruction, both of whom hadsigns of cardiovagal or sympathetic dysfunction.:" In four patients described in the literature,9,74 results of manometric studies of theupper gastrointestinal tract were abnormal;treatment of a pulmonary tumor in one patientresulted in cessation ofnausea and vomiting andrestoration of the motility in the upper gut tonormal.9
Histologically, the myenteric plexus showeddegeneration and a decline in neurons and axons, inflammatory cell infiltration with lymphocytes and plasma cells, and glial cell proliferation. The submucous plexus was unaffected, andthe extrinsic nerves were not examined.?"
Drug-Induced Neuropathy.-Ileus causedby the alkaloid vincristine" is an example of adrug-induced neuropathy that affects motorfunction of the gut. The neuropathy is presum-
834 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES Mayo Clin Proc, June 1990, Vol 65
ably due to the effects ofthis agent on the peripheral nervous system, including autonomic nerves;however, direct toxic effects on the myentericplexus cannot be excluded. Among adrenergicagents that are used in clinical practice, thecentrally acting u2-agonist clonidine may inducereversible constipation and intestinal pseudoobstruction;" but it does not result in a chronicneuropathic process. Nevertheless, these medications may aggravate gastrointestinal symptoms in those patients (such as patients withdiabetes who have hypertension) who may require their concomitant use.
Autonomic System Degenerations. Pandysautonomia or Selective Dysautonomias.-Pandysautonomias are characterized bypreganglionic or postganglionic lesions in bothsympathetic and parasympathetic nerves.Gastrointestinal involvement, which is manifested as vomiting, paralytic ileus, constipation,or a pseudo-obstruction syndrome, has beenreported in acute,77-82 subacute." or congenital'"pandysautonomia. Motor disturbances of thegut have been substantiated in the esophagus(abnormal pressure in the lower esophagealsphincter, simultaneous contractions with swallowing, and multiple high-amplitude nonperistaltic contractions'"); the stomach (antral hypomotility in one patient); and the small bowel(bursts in the fasting and postprandial periodsin two patients'"), Four published reports78,81.83,86
have described patients with selective cholinergic dysfunction and disorders of gastrointestinalmotor activity.
Histologic studies ofthe gut have been limitedin these conditions. In a patient with pandysautonomia who had apparent achalasia of the distal esophagus, a biopsy specimen of the cardiataken during a Heller procedure showed apparently normal ganglia of the myenteric plexus.?'This study suggested that the lesion was extrinsic to the gut. Most other reports that includedmorphologic studies of peripheral nerves in thesesyndromes provided no description of the myenteric plexus or extrinsic nerves.
Failure of Muscarinic Cholinergic Receptors.-Bannister and Hoyes"? described apatient with constipation, recurrent small bowel
pseudo-obstruction, delayed gastric emptying,and a dilated duodenal loop. The number ofganglion cells in a rectal biopsy specimen andthe perikaryon and dendrites of neurons in thesubmucous and myenteric plexuses were normal. The unique feature of this case was theabsence ofany response ordenervation hypersensitivity response to exogenously administeredcholinergic agonists or anticholinesterase drugs.Because the morphologic features ofthe smoothmuscle itself were also normal, the authorspostulated a postjunctional defect ofthe muscarinic receptor, but no confirmatory in vitro studies were performed.
Idiopathic Orthostatic Hypotension.Idiopathic orthostatic hypotension is sometimesassociated with motor dysfunction of the gut,such as alteration in bowel movements and fecalincontinence.s" Cardiovascular and sudomotorabnormalities usually precede gut involvement.My colleagues and I observed similar alterationsin bowel movements, heartburn, abdominal pain,and weight loss in three patients with idiopathicorthostatic hypotension.55 One of our patientsalso had postprandial antral hypomotility,whereas phasic pressure bursts in the smallbowel were observed during fasting in two ofthese three patients. More recently, other investigators have reported altered esophageal motility and gastric emptying in patients with idiopathic orthostatic hypotension.t" The preciselevel of the lesion along the neural axis and theappearance of the neurons of the myentericplexus are unknown.
Shy-Drager Syndrome.-The Shy-Dragersyndrome is discussed subsequently in the section on extrapyramidal disease.
Conditions of the Spinal Cord. SpinalCord Injury.-During the acute phase afterspinal cord injury, ileus is a frequent finding, butit is rarely prolonged." Fealey and associates'"studied patients in whom gut function had beenrecovered subsequent to the initial ileus afterspinal cord injury. They identified only minorabnormalities in the interdigestive antral motility; postcibal pressure activity in the distal partof the stomach and the proximal aspect of thesmall bowel was normal. Thus, impaired gastric
Mayo Clin Proc, June 1990, Vol 65 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES 835
emptying is unusual in such patients,90,92 andthe improvement ingastric emptyingin responseto metoclopramide'" suggests neuronal ratherthan muscle dysfunction as the cause of transitdelays.
The single report that gallstone disease ismore prevalent in patients with spinal cordinjury than in control subjects" necessitatesconfirmation. This complication may be theconsequence of either abnormal motility of thegallbladder or decreased enterohepatic cyclingof bile acids as a result of slow small boweltransit.l"
In contrast to the rarity of motor disorders ofthe upper gut after spinal cord injury, disturbances in colonic and anorectal function arecommon, probably as a result of interruption ofsupraspinal control of the sacral parasympathetic outflow. Thus, reports have described adecrease in colonic compliance'v-" and an absence of postprandial colonic motor and myoelectric activity94,96 in several patients with thoracicspinal cord injury. The entire large bowel transit may be affected in patients with paraplegia.??possibly because of slow transit throughout thecolon or obstruction of the distal aspect of thecolon due to an abnormal parasympathetic supply. Dysfunction of the anorectal sphincter iscommon and distressing." Recent work withneuroprosthetic stimulation of the sacral anterior roots may pave the way for normalizing thepelvic colon and anorectal sphincter mechanismin these patients."
In summary, spinal cord injury has moredevastating effects on the distal part ofthe bowelthan on the foregut or midgut, which may bespared because of the preservation of vagalnerve function. The effect of spinal cord injuryon the morphologic features or in vitro functionof myenteric plexus neurons in the gut has notbeen reported.
Multiple Sc1erosis.-Severe constipation isa frequent accompaniment of urinary bladderdysfunction in patients with advanced multiplesclerosis. Excessive increases in intracolonicpressure occur in response to a volume stimulusin patients with multiple sclerosis in comparison with responses in healthy control subjects;"
this response is similar to detrusor hyperreflexia, a common cystometric disturbance insuch patients. Some patients fail to have increased postprandial colonic motor and myoelectric activity, in contrast to the responses seen inhealthy control subjects.?? In one study, colonictransit of radiopaque markers was prolonged in14 of 16 patients with multiple sclerosis andurinary bladder involvement.l''? In that series,10 patients also had evidence of fecal incontinence, and 5 had spontaneous rectal contractions. The studies performed to date have notbeen sufficiently detailed to assess the relativecontributions of the sympathetic and parasympathetic nervous systems. Nonetheless, pelviccolon dysfunction is more likely due to impairedfunction of the supraspinal centers or descending pathways that control the sacral parasympathetic outflow. Further studies need to addressthe mechanism of impaired gut transit in multiple sclerosis, which, as with spinal cord injury,results in motility disturbances more frequentlyin the lower than in the upper gut.
Diseases of the Brain. ExtrapyramidalDisease.-Patients with parkinsonism areknown to have delayed gastric emptying that isaggravated by treatment with levodopa.''" Inthe original description of the Shy-Drager syndrome.l'" constipation and fecal incontinencewere included among the classic features ofthedisorder. One patient with the Shy-Dragersyndrome had substantial reduction in fastingand postprandial antral and small bowel pressure activity." Abnormalities in esophagealmotility were also evidenced by cineradiographyand by frequent simultaneous low-amplitudeperistaltic waves during esophageal manometryin two patients with the Shy-Drager syndromeand cholinergic dysfunction.l'" Megacolon anddilatation of the small bowel have been recognized in patients with parkinsonism.Pvl'" rarely,colonic dilatation may lead to sigmoid volvuIUS. l06,107 Constipation is common in patientswith parkinsonism, and determining the relative contributions of gut hypomotility, generalized hypokinesia, and the effects of variousanticholinergic and dopamine agonist medications to the cause of this symptom is difficult.
836 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES Mayo Clin Proc, June 1990, Vol 65
The bioavailability of medications can be considerably altered by these effects on gut transit.
Apart from the degenerative changes in central structures, recent reports have suggestedthat degenerative changes and Lewy inclusionbodies are present in myenteric plexus ganglioncells in the esophagus-?" and the colon.108,109
Esophageal malfunction has been reported ina patient with Wilson's disease who had dysphagia.'!? Parkinsonian features and choreoathetosis may occur in neuronal intranuclearinclusion disease.v?
Epilepsy.-Visceral autonomic epilepsy mayoccur in conjunction with nausea and vomiting,which may not be associated with obvious alteration of consciousness.UlU" Recently, Peppercorn-" described 10 female adults with abdominal pain, nausea, bloating or diarrhea,neurologic symptoms, sleep electroencephalographic abnormalities, and prompt and nearlycomplete resolution with anticonvulsants. Assessment of gastrointestinal motor functionconcomitantly with electroencephalography insuch patients with evidence of visceral epilepsyhas not been performed to date; hence, the relationship between the abnormal brain dischargesand their effect on gut motility remains unknown.
Brain-Stern Lesions.-The association ofbrain-stem lesions and symptoms of upper orlower gut dysfunction has been established formany years. Recent reports have described themotility ofthe gut in patients with such lesions.For example, my colleagues and p16reported theabnormal velocity of propagation of an interdigestive migrating motor complex and abnormalpostprandial motility in the upper gut in a patient with a medullary astrocytoma. Whetherthis motor dysfunction of the gut is due to mechanical stimulation of the vomiting center inthe area postrema.l!" a disturbance of neuralconnections.P" or chemical activation of theemetic chemoreceptor trigger zone by an endogenous substance-!? is uncertain.
Brain-stem strokes have also been associatedwith small bowel or colonic pseudo-obstruction,55,120 colonic inertia, and esophageal incoordination.':" Moreover, some patients have an
inability to perceive rectal distention and lackthe rectoanal inhibitory reflex. 121
GENERALIZED MUSCLE DISORDERSCAUSING GUT DYSMOTILITYAs in the material on disease of neural control,muscle disorders that selectively affect the gutwithout systemic involvement will not be discussed herein.
Amyloidosis.-As previously emphasized,amyloidosis may result in gut dysmotility byinfiltration ofthe muscle layers; the presence ofsuch a myopathy can be confirmed by manometric studies."
Systemic Sclerosis.-Systemic sclerosis isfrequently associated with symptoms of gastrointestinal motor dysfunction. Whereas esophageal involvement is most commonly identified inclinical practice, some evidence has shown thatanorectal involvement is just as common. 122Cohen and co-workers123-125 suggested a twostage process in the natural history of the motility disorder ofthe gut: (1) a neuropathic processinitially and (2) a myopathic disturbance subsequently (Fig. 5) as a result of infiltration of themuscle layers with fibrous tissue. The originalobservations that suggested an early neuropathic process in the esophagus and anorectalregion have recently been confirmed in the smallintestine. Thus, uncoordinated fasting and postprandial phasic pressure bursts associated withtonic elevation of baseline pressure in the smallintestine'P" in a minority of patients withscleroderma who have gastrointestinal features suggest an initial neuropathic disturbance. Otherinvestigators have substantiated the lack ofcyclicinterdigestive motility in patients with systemicsclerosis. 127,128 The histopathologic findings ingut muscle in this disorder have been well characterized and may be distinguishable from thoseof familial hollow visceral myopathy. 129 Morerecent studies have suggested, however, that itmay not always be possible to distinguish thehistologic appearances from those of sporadichollow visceral myopathy. 130 Further studies onthe myenteric plexus are awaited.
Dermatomyositis.-Motor disturbances ofthe gut have been a well-recognized, although
Mayo Clin Proc, June 1990, Vol 65 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES 837
Systemic sclerosis Control
Antroduodenum
Descending duodenum
Distal duodenum
Proximal jejunum
,I Jl~
2J50 mm Hg
5 min
• "" oIIIi l, ...... L-W ,' ... ',,Ilj,l .....
,. .. .....,J",o .,
Fig. 5. Manometric profile of myopathic pseudo-obstruction due to systemic sclerosis:note low amplitude of phasic pressure activity (contractions) at antral, duodenal, andjejunal levels in comparison with amplitude of contractions in a healthy control subject.(From Greydanus and Camilleri.P" By permission ofthe American GastroenterologicalAssociation.)
rare, feature of dermatomyositis. 131 Esophagealsymptoms occur more commonly than symptoms suggestive of gastric stasis.v" and investigators have found evidence of delayed transit ofsolids in the esophagus and of both solids andliquids in the stomach.P! The impairment ofpropulsive activity of the upper gut correlateswith the weakness of skeletal muscle groups. 133
Morphologic abnormalities ofgut smooth muscleare rarely seen.P" and dysphagia most likelyresults predominantly from skeletal muscleinvolvement.
Dystrophia Myotonica.-Various studieshave found abnormal muscle function at virtually all levels of the gastrointestinal tract inpatients with dystrophia myotonica, from thepharynx to the anal sphincters.Ps'<' The studyby Lewis and Daniel':" demonstrated increasedduodenal contractions in association with variability of the maximal rate of contractions, andthese authors postulated that these effects resultedfrom smooth muscle damage, which causedpartial depolarization. In one patient, my col-
leagues and I noted increased tonic and phasicpressure activity in the proximal jejunum during fasting. 9 Enhancing cholinergic transmission with the anticholinesterase edrophoniumdid not result in antral stimulation;139 hence, themechanism for the beneficial effect of metoclopramide on emptying of solids from the stomach138 is unclear.
The degenerative changes in small intestinaland colonic smooth muscle with fatty infiltrationand collagen formation among smooth musclecells are similar to those observed in dystrophicskeletal muscle.t'" In one study, degenerativechanges were noted in the myenteric plexus,whereas gut smooth muscle was histologicallynormal. 142 Recent immunohistochemical studies disclosed a decrease of substance P andenkephalin-immunoreactive fibers in the muscularis externa.':"
Congenital myotonic dystrophy may similarlyaffect gut smooth muscle function and result ingastroparesis.t'" subacute obstruction, megacolon, and constipation in children of patients
838 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES Mayo Clin Proc, June 1990, Vol 65
Table 2.-Components in the Evaluation forExtrinsic Neurologic Disease in Patients With
Gastrointestinal Motor Dysfunction
confirm a substantial disturbance in the motorfunction of the gut and to distinguish betweenneuropathic and myopathic disorders." Thus,neuropathic conditions usually present a picture of uncoordinated but normal-amplitudephasic pressure peaks, whereas myopathic conditions show considerably reduced amplitude ofcontractions in the affected regions on manometry. Such studies, however, generally do notallow the distinction between intrinsic (myenteric plexus) and extrinsic neuropathies. Indirect tests ofautonomic function (Table 2; Appen-
with dystrophia myotonica.v" Gastrointestinalinvolvement has been recorded in other rarevariants of muscular dystrophies, includingoculogastrointestinal and Duchenne musculardystrophy. 145,146
Mitochondrial Myopathy.-A single case ofchronic intestinal pseudo-obstruction due tomitochondrial myopathy was recently reported.!" This patient also had ophthalmoplegia (restriction of ocular movements to a fewdegrees in all directions, slight ptosis, andmyopia), hearing loss, generalized muscle atrophy, and, in the gut, absence of esophagealperistalsis, delayed gastric emptying, and dilatation of the duodenum and small intestine.No details on gastrointestinal smooth musclewere provided in the report ofthis unusual case.
IDENTIFICATION OF EXTRINSICNEUROLOGIC DISEASE INPATIENTS WITH FUNCTIONALGASTROINTESTINAL SYMPTOMSClearly, patients with lesions at virtually anylevel ofthe nervous system may have symptomsof gastrointestinal motor dysfunction. Becausefunctional gastrointestinal disorders are by farthe most commonly seen conditions in gastroenterologic practice.l'" it is necessary to develop astrategy to identify those in whom such a neurologic disturbance may be present, and this strategy is only part of the diagnostic evaluation ofdisordered gastrointestinal function and itscause.v" Patients should undergo further testing if they have clinical features suggestive ofautonomic or peripheral nerve dysfunction, suchas orthostatic dizziness, sweating abnormalities, repeated bladder infections, paroxysmaltachycardia, or paresthesia.
The first steps are elicitation of the historyand performance of a physical examination(Table 2) to identify any evidence of a generalized neurologic disorder. The physician shouldthoroughly evaluate all systems and inquireabout past history and family history. It isessential to record the use of any medicationsthat may influence gut motility.
Gastrointestinal motility and transit measurements help the clinician to identify or to
Component
History
Medications
Past history
Family history
Examination
Studies
Specific features
Postural dizziness, control ofblood pressure
Disturbances of visionSweatingUrinary disturbances or infectionsSensory or motor deficits
Calcium channel blockers,anticholinergic agents, antiarrhythmic drugs, antipsychoticagents, antihypertensive agents
Diabetes mellitus, spinal cordinjury
Amyloidosis, other neuropathy
Blood pressure and pulse (withpatient supine and standing)
Pupils (size, reaction to light)Cranial nervesSensationMotor function
Gastrointestinal manometry (±)RR interval (electrocardiographic)
responses to Valsalva maneuverand pulse rate variation (oscillation) with deep breathing
Pupillary responses to 0.1% epinephrine,0.125% pilocarpine,5% cocaine drops
Thermoregulatory sweat testQuantitative sudomotor axon
reflex test (to iontophoresedacetylcholine)
Blood pressure and plasmanorepinephrine (with patientsupine and standing)
Screen for peripheral neuropathyMagnetic resonace imaging of the
brain
Mayo CUn Proc, June 1990, Vol 65 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES 839
dix) are exceedingly useful for identifying thepresence of other visceral denervation. 150-153 Theclose concordance of abdominal vagal dysfunction with cardiovagal neuropathy in patientswith diabetes'>' suggests that these tests mayprovide a realistic evaluation ofthe overall function of autonomic supply to the viscera, including the gastrointestinal tract.
Once a defect ofthe sympathetic nervous system has been identified, the effect of intravenousadministration of edrophonium on norepinephrine levels may provide a further assessment ofthe integrity of postganglionic sympatheticnerves. 155 ,156 Similarly, dysfunction of the vagusnerve identified by cardiac reflexes may be further assessed by means of the plasma pancreaticpolypeptide response to either sham feeding orhypoglycemia. 157 This test, however, is rarelynecessary in clinical practice because cardiacautonomic responses are easier and less expensive to determine and are sensitive indicators ofautonomic dysfunction of abdominal viscera. 154
Screening of a patient with visceral autonomic neuropathy must include tests that identify occult causes of a peripheral neuropathy,such as lung tumors or amyloidosis. In thosepatients with autonomic disturbance of visceraother than abdominal organs, imaging of thebrain becomes essential, particularly when thesupine plasma norepinephrine levels and theirresponse to administration of edrophonium arenormal, findings that suggest normal function ofpostganglionic fibers. In our experience, magnetic resonance imaging has been preferable, 116
particularly for demonstrating lesions in thebrain stem.
CONCLUSIONThe recent surge of interest in gastrointestinalmotility and the availability of techniques thatprovide a better evaluation of gastrointestinalmotor function have necessitated broader collaborations between gastroenterologists andneurologists. The gastrointestinal tract is animportant component ofthe area supplied by theautonomic nervous system and may be involvedin systemic disorders that affect other musclesystems. In a few patients with functional gas-
trointestinal symptoms, identification of a specific neurologic disorder will be possible. Thisdisorder may be at any level of the extrinsicneural control of the gut, from the brain to thepostganglionic fibers, the enteric nervous system, or the smooth muscle itself. These considerations emphasize the importance of the interaction between the neural axis and the gut andshould provide a framework for the investigation of operative mechanisms in patients withmotor disorders of the gut.
ACKNOWLEDGMENTI thank Dr. Sidney F. Phillips for helpful discussions in the preparation ofthis work; Drs. RobertD. Fealey and Phillip A. Low ofthe DepartmentofNeurology for stimulating my interest and forpermission to use normal data for autonomicfunction tests developed in their respective laboratories; and Cynthia L. Stanislav and Linda J.Bakken for excellent secretarial assistance.
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APPENDIX
SUMMARY OF COMMON AUTONOMICFUNCTION TESTSPupillaryFunction Tests.-Responses to lightand accommodation assess the parasympatheticsupply (Appendix Table 1); dilatation in dimlight assesses the sympathetic supply. Dropsare instilled to search for signs of denervationhypersensitivity of the pupillary muscles: (1)dilute (0.125%) pilocarpine (an alkaloid thatacts directly on end-organs affected by acetylcholine) induction of pupillary constrictionimplies parasympathetic denervation; (2) 0.1%epinephrine (direct stimulant of a-adrenergicreceptors) induction of pupillary dilatation indicates a postganglionic sympathetic lesion. Instillation of 4 to 5% cocaine drops blocks uptakeof norepinephrine by the nerve ending and indirectly dilates the pupil. No such dilatationoccurs if impulses do not reach the sympatheticnerve endings because of a preganglionic or apostganglionic lesion.
Cardiovascular Tests. Orthostatic Hypotension.-In response to an 80° tilt, a decline insystolic or diastolic pressure without a compensatory increase in pulse rate indicates sympathetic dysfunction.
Heart Period Responses to Deep Breathing.-Inflation and deflation ofthe lungs stimulate vagal afferents that reflexly change thepulse rate through vagal efferents. Thus, reductions in pulse rate occur with inspiration, and increases accompany expiration. This pulse ratevariation (oscillation) is related to the age of thepatient; if oscillations are impaired, they indicate vagal dysfunction.
Valsalva Maneuver.-Forced expirationagainst a closed glottis is achieved by maintaining pressure in a sphygmomanometer at 40 to 50mm Hg for 15 to 20 seconds by blowing into thesphygmomanometer. This maneuver results ina complex series of changes in pulse rate andblood pressure involving both vagal and sympa-
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Appendix Table I.-Interpretation of Results of Autonomic Function Tests
Abnormal resultTest of Normal implies
autonomic function value dysfunction of:
Pupillary testsResponse to light
LatencyConstriction
Pharmacologic tests0.125% pilocarpine0.1% epinephrine
5% cocaine
Blood pressure reduction on tilt to 80°SystolicDiastolic
Valsalva ratio
Pulse rate change with deep breathing
Thermoregulatory sweat test% surface area of anhidrosis
Quantitative sudomotor axon reflex testSweat output (ul/cm'')
Forearm
Foot
Latency (min)Forearm
Foot
Plasma norepinephrinePatient supine
Patient standing
Response to intravenous administrationof edrophonium
0.2-0.3 s2-4mm
0-0.5-mm constrictionNo change
>1.5-mm dilatation
<25mmHg<15mmHg
>1.5
Age related, 6-18 beats/min
M: O%;F: <3%
M: 0.76-5.51F: 0.34-1.33M: 0.92-5.73F: 0.25-1.95
M: 1-2.4F: 0.9-1.9M: 1-2.7F: 1-2.8
70-750 pg/ml
200-1,700 pg/ml
>35% increase abovebaseline within 2-8 min
ParasympatheticParasympathetic
ParasympatheticPostganglionic,
sympatheticSympathetic
SympatheticSympathetic
Sympathetic orparasympathetic
Parasympathetic
Sympathetic
Postganglionic,sympathetic
Postganglionic,sympathetic
Sympathetic
Postganglionic,sympathetic
thetic responses. In autonomic dysfunction, thephase IV responses of blood pressure overshootand compensatorybradycardia are typically lost.A useful index is the Valsalva ratio, which compares the longest (usually in phase IV) andshortest (usually in phase II) RR intervalsmeasured on the electrocardiogram during andafter the Valsalva maneuver. A reduced indexindicates autonomic dysfunction.
Sweat Tests. Thermoregulatory SweatTest.-Mter being covered with alizarin redpowder, the patient is exposed to an environ-
ment of 44 to 50°C and 40 to 50% relativehumidity for up to 30 minutes. An increase incore body temperature of 1°C is required. Thepercentage surface area of anhidrosis is determined and indicates sympathetic (preganglionicor postganglionic) dysfunction.
Quantitative Sudomotor Axon ReflexTest.-A sweat capsule assesses the latency between stimulation and appearance of sweat andthe output of sweat in the upper and lower limbsin response to iontophoresed 10% acetylcholinesolution. This transmitter is charged and enters
846 GASTROINTESTINAL MOTILITY AND NEUROLOGIC DISEASES Mayo elin Proc, June 1990, Vol 65
the skin in response to the application of a weakelectric current (2 rnAfor 10 minutes). The acetylcholine results in antidromic stimulation ofthe postganglionic sympathetic fiber, which, inturn, orthodromically stimulates a sweat gland.A delay or lack of output of sweat implies apostganglionic sympathetic lesion.
Plasma Norepinephrine.-A low plasmanorepinephrine concentration with the patientsupine suggests a postganglionic sympatheticlesion. Failure of the plasma norepinephrine
level to increase when the patient stands suggests either a preganglionic or a postganglionicdisturbance.
Intravenous administration of edrophoniumproduces a transient amplification ofendogenouscholinergic activity in the sympathetic gangliaby rapid inhibition of acetylcholinesterase. Theresult is a rapid release of norepinephrine intothe plasma from the postganglionic sympatheticfibers. Thus, this test assesses the integrity ofthe postganglionic sympathetic fibers.