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CLINICIAN UPDATE Pathophysiology and Management of Patients With Chest Pain and Normal Coronary Arteriograms (Cardiac Syndrome X) Juan Carlos Kaski, MD, DSc Downloaded from http://circ.ahajournals.org/ by guest on June 18, 2017 P atients with cardiac syndrome X (CSX)—typical chest pain and electrocardiographic changes suggestive of myocardial ischemia despite normal coronary arteriograms–represent a diagnostic and therapeutic riddle. CSX is not associated with an increased mortality or an increased risk of cardiovascular events, but it often severely impairs quality of life and represents a substantial cost burden to the healthcare system. This syndrome of chest pain with normal coronary arteries encompasses a variety of pathogenic subgroups and is predominantly seen in postmenopausal women. Lack of understanding of the syndrome by the cardiovascular physician not infrequently results in discounting the clinical problem. Treatment remains elusive, but management strategies can improve the patient’s quality of life and reduce the financial burden imposed on health services. Case Report: A 55-year-old white female pharmacist underwent diagnostic coronary arteriography for the assessment of typical exertional chest pain, which had started 18 months previously and had gradually become more frequent and severe despite treatment with oral and sublingual nitrates and atenolol (50 mg daily). Central chest pain and dyspnea occurred at rest and with emotional stress and responded rather poorly to sublingual nitrate administration. ECG exercise stress test was positive (Figure 1), and transient perfusion defects were found on thallium-201 dipyridamole testing (Figure 2). She had long-lasting excruciating chest pain after dipyridamole infusion. Risk factors included a family history of coronary artery disease, a lowdensity lipoprotein-cholesterol level of 4.2 mmol/L, a high-density lipoproteincholesterol level 0.9 mmol/L, menopausal status, a previous history of smoking, body-mass index of 28 kg/m2, and raised high-sensitivity C-reactive protein levels (3.8 mg/L). Coronary arteries and left ventricular function were completely normal. Coronary intravascular ultrasound showed no significant subangiographic disease. After reassurance by her cardiologist, all cardiac medications were discontinued. Symptoms continued to deteriorate over the ensuing months, however, to the point that she was unable to work and required help with her supermarket shopping and household tasks. She was referred to our CSX clinic for treatment. Esophageal manometry and pH measurements showed 4 asymptomatic episodes of gastroesophageal reflux without associated ECG changes. Specialist psychological assessment revealed no abnormalities. Coronary artery spasm and musculoskeletal conditions were ruled out as the cause of her symptoms. Transient ST-segment depression and chest pain detected during ambulatory monitoring were usually associated with tachycardia (Figure 3). It was noted that 20% of the episodes of ST-segment depression occurred with a heart rate ⬍80 bpm. Brachial artery flow-mediated dilatation was reduced to 1.3%, indicating systemic endothelial dysfunction. Dobutamine stressechocardiogram showed no regional wall motion abnormalities despite the occurrence of ST-segment depression and chest pain. Treatment was initiated with diltiazem 360 mg daily, simvastatin 40 mg daily, imipramine 50 mg daily, and sublingual nitrates. An exercise program was devised for this patient, and she received advice regarding diet and lifestyle changes. The patient decided against estrogen replacement therapy. Clinical Results: Symptoms improved significantly over an 8-month period and the patient was able to return to work. Improvements were observed in body mass index (23 kg/m2), high-density lipoprotein-cho- From the Coronary Artery Disease Research Unit, Cardiological Sciences, St George’s Hospital Medical School, London, UK. Correspondence to Prof J.C. Kaski, Head, Cardiological Sciences, Director, Coronary Artery Disease Research Unit, Department of Cardiovascular Medicine, St George’s Hospital Medical School, Cranmer Terrace, London SW17 0RE, United Kingdom. E-mail [email protected] (Circulation. 2004;109:568-572.) © 2004 American Heart Association, Inc. Circulation is available at http://www.circulationaha.org DOI: 10.1161/01.CIR.0000116601.58103.62 568 Kaski Downloaded from http://circ.ahajournals.org/ by guest on June 18, 2017 Figure 1. Positive exercise stress test response with horizontal ST-segment depression associated with typical central chest pain. Chest pain subsided gradually after exercise (some chest discomfort persisted for 12 minutes), and ST-segment depression returned to baseline levels within 5 minutes. lesterol level (1.3 mmol/L), lowdensity lipoprotein-cholesterol level (2.8 mmol/L), and flow-mediated dilatation (4.2%). Exercise test was borderline positive, with up-sloping ST-segment depression but without chest pain (peak heart rate 158 bpm, peak blood pressure 180/88 mm Hg; stage 4 Bruce protocol). Background Although patients with typical exertional chest pain and positive exercise tests usually have obstructive coronary artery disease, particularly when risk factors are present, approximately 20% of these patients have normal coronary arteriograms.1 These individuals are considered to have CSX, for which there is no universally accepted defini- Cardiac Syndrome X 569 tion. Most cardiologists agree that, in addition to typical chest pain and ECG changes (or other evidence of a cardiac involvement such as myocardial perfusion abnormalities), the coronary angiogram should be completely normal.1,2 Even this stringent angiographic criterion has limitations, as coronary arteriography provides no information regarding early atherosclerotic events within the arterial wall. Patients with systemic hypertension, left ventricular hypertrophy, and diabetes mellitus are excluded from CSX, as it is assumed that the cause for their angina is known. Consideration whether or not such exclusions are justifiable is beyond the scope of this manuscript. Patients with coronary artery spasm and those with objectively documented extracardiac causes for the pain (such as chest wall syndrome, psychological disturbances, and esophageal spasm) are also excluded.1 Despite intense investigation over the past 30 years regarding the pathogenesis of CSX, many fundamental questions remain unanswered. Among these, the following feature prominently: (1) Is the chest pain cardiac in origin?; (2) Is it caused by myocardial ischemia?; (3) Are other mechanisms involved?; and (4) What are the respective roles of microvascular dysfunction and reduced pain threshold? Pathogenesis Coronary Microvascular Dysfunction (Microvascular Angina) Figure 2. Short and long axis 201-thallium scintigraphy images showing transient perfusion defects in the septal region of the left ventricle after dipyridamole infusion. Excruciating chest pain and ST-segment changes suggestive of myocardial ischemia were observed immediately after dipyridamole. Microvascular angina (reduced coronary microvascular dilatory responses and increased coronary resistance)3 has been consistently found in CSX patients and suggested as a cause for regional myocardial blood flow abnormalities and heterogeneous myocardial perfusion. Endothelial dysfunction, with reduced bioavailability of endogenous NO and increased plasma levels of endothelin-1 (ET-1), may explain the abnormal behavior of the coronary microvasculature in CSX.4 – 6 Transient myocardial perfusion defects have been reported in areas supplied by 570 Circulation February 10, 2004 Downloaded from http://circ.ahajournals.org/ by guest on June 18, 2017 Figure 3. Continuous 2-channel ambulatory ECG monitoring during the patient’s daily activities. Episodes of typical transient ST-segment depression were observed during monitoring and were commonly associated with increased heart rate and chest pain. Episodes of chest pain usually lasted longer than episodes of ST-segment depression. arteries showing endothelial dysfunction4 and increased levels of ET-1 correlated with impaired coronary microvascular dilator responses in patients with chest pain and normal coronary arteries.7 Moreover, a lower NO/ET-1 ratio has been found in CSX patients compared with control subjects.8 Endothelial dysfunction in CSX appears to be multifactorial and linked to risk factors such as smoking, obesity, hypercholesterolemia, and inflammation.1 High plasma C-reactive protein levels, a marker of inflammation, have been shown to correlate with disease activity9 and endothelial dysfunction. CSX patients with multiple risk factors often have subangiographic coronary atheroma that may further impair endothelial function. Insulin resistance has also been suggested to have a major pathogenic role.10 Given the high prevalence (approximately 70% in most series) of postmenopausal women in the CSX population, estrogen deficiency has been suggested as a pathogenic agent acting via endothelium-dependent and endotheliumindependent mechanisms.11 Impaired endothelial function in postmenopausal CSX patients is improved by the administration of 17-estradiol.11 ischemia could be its pathogenic mechanism. However, this mechanism has proven elusive, as ischemia is objectively documented in only a minority (approximately 25%) of patients.1,2 Evidence of myocardial ischemia in these patients derives from myocardial perfusion studies, from investigations using metabolic markers such as myocardial lactate and isoprostane production, and from coronary sinus blood oxygen and pH changes. Studies using myocardial-perfusion MRI12 and 31Phosphorus nuclear magnetic resonance13 have provided fresh evidence for myocardial ischemia in CSX patients. Because many authors question the role of myocardial ischemia in CSX based on its good prognosis, the poor response to nitrates in many cases, the normal results of stress echocardiography, and the absence of objective markers of ischemia in many CSX patients, non-ischemic mechanisms have been proposed to explain the occurrence of CSX, including autonomic nervous system dysfunction14,15 and increased pain perception.16 Negative findings regarding ischemia, however, may be due to dilution of study groups by subjects with non-cardiac chest pain and to poor sensitivity of diagnostic techniques. Myocardial Ischemia Abnormal Pain Perception From the initial description of CSX, it has been speculated that myocardial Increased pain perception is common in patients with CSX, but the reason Figure 4. Interrelations between chest pain and microvascular dysfunction are important in the pathogenesis of CSX and are likely to determine the patient’s clinical presentation. A given patient with markedly increased pain sensitivity (y axis, arbitrary severity scale 1 to 10) may develop chest pain in response to algogenic cardiac (and probably also non-cardiac) stimuli even in the absence of major coronary microvascular dysfunction or myocardial ischemia. Adenosine and potassium release have been suggested to cause chest pain and ECG changes in CSX patients. Endothelin-1 and the autonomic nervous system modulate pain threshold. Patients with both marked microvascular dysfunction (x axis) and reduced pain threshold will be highly symptomatic and are also likely to have objective evidence of myocardial ischemia. Patients with intermediate degrees of chest pain sensitivity and microvascular dysfunction may have no ischemia or this may be undetectable; the latter depending on the sensitivity of the diagnostic tools employed for investigation and the severity and location of ischemia. Variable interactions between pain threshold and microvascular dysfunction can explain the heterogeneous pathogenesis of CSX. Both pain threshold and microvascular dysfunction have ample gradation spectra regarding severity and are also modulated by factors such as endothelial dysfunction, inflammation, autonomic influences, and psychological mechanisms, among others. remains elusive. Potassium and adenosine release, as well as abnormalities in the central modulation of pain perception, have been suggested to play a role.16 Greater and more extensive cortical activation, particularly of the right insula, suggesting abnormal handling of afferent stimuli by the central nervous system is seen in CSX patients as compared with controls.16 CSX patients may thus have an ineffective thalamic gate that would allow inadequate cortical activation by afferent stimuli from the heart, resulting in increased pain perception16. Auto- Kaski Cardiac Syndrome X 571 nomic nervous system imbalance with increased adrenergic activity and impaired parasympathetic tone could explain both increased pain sensitivity and endothelial dysfunction.14 –16 Possible interactions between pain threshold and microvascular dysfunction in CSX are presented in Figure 4. Psychiatric Morbidity Downloaded from http://circ.ahajournals.org/ by guest on June 18, 2017 CSX patients have high rates of psychiatric morbidity17; approximately 30% have a treatable psychiatric disorder and another 30% have psychological problems, factors that probably contribute to the continuing symptoms characteristic of the condition. Psychiatric morbidity varies in different series depending on the referral sources of these patients and may, particularly in anxiety disorders, be secondary to inappropriate reassurance about often disabling cardiovascular symptoms, uncertainty as to the nature of the condition, and failure of conventional treatments to improve quality of life. Prognosis and Management With the exception of patients who present with left bundle branch block and subjects with microvascular angina secondary to serious systemic diseases (such as amyloidosis or myeloma), prognosis is good regarding survival and left ventricular function in patients with CSX.1,2 Quality of life, however, is poor in a large proportion of CSX patients. Treatment is a challenging and often frustrating exercise for both patients and physicians. Kaski and Valenzuela Garcia18 have reviewed treatment options available for CSX, and American Heart Association/American College of Cardiology treatment guidelines are available for management of CSX in the context of the acute coronary syndrome.19 Successful management usually depends on identifying the prevailing pathogenic mechanism and tailoring the intervention to the individual patient. Advice on lifestyle changes and risk factor management–in particular aggressive lipid lowering therapy with statins—should Figure 5. Practical algorithm for management of patients with cardiac syndrome X. ACEi indicates angiotensin-converting enzyme inhibitors; CAD, coronary artery disease; HT, hormone therapy; IVUS, intravascular ultrasound; LVH, left ventricular hypertrophy; MVA, microvascular angina; SCS, spinal cord stimulation; and TENS, transcutaneous electrical nerve stimulation. be considered vital components of any therapeutic strategy. A multidisciplinary approach is required in most cases. Figure 5 depicts an algorithm used in our institution for the management of CSX patients. Briefly, antianginals such as calcium antagonists and -adrenergic blockers are useful in patients with documented myocardial ischemia or abnormal myocardial perfusion. Sublingual nitrates are effective in 50% of CSX patients.2 Little evidence is available in relation to the efficacy of nicorandil, ␣-adrenergic blockers, trimetazidine, and angiotensin-converting enzyme inhibitors in this setting. vasculature. Controlled clinical trials have suggested, however, that the risk of developing cardiovascular disease and breast cancer increases in women taking hormone therapy (HT). Thus, although HT has potential cardiovascular benefits, it can also cause harm.23 The US Preventative Services Task Force has suggested that routine postmenopausal HT should not be advised for the prevention of chronic conditions,23 and women should take an active part in decisions regarding HT. These recommendations apply also to CSX patients. However, HT may be useful in specific cases where a direct relationship exists between estrogen deficiency and CSX symptoms. Analgesic Intervention Analgesic intervention with imipramine,20 an antidepressant with analgesic properties, and with aminophylline,21,22 an antagonist of adenosine receptors, has been shown to improve symptoms in patients with chest pain and normal coronary arteriograms. Transcutaneous electrical nerve stimulation and spinal cord stimulation can offer good pain control. As with other interventions in CSX, studies in larger numbers of patients are lacking. Psychological Intervention Psychological intervention may be beneficial for a substantial number of patients, whether or not organic factors are involved.24 Studies support the role of a structured cognitive behavioral approach to the management of CSX patients with non-ischemic chest pain,24 and this treatment is more likely to be effective if it is begun early after diagnosis. Physical Training Hormone Therapy Hormone therapy improves chest pain and endothelial function in women with CSX.11 Estrogens antagonize the effects of ET-1 and dilate the coronary As a result of physical deconditioning and low pain threshold, CSX patients have an impaired exercise capacity.25 Physical training improves pain threshold and endothelial function and 572 Circulation February 10, 2004 delays the onset of exertional pain in patients with typical chest pain and normal coronary arteries.25 6. Summary and Final Considerations Downloaded from http://circ.ahajournals.org/ by guest on June 18, 2017 Controversy surrounds the pathogenesis and management of CSX patients. Although the majority of these patients has non-ischemic mechanisms and increased pain sensitivity, only a minority has documented myocardial ischemia. Identification of the prevailing mechanism is important for rational management. A multidisciplinary approach and a genuine, sympathetic appreciation by the physician of the devastating effect of CSX on the patient’s quality of life usually have a positive therapeutic impact. References 1. Kaski JC. Cardiac syndrome X and microvascular angina. In: Kaski JC, ed. Chest Pain With Normal Coronary Angiograms: Pathogenesis, Diagnosis and Management. London, UK: Kluwer Academic Publishers; 1999:1–12. 2. Kaski JC, Rosano GM, Collins P, et al. Cardiac syndrome X: clinical characteristics and left ventricular function: long-term follow-up study. J Am Coll Cardiol. 1995; 25:807– 814. 3. Cannon RO III, Epstein SE. “Microvascular angina” as a cause of chest pain with angiographically normal coronary arteries. Am J Cardiol. 1988;61:1338 –1343. 4. Zeiher AM, Krause T, Schachinger V, et al. Impaired endothelium-dependent vasodilation of coronary resistance vessels is associated with exercise-induced myocardial ischemia. Circulation. 1995;91:2345–2352. 5. 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A report of the American College of Cardiology/American Heart Association task force on practice guidelines (Committee on the Management of Patients With Unstable Angina). Circulation. 2000;102:1193–1209. 20. Cannon RO III, Quyyumi AA, Mincemoyer R, et al. Imipramine in patients with chest pain despite normal coronary angiograms. N Engl J Med. 1994;330:1411–1417. 21. Elliott PM, Krzyzowska-Dickinson K, Calvino R, et al. Effect of oral aminophylline in patients with angina and normal coronary arteriograms (cardiac syndrome X). Heart. 1997;77:523–526. 22. Yoshio H, Shimizu M, Kita Y et al. Effects of short-term aminophylline administration on cardiac functional reserve in patients with syndrome X. J Am Coll Cardiol. 1995;25: 1547–1551. 23. Paoletti R, Wenger NK. Review of the international position on women’s health and menopause: a comprehensive approach. Circulation. 2003;107:1336 –1339. 24. Mayou RA, Bryant BM, Sanders D, et al. A controlled trial of cognitive behavioural therapy for non-cardiac chest pain. Psychol Med. 1997;27:1021–1031. 25. Eriksson BE, Tyni-Lenne R, Svedenhag J, et al. Physical training in syndrome X: physical training counteracts deconditioning and pain in syndrome X. J Am Coll Cardiol. 2000;36: 1619 –1625. Pathophysiology and Management of Patients With Chest Pain and Normal Coronary Arteriograms (Cardiac Syndrome X) Juan Carlos Kaski Downloaded from http://circ.ahajournals.org/ by guest on June 18, 2017 Circulation. 2004;109:568-572 doi: 10.1161/01.CIR.0000116601.58103.62 Circulation is published by the American Heart Association, 7272 Greenville Avenue, Dallas, TX 75231 Copyright © 2004 American Heart Association, Inc. All rights reserved. Print ISSN: 0009-7322. 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