Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Heroin-Related Noncardiogenic Pulmonary Edema* A Case Series Karl A. Sporer, MD; and Elizabeth Dorn, MD Study objectives: To examine the current clinical spectrum of noncardiogenic pulmonary edema (NCPE) related to heroin overdose. Design: Retrospective chart review of all identified patients from August 1994 through December 1998. Setting: Urban academic hospital. Patients or participants: Heroin-related NCPE was defined as the syndrome in which a patient develops significant hypoxia (room air saturation < 90% with a respiratory rate > 12/min) within 24 h of a clinically apparent heroin overdose. This should be accompanied by radiographic evidence of diffuse pulmonary infiltrates not attributable to other causes, such as cardiac dysfunction, pneumonia, pulmonary embolism, or bronchospasm, and which resolve clinically and radiographically within 48 h. Interventions: None. Measurements and results: Twenty-seven patients were identified during this 53-month period, with a majority being male patients (85%; average age, 34 years). Twenty patients (74%) were hypoxic on emergency department arrival, and 6 patients (22%) had symptoms develop within the first hour. One patient had significant hypoxia develop within 4 h. Nine patients (33%) required mechanical ventilation, and all intubated patients but one were extubated within 24 h. Eighteen patients (66%) were treated with supplemental oxygen alone. Hypoxia resolved spontaneously within 24 h in 74% of patients, with the rest (22%) resolving within 48 h. Twenty patients (74%) had classical radiograph findings of bilateral fluffy infiltrates, but unilateral pulmonary edema occurred in four patients (15%) and more localized disease occurred in two patients (7%). Conclusion: NCPE is an infrequent complication of a heroin overdose. The clinical symptoms of NCPE are clinically apparent either immediately or within 4 h of the overdose. Mechanical ventilation is necessary in only 39% of patients. The incidence of NCPE related to heroin overdose has decreased substantially in the last few decades. (CHEST 2001; 120:1628 –1632) Key words: heroin; noncardiogenic; poisoning; pulmonary edema Abbreviations: ED ⫽ emergency department; NCPE ⫽ noncardiogenic pulmonary edema; PA ⫽ pulmonary artery use has increased dramatically in the H eroin United States during the past decade, and heroin-related emergency department (ED) visits have increased 110% between 1990 and 1995.1 In 1996, heroin overdose was responsible for 14,300 ED visits as well as 4,178 deaths.2 In certain western cities, the death toll from *From the Department of Medicine (Dr. Sporer), University of California, San Francisco, San Francisco General Hospital, San Francisco; and Department of Emergency Medicine (Dr. Dorn), Alameda County Medical Center/Highland Campus, University of California, San Francisco, San Francisco, CA. Manuscript received August 3, 2000; revision accepted May 1, 2001. Correspondence to: Karl A. Sporer, MD, Emergency Services, Room 1E21, San Francisco General Hospital, 1001 Potrero Ave, San Francisco, CA 94110; e-mail: [email protected] 1628 heroin overdoses has become the largest category of preventable deaths. In San Francisco, more people die of a heroin overdose than all causes of trauma combined.3 The actual mechanism of death caused by a heroin overdose has never been adequately explained.4 The one striking finding is the almost universal occurrence of noncardiogenic pulmonary edema (NCPE) in the fatal overdose.4 – 6 It is hoped that a better understanding of NCPE in patients with nonfatal heroin overdoses may lead to a partial explanation of the mode of death in a heroin overdose and can lead us in directions that may decrease the death rate from this street drug. An appreciation of the incidence of NCPE in heroin-overdose patients may also give us insight into proper treatment of patients with nonfatal heroin overdoses. Clinical Investigations in Critical Care Downloaded From: http://journal.publications.chestnet.org/pdfaccess.ashx?url=/data/journals/chest/21969/ on 05/15/2017 NCPE is a well-known severe complication of heroin overdose that was first described by William Osler during an autopsy in 1880.7 The presentation and clinical course of NCPE patients with nonfatal heroin overdoses were first described8 in 1953, and later in a variety of case series and reports.9 –28 A heroin overdose is routinely clinically diagnosed by noting the combination of altered mental status, severely decreased respiratory drive, pinpoint pupils, and circumstantial evidence of drug use.29 NCPE related to a heroin overdose usually presents as the combination of persistent hypoxia after resolution of opiate respiratory depression along with frothy, pinktinged pulmonary secretions, and a characteristic radiograph pattern of fluffy diffuse pulmonary infiltrates. Some of these patients require mechanical ventilation to treat their hypoxia. The symptoms usually resolve rapidly with supportive care alone within hours to 1 or 2 days. NCPE has also been reported with overdoses of methadone,30 propoxyphene,31 codeine,32 buprenorphine,33,34 and nalbuphine.35 There is also an unrelated syndrome of cardiogenic pulmonary edema that has been rarely reported with the use of naloxone36 or nalmefene37 to reverse therapeutic doses of opiates after anesthesia. Materials and Methods This study took place at San Francisco General Hospital, an urban hospital with ⬎ 75,000 ED visits per year. The University of California, San Francisco Committee of Human Research approved this study. Most heroin overdoses are diagnosed and initially treated by paramedics. After making the presumptive diagnosis of a heroin overdose (a patient with an abnormal level of consciousness, pinpoint pupils, and decreased or absent respirations), the patient is treated with a bag-valve mask and supplemental oxygen along with an IM dose of naloxone, 2 mg. Approximately 70% of the heroin-overdose patients in San Francisco are transported to San Francisco General Hospital.38 In the ED, heroin-overdose patients are observed for 2 h for signs of significant resedation, significant hypoxia, fever, or other complications. IV fluids are rarely administered. We defined opiate-related NCPE as the syndrome in which a patient develops significant hypoxia (room air oxygen saturation ⬍ 90% with a respiratory rate ⬎ 12/min) within 24 h of a clinically apparent heroin overdose. This should be accompanied by radiographic evidence of diffuse pulmonary infiltrates not attributable to other causes, such as cardiac dysfunction, pneumonia, pulmonary embolism, or bronchospasm, and which resolve clinically and radiographically within 48 h. A database of all ED patients seen during the period of August 1994 through December 1998 was queried for this study. The absolute number of patients who presented to our ED with the diagnosis of a heroin overdose was determined by searching the diagnosis field with a combination of the terms, “heroin overdose” or “HOD.” All of the admissions to the medicine service at our hospital with a test diagnosis containing the words “heroin overdose,” “HOD,” “heroin,” or “opiate” were reviewed. The clinical charts and radiographs of 162 patients were reviewed by one of the authors (E.D.) for appropriateness of the diagnosis of NCPE. Most patients were admitted to the hospital for a variety of other medical reasons, such as pneumonia, possible endocarditis, persistent confusion, cellulitis, etc. Borderline cases (eg, atypical pneumonia) were reviewed by the first author (K.A.S.) for consistency with the diagnosis. Results There were 1,278 patients who presented with the diagnosis of heroin overdose in our hospital during this 53-month period; 162 of these patients were admitted to the medical service, and a total of 27 patients met the criteria for the diagnosis of NCPE. There were 23 male patients in this NCPE cohort, and the average age was 34 years. There were no repeat cases among the NCPE group. The repeat rate for all heroin-overdose patients has been shown38 to be extremely small in our city. All patients but one received prehospital naloxone. Twenty patients (74%) were hypoxic on presentation to the ED, and 6 patients (22%) had severe hypoxia develop during the first hour. One patient (4%) presented with a room air oxygen saturation of 93% and a respiratory rate of 18/min that worsened within 4 h to a room air oxygen saturation of 81%. Characteristic radiographic findings of pulmonary edema developed in this patient. There were no episodes of hypoventilation in this group of patients. The respiratory rate ranged from 16 to 44/min (average, 24/min). The initial oxygen saturation ranged from 47 to 89% on room air, with an average oxygen saturation of 76%. Thirty-three percent of these patients required mechanical ventilation to achieve adequate oxygenation, while most of the patients (66%) were treated with oxygen via nonrebreather face mask and observation only. There were three patients who presented with hypotension (systolic BP ⬍ 90 mm Hg). These episodes resolved spontaneously with ⬍ 500 mL of crystalloid fluid resuscitation. The hypoxic symptoms of a majority of patients (74%) resolved within 24 h, several within 8 h. The other six patients (22%) had resolution of symptoms within 24 to 48 h. All intubated patients but one were extubated within 24 h. This patient required a prolonged ICU stay partially because of an iatrogenic pneumothorax. Classic chest radiographic findings of bilateral pulmonary edema were noted in 20 of the 27 patients (74%). Interestingly, four patients presented with chest radiographic findings of unilateral pulmonary edema, a finding that has been previously reported.14,16,39 Three other patients had chest radiographic findings of “patchy atelectasis” (n ⫽ 2) and “nodular interstitial pattern” (n ⫽ 1). These CHEST / 120 / 5 / NOVEMBER, 2001 Downloaded From: http://journal.publications.chestnet.org/pdfaccess.ashx?url=/data/journals/chest/21969/ on 05/15/2017 1629 patients did not undergo bronchoscopy to definitively rule out aspiration pneumonia, but the absence of an increased WBC count and the very rapid resolution of the symptoms and the radiographic findings make this less likely. Rhabdomyolysis was diagnosed in two of these patients, and they were treated with fluid replacement and sodium bicarbonate. Neither patient developed renal insufficiency. Discussion We have presented the clinical characteristics of the largest case series of heroin-related NCPE since the 1960s. NCPE is an infrequent complication of patients who present with an acute heroin overdose. The symptoms of significant hypoxia with an adequate respiratory rate usually occur rapidly after treatment. The radiographic findings are usually bilateral fluffy infiltrates, but a percentage of patients can have unilateral or lobar disease. Only 33% of these patients require intubation. Most patients required only supplemental oxygen, and most of these patients’ symptoms resolve within 24 h. The epidemiology of NCPE has changed over the last 40 years. Earlier retrospective case series14,17,18 of heroin-overdose patients admitted to the hospital have described a NCPE rate of 48 to 80%. The full denominator, including heroin-overdose patients admitted to and discharged from the hospital, was not available in these studies. More recent case series38,40 – 43 of patients presenting with heroin overdoses have a NCPE rate of 0.8% to 2.4%, similar to our rate of 2.1%. The decreased rate of NCPE in patients with nonfatal heroin overdoses can be partially explained by including the full denominator of heroin-overdose patients admitted to and discharged from the hospital. But this alone cannot explain all of the difference. These earlier case series14,17,18 occurred before naloxone was readily available. This specific narcotic antagonist may be instrumental in decreasing the number of patients with nonfatal heroin overdoses with NCPE. The improvement of emergency medical services with the earlier prehospital administration of naloxone and oxygen may also add to this improvement.41 This early experience with high rates of NCPE is the likely reason for the extended recommended observation period of 12 to 24 h that is commonly quoted.14,44 Because NCPE is a relatively uncommon event in heroin-overdose patients and usually presents early, a 1-h to 2-h observation period should be adequate for these patients. One prospective study43 demonstrated that these patients rarely return to the hospital for subsequent treatment. 1630 The pathophysiology of NCPE related to heroin overdose has never been adequately explained. This is of interest not because of its relative infrequency in nonfatal heroin overdose, but because of its almost universal occurrence in fatal heroin overdose.4 – 6 This may suggest that this entity may be a partial explanation for the mode of death in a heroin overdose. The investigations into the cause of heroin-related NCPE have been limited. Hemodynamic evaluation of a total of 11 patients with heroin-related NCPE demonstrated normal or increased cardiac output, normal pulmonary capillary pressure, and only moderately elevated pulmonary artery (PA) pressure.24,28,45,46 Pulmonary fluid analysis of patients with this syndrome confirmed a much higher protein concentration, as compared to edema fluid from patients with congestive heart failure, consistent with the hypothesis that leaky pulmonary capillaries and not pump failure are the likely cause of heroinrelated NCPE.45,47 The only animal model48 of opiate-induced pulmonary edema examined the effect of morphine on the pulmonary vasculature in perfused, normally oxygenated cats and dogs. A large dose of morphine caused a highly variable increase in pulmonary vascular resistance via venous vasoconstriction. Animals with a mild-to-moderate increase in PA pressure recovered spontaneously and returned to baseline. The animals with a marked increase in PA pressure had pulmonary edema develop within 20 to 30 min. The increase in PA pressure was reversed by chlorpheniramine, a histamine type 1-receptor antagonist. Pretreatment with naloxone blunted this response but had no effect in posttreatment. Histamine has been implicated as a possible mediator of NCPE related to heroin overdose. Human lungs are rich in histamine,49 and opiates have been shown to cause its systemic and local release.50 –57 Histamine has been shown49,58,59 to increase pulmonary lymph flow and capillary permeability. One study of patients with fatal heroin overdoses demonstrated a modest correlation with elevated tryptase levels (a postmortem histamine surrogate), as compared to control subjects.60 Conclusion To our knowledge, this is the largest case series of NCPE reported in several decades. NCPE is an infrequent complication of nonfatal heroin overdoses, with an incidence of 2.1% in our hospital. The symptoms of significant hypoxia with an adequate respiratory rate usually occur rapidly after treatment. The radiographic findings are usually bilateral fluffy Clinical Investigations in Critical Care Downloaded From: http://journal.publications.chestnet.org/pdfaccess.ashx?url=/data/journals/chest/21969/ on 05/15/2017 infiltrates, but a significant percentage of patients can have unilateral or lobar disease. Only 33% of these patients require mechanical ventilation. A majority of patients only required supplemental oxygen, and symptoms in most of these patients resolved within 24 h. References 1 Department of Health and Human Services. Year-end preliminary estimates from the 1996 Drug Abuse Warning Network, Rockville, MD: Substance Abuse and Mental Health Services Administration, November 1997 2 Department of Health and Human Services. Drug Abuse Warning Network: annual medical examiners data, 1995, Rockville, MD: Substance Abuse and Mental Health Services Administration, May 1997 3 McLoughlin E, Weitzel M, Skaj P, et al. Profile of injury in San Francisco. San Francisco, CA: San Francisco Department of Public Health, 1998 4 Darke S, Zador D. Fatal heroin “overdose”: a review. Addiction 1996; 91:1765–1772 5 Levine SB, Grimes ET. Pulmonary edema and heroin overdose in Vietnam. Arch Pathol 1973; 95:330 –332 6 Karch SB. Narcotics. In: The pathology of drug abuse. 2nd ed. Boca Raton, FL: CRC Press; 1997; 281– 407 7 Sternbach G. William Osler: narcotic-induced pulmonary edema. J Emerg Med 1983; 1:165–167 8 Troen P. Pulmonary edema in acute opium intoxication. N Engl J Med 1953; 248:364 –366 9 Silber R, Clerkin EP. Pulmonary edema in acute heroin poisoning. Am J Med 1959; 27:187–192 10 Selzman HM, Kahil ME, Fred HL. Pulmonary edema accompanying heroin intoxication. Cardiovasc Res Center Bull 1967; 6:77–78 11 Louria DB, Hensle T, Rose J. The major medical complications of heroin addiction. Ann Intern Med 1967; 67:1–22 12 Cherubin CE. The medical sequelae of narcotic addiction. Ann Intern Med 1067; 67:23–33 13 Stern WZ, Spear PW, Jacobson HG. The roentgen findings in acute heroin intoxication. AJR Am J Roentgenol 1968; 103: 522–532 14 Steinberg AD, Karliner JS. The clinical spectrum of heroin pulmonary edema. Arch Intern Med 1968; 122:122–127 15 Karliner JS, Steinberg AD, Williams MH Jr. Lung function after pulmonary edema associated with heroin overdose. Arch Intern Med 1969; 124:350 –353 16 Jaffe RB, Koschmann EB. Intravenous drug abuse: pulmonary, cardiac, and vascular complications. Am J Roentgenol Radium Ther Nucl Med 1970; 109:107–120 17 Morrison WJ, Wetherill S, Zyroff J. The acute pulmonary edema of heroin intoxication. Radiology 1970; 97:347–351 18 Duberstein JL, Kaufman DM. A clinical study of an epidemic of heroin intoxication and heroin-induced pulmonary edema. Am J Med 1971; 51:704 –714 19 Frand UI, Shim CS, Williams MH Jr. Heroin-induced pulmonary edema: sequential studies of pulmonary function. Ann Intern Med 1972; 77:29 –35 20 Addington WW, Cugell DW, Basely ES. The pulmonary edema of heroin toxicity: an example of the stiff lung syndrome. Chest 1972; 62:199 –205 21 Light RW, Dunham TR. Severe slowly resolving heroininduced pulmonary edema. Chest 1975; 67:61– 64 22 Paranthaman SK, Khan F. Acute cardiomyopathy with recurrent pulmonary edema and hypotension following heroin overdosage. Chest 1976; 69:117–119 23 Banner AS, Muthuswamy P, Shah RS, et al. Bronchiectasis following heroin-induced pulmonary edema: rapid clearing of pulmonary infiltrates. Chest 1976; 69:552–555 24 Smith WR, Glauser FL, Dearden LC, et al. Deposits of immunoglobulin and complement in the pulmonary tissue of patients with “heroin lung.” Chest 1978; 73:471– 476 25 Leechawengwong M, Berger HW, Jayamanne DS. Longterm serial follow-up after two episodes of heroin-induced adult respiratory distress syndrome. Mt Sinai J Med 1979; 46:119 –121 26 Wang M, Liaw S, Bullard MJ. Heroin lung: report of two cases. J Formosa Med Assoc 1994; 93:170 –172 27 Raijmakers PG, Groeneveld AB, de Groot MC, et al. Delayed resolution of pulmonary oedema after cocaine/heroin abuse. Thorax 1994; 49:1038 –1040 28 Otto D, Franke M, Madden JF. Hypothermia accompanied by noncardiogenic pulmonary edema: a case report. Del Med J 1996; 68:499 –502 29 Sporer KA. Acute heroin overdose. Ann Intern Med 1999; 130:584 –590 30 Kjeldgaard JM, Hahn GW, Heckenlively JR, et al. Methadone-induced pulmonary edema. JAMA 1971; 218:882– 883 31 Bogartz LJ, Miller WC. Pulmonary edema associated with propoxyphene intoxication. JAMA 1971; 215:259 –262 32 Sklar J, Timms RM. Codeine-induced pulmonary edema. Chest 1977; 72:230 –231 33 Gould DB. Buprenorphine causes pulmonary edema just like all other mu-opioid narcotics [letter]. Chest 1995; 107:1478–1479 34 Thammakumpee G, Sumpatanukule P. Noncardiogenic pulmonary edema induced by sublingual buprenorphine. Chest 1994; 106:306 –308 35 Stadnyk A, Grossman RF. Nalbuphine-induced pulmonary edema. Chest 1986; 90:773–774 36 Schwartz JA, Koenigsberg MD. Naloxone-induced pulmonary edema. Ann Emerg Med 1987; 16:1294 –1296 37 Henderson CA, Reynolds JE. Acute pulmonary edema in a young male after intravenous nalmefene. Anesth Analg 1997; 84:218 –219 38 Sporer KA, Firestone J, Isaacs SM. Out-of-hospital treatment of opioid overdoses in an urban setting. Acad Emerg Med 1996; 3:660 – 667 39 Stern WZ, Subbarao K. Pulmonary complications of drug addiction. Semin Roentgenol 1983; 18:183–197 40 Smith DA, Leake L, Loflin JR, et al. Is admission after intravenous heroin overdose necessary? Ann Emerg Med 1992; 21:1326 –1330 41 Bertini G, Russo L, Cricelli F, et al. Role of a prehospital medical system in reducing heroin-related deaths. Crit Care Med 1992; 20:493– 498 42 Osterwalder JJ. Patients intoxicated with heroin or heroin mixtures: how long should they be monitored? Eur J Emerg Med 1995; 2:97–101 43 Christenson J, Etherington J, Grafstein E, et al. Early discharge of patients with presumed opioid overdose: development of a clinical prediction rule. Acad Emerg Med 2000; 7:1110 –1118 44 Goldfrank L, Weisman R. Opioids. In: Goldfrank LR, Flomenbaum NE, Lewin N, et al, eds. Goldfrank’s toxicologic emergencies. 6th ed. Norwalk, CT: Appleton & Lange, 1994; 769 –783 45 Karliner J. Noncardiogenic forms of pulmonary edema. Circulation 1972; 156:212–215 46 Gopinathan K, Saroja D, Spears R, et al. Hemodynamic studies in heroin-induced acute pulmonary edema [abstract]. Circulation 1970; III-44:61– 63 47 Katz S, Aberman A, Frand UI, et al. Heroin pulmonary edema: evidence for increased pulmonary capillary permeCHEST / 120 / 5 / NOVEMBER, 2001 Downloaded From: http://journal.publications.chestnet.org/pdfaccess.ashx?url=/data/journals/chest/21969/ on 05/15/2017 1631 ability. Am Rev Respir Dis 1972; 106:472– 474 48 Hakim TS, Grunstein MM, Michel RP. Opiate action in the pulmonary circulation. Pulm Pharmacol 1992; 5:159 –165 49 Pietra GG, Szidon JP, Leventhal MM, et al. Histamine and interstitial pulmonary edema in the dog. Circ Res 1971; 29:323–337 50 Brashear RE, Kelly MT, White AC. Elevated plasma histamine after heroin and morphine. J Lab Clin Med 1974; 83:451– 457 51 Schurig J, Cavanagh R, Buyniski J. Effect of butorphanol and morphine on pulmonary mechanics, arterial blood pressure and venous plasma histamine in the anesthetized dog. Arch Int Pharmacodyn Ther 1978; 233:296 52 Philbin DM, Moss J, Akins CW, et al. The use of H1 and H2 histamine antagonists with morphine anesthesia: a doubleblind study. Anesthesiology 1981; 55:292–296 53 Fahmy NR. Hemodynamics, plasma histamine, and catecholamine concentrations during an anaphylactoid reaction to morphine. Anesthesiology 1981; 55:329 –331 1632 54 Rosow CE, Moss J, Philbin DM, et al. Histamine release during morphine and fentanyl anesthesia. Anesthesiology 1982; 56:93–96 55 Moss J, Rosow CE. Histamine release by narcotics and muscle relaxants in humans. Anesthesiology 1983; 59:330–339 56 Barke KE. Opiates, mast cells, and histamine release. Life Sci 1993; 53:1391–1399 57 Withington DE, Patrick JA, Reynolds F. Histamine release by morphine and diamorphine in man. Anesthesia 1993; 48: 26 –29 58 Brigham KL, Owen PJ. Increased sheep lung vascular permeability caused by histamine. Circ Res 1975; 37:647– 657 59 Pietra GG, Magno M, Johns L. Morphological and physiological study of the effect of histamine on the isolated perfused rabbit lung. Lymphology 1979; 12:165–176 60 Edston E, van Hage-Hamsten M. Anaphylactoid shock: a common cause of death in heroin addicts? Allergy 1997; 52:950 –954 Clinical Investigations in Critical Care Downloaded From: http://journal.publications.chestnet.org/pdfaccess.ashx?url=/data/journals/chest/21969/ on 05/15/2017