Emphysema

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Overview

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [2]

Overview

Emphysema is a long-term, progressive disease of the lungs that primarily causes shortness of breath. In people with emphysema, the tissues necessary to support the physical shape and function of the lungs are destroyed. It is included in a group of diseases called chronic obstructive pulmonary disease or COPD (pulmonary refers to the lungs). Emphysema is called an obstructive lung disease because the destruction of lung tissue around smaller sacs, called alveoli, makes these air sacs unable to hold their functional shape upon exhalation. Emphysema is most often caused by tobacco smoking and long-term exposure to air pollution.

The term emphysema means “swelling” and derives from the Greek ἐμφυσᾶν emphysan meaning “inflate” – itself composed of ἐν en, meaning “in“, and φυσᾶν physan, meaning “breath, blast“.^[1]

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Historical perspective

The terms chronic bronchitis and emphysema were formally defined at the CIBA guest symposium of physicians in 1959. COPD has probably always existed but has been called by different names in the past. Bonet described a condition of “voluminous lungs” in 1679. Matthew Baillie illustrated an emphysematous lung in 1789 and described the destructive character of the condition. The term COPD was first used by William Briscoe in 1965 and has gradually overtaken other terms to become established today as the preferred name for this disease.

Pathophysiology

Emphysema is caused by loss of elasticity of the lung tissue, from destruction of structures supporting the alveoli, and destruction of capillaries feeding the alveoli. The result is that the small airways collapse during exhalation, leading to an obstructive form of lung disease (airflow is impeded and air is generally “trapped” in the lungs in obstructive lung diseases). When toxins such as smoke are breathed into the lungs, the particles are trapped and cause a localized inflammatory response. Chemicals released during the inflammatory response (e.g., elastase) can break down the walls of alveoli (alveolar septum). This leads to fewer but larger alveoli, with a decreased surface area and a decreased ability to absorb oxygen and exude carbon dioxide by diffusion. The activity of another molecule called alpha 1-antitrypsin normally neutralizes the destructive action of one of these damaging molecules.

Risk Factors

Chronic obstructive pulmonary disease is a group of diseases characterized by the pathological limitation of airflow in the airway that is not fully reversible. A full comprehensive diagnosis is needed to eliminate related conditions and isolate the influence of lifestyle and behavior risk factors on condition outcome. Some common risk factors are cigarette smoking, occupational pollutants, air pollution and genetics. Other risk factors are increasing age, male gender, allergy, repeated airway infection.

Differential Diagnosis

In clinical practice, COPD is defined by its characteristically low airflow on lung function tests.^[2] In contrast to asthma, this limitation is poorly reversible and usually gets progressively worse over time. It should be differentiated from certain conditions that have similar presentation for instance congestive heart failure, chronic asthma, bronchiectasis, and bronchiolitis obliterans.

References

↑ emphysema at dictionary.com
↑ Template:Cite doi [1]

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Historical Perspective

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editors-In-Chief: Mehrian Jafarizade, M.D [2], Cafer Zorkun, M.D., Ph.D. [3], Priyamvada Singh, MBBS [4]

Overview

The terms chronic bronchitis and emphysema were formally defined at the CIBA guest symposium of physicians in 1959. Matthew Baillie illustrated an emphysematous lung in 1789 and described the destructive character of the condition.

Historical Perspective

In 1679, Bonet for the first time described voluminous lungs.
In 1721, Ruysh described enlarged lung airspaces in emphysema.
In 1769, Giovanni Morgagni described nineteen cases in which the lungs were “turgid” particularly from air.
In 1789, Matthew Baillie illustrated an emphysematous lung and described the destructive character of the condition.
In 1837, René Laennec, the physician who invented the stethoscope, used the term “emphysema” in his book A Treatise on the Diseases of the Chest and of Mediate Auscultation to describe lungs that did not collapse when he opened the chest during an autopsy. He noted that they did not collapse as usual because they were full of air and the airways were filled with mucus.^[1]
In 1842, John Hutchinson invented the spirometer, which allowed the measurement of the vital capacity of the lungs. However, his spirometer could only measure volume, not airflow.^[2]
In 1944, Ronald Christie defined the diagnosis for emphysema based on dyspnea on exertion, after exclusion of bronchospasm, or left ventricular failure.
In 1947, Tiffeneau and Pinelli, and in 1950 and 1951, Gaensler described the principles of measuring airflow.
in 1952, Gough explained the pathology of emphysema.
In 1956, Barach and Bickerman described treatment for emphysema in their comprehensive textbook.
In 1959, the terms chronic bronchitis and emphysema were formally defined at the CIBA guest symposium of physicians.
In 1962, American Thoracic Society Committee on Diagnostic Standards defined the components of COPD and this definition is the foundation of COPD description today.
In 1964, Gross produced destruction of alveoli and hyperinflation, by injection of pancreatic extracts (papain) into the airways of guinea pigs.
In 1967, Reid described the pathology of emphysema and other components of COPD.
In 1976, Thurlbeck illustrated the various types of emphysema in his book.
In 2003, Choe used methylprednisolone to produce emphysema in rats. They conclude that systemic methylprednisolone increases the activity of matrix metalloproteinases in the lung and causes emphysema. ^[3]
In 2004, GOLD offered a new classification of the severity of COPD. ^[4]
In 2005, Voelkel and Taraseviciene-Stewart offered emphysema as an autoimmune vascular disease. ^[5]

Landmark Events in the Development of Treatment Strategies

In 1956, Barach and Bickerman described treatment for emphysema in their comprehensive textbook.
In 1980, for treatment of COPD patients, a clinical trial was performed and the use of nocturnal oxygen therapy for emphysema proved. ^[6]
In 1998, Paggiaro performed a multicentre clinical trial of corticosteroids for emphysema treatment.^[7]

Below table is a summery of emphysema historical prospective:

Year	Investigator	Landmark event
1679	Bonet	Voluminous lungs
1721	Ruysh	Emphysema is enlarged lung spaces
1769	Giovanni Morgagni	Nineteen cases of air filled lungs
1789	Matthew Baillie	Destructive character of emphysema
1837	René Laennec	Hyper-resonant lungs with his invented stethoscope
1842	John Hutchinson	Spirometry invention for measurement of the vital capacity of the lungs
1944	Ronald Christie	Clinical definition of emphysema
1947	Tiffeneau and Pinelli	Measuring the air flow in spirometry
1952	Gough	Emphysema pathology description
1956	Barach and Bickerman	First description for treatment of emphysema
1959	CIBA guest symposium of physicians	The terms chronic bronchitis and emphysema were formally defined
1962	American Thoracic Society Committee on Diagnostic Standards	Defined the components of COPD
1967	Reid	Described the pathology of emphysema and other components of COPD
1976	Thurlbeck	Illustrated the various types of emphysema
1980	Oxygen therapy trial	Use of nocturnal oxygen therapy for emphysema is beneficial
1998	Paggiaro	Corticosteroids for emphysema treatment
2004	GOLD criteria	New classification of the severity of COPD
2005	Voelkel and Taraseviciene-Stewart	Emphysema as an autoimmune vascular disease

References

↑ Petty TL (2006). “The history of COPD”. Int J Chron Obstruct Pulmon Dis. 1 (1): 3–14. PMC 2706597. PMID 18046898.
↑ Fishman AP (2005). “One hundred years of chronic obstructive pulmonary disease”. Am. J. Respir. Crit. Care Med. 171 (9): 941–8. doi:10.1164/rccm.200412-1685OE. PMID 15849329. Unknown parameter |month= ignored (help)
↑ Choe KH, Taraseviciene-Stewart L, Scerbavicius R, Gera L, Tuder RM, Voelkel NF (2003). “Methylprednisolone causes matrix metalloproteinase-dependent emphysema in adult rats”. Am. J. Respir. Crit. Care Med. 167 (11): 1516–21. doi:10.1164/rccm.200210-1207OC. PMID 12522028.
↑ “Global Initiative for Chronic Obstructive Lung Disease – Global Initiative for Chronic Obstructive Lung Disease – GOLD”.
↑ Voelkel N, Taraseviciene-Stewart L (2005). “Emphysema: an autoimmune vascular disease?”. Proc Am Thorac Soc. 2 (1): 23–5. doi:10.1513/pats.200405-033MS. PMID 16113465.
↑ “Continuous or nocturnal oxygen therapy in hypoxemic chronic obstructive lung disease: a clinical trial. Nocturnal Oxygen Therapy Trial Group”. Ann. Intern. Med. 93 (3): 391–8. 1980. PMID 6776858.
↑ Paggiaro PL, Dahle R, Bakran I, Frith L, Hollingworth K, Efthimiou J (1998). “Multicentre randomised placebo-controlled trial of inhaled fluticasone propionate in patients with chronic obstructive pulmonary disease. International COPD Study Group”. Lancet. 351 (9105): 773–80. PMID 9519948.

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Classification

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Mehrian Jafarizade, M.D [2]

Overview

Emphysema can be classified by location in to different types such as panacinary, centroacinary, congenital lobaremphysema, and paraseptal emphysema.

Classification

Emphysema can be classified by location into three categories:

Panacinary (panlobular):

The entire respiratory acinus, from respiratory bronchiole to alveoli, is expanded. Occurs more commonly in the lower lobes (especially basal segments) and in the anterior margins of the lungs.^[1]

Centroacinary (panacinar and centriacinar):

The respiratory bronchiole (proximal and central part of the acinus) is expanded. The distal acinus or alveoli are unchanged. Occurs more commonly in the upper lobes.^[1]^[2]

Other types:

Congenital lobar emphysema (CLE)

CLE results in over-expansion of a pulmonary lobe, and resultant compression of the remaining lobes of the ipsi-lateral lung (and possibly also the contralateral lung). There is bronchial narrowing because of weakened or absent bronchial cartilage.^[3] There may be congenital extrinsic compression, commonly by an abnormally large pulmonary artery. This causes malformation of bronchial cartilage, making them soft and collapsible.^[3] CLE is a potentially reversible (yet possibly life-threatening) cause of respiratory distress in the neonate.^[3]

Paraseptal emphysema

Para-septal emphysema is a type of emphysema which involves the alveolar ducts and sacs at the lung periphery. The emphysematous areas are sub-pleural in location and often surrounded by inter-lobular septa (hence the name). It may be an incidental finding in young adults, and may be associated with spontaneous pneumothorax. It may also be seen in older patients with centri-lobular emphysema. Both centri-lobular and para-septal emphysema may progress to bullous emphysema. A bulla is defined as being at least 1 cm in diameter, and with a wall less than 1 mm thick. Bullae are thought to arise by air trapping in emphysematous spaces, causing local expansion.^[4]

References

↑ ^1.0 ^1.1 “Emphysema”. Retrieved 2008-11-20.
↑ Anderson AE, Foraker AG (1973). “Centrilobular emphysema and panlobular emphysema: two different diseases”. Thorax. 28 (5): 547–50. doi:10.1136/thx.28.5.547. PMC 470076. PMID 4784376. Unknown parameter |month= ignored (help)
↑ ^3.0 ^3.1 ^3.2 eMedicine Specialties > Radiology > Pediatrics –> Congenital Lobar Emphysema Author: Beverly P Wood, MD, MS, PhD, University of Southern California. Updated: December 1, 2008
↑ Webb WR, Higgins CB. Thoracic Imaging. Lippincott, Williams & Wilkins 2005.

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Pathophysiology

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Overview

Emphysema is caused by loss of elasticity of the lung tissue, from destruction of structures supporting the alveoli, and destruction of capillaries feeding the alveoli. The result is that the small airways collapse during exhalation (although alveolar collapsability has increased), leading to an obstructive form of lung disease (airflow is impeded and air is generally “trapped” in the lungs in obstructive lung diseases). When toxins such as smoke are breathed into the lungs, the particles are trapped and cause a localized inflammatory response. Chemicals released during the inflammatory response (e.g., elastase) can break down the walls of alveoli (alveolar septum). This leads to fewer but larger alveoli, with a decreased surface area and a decreased ability to absorb oxygen and exude carbon dioxide by diffusion. The activity of another molecule called alpha 1-antitrypsin normally neutralizes the destructive action of one of these damaging molecules.

Pathophysiology

Emphysema is caused by loss of elasticity (increased compliance) of the lung tissue, from destruction of structures supporting the alveoli, and destruction of capillaries feeding the alveoli. The result is that the small airways collapse during exhalation (although alveolar collapsability has increased), leading to an obstructive form of lung disease (airflow is impeded and air is generally “trapped” in the lungs in obstructive lung diseases).

When toxins such as smoke are breathed into the lungs, the particles are trapped and cause a localized inflammatory response. Chemicals released during the inflammatory response (e.g., elastase) can break down the walls of alveoli (alveolar septum). This leads to fewer but larger alveoli, with a decreased surface area and a decreased ability to absorb oxygen and exude carbon dioxide by diffusion. The activity of another molecule called alpha 1-antitrypsin normally neutralizes the destructive action of one of these damaging molecules.
After a prolonged period, hyperventilation becomes inadequate to maintain high enough oxygen levels in the blood. The body compensates by vasoconstricting appropriate vessels. This leads to pulmonary hypertension, which places increased strain on the right side of the heart, the one that pumps unoxygenated blood to the lungs, fails. The failure causes the heart muscle to thicken to pump more blood. Eventually, as the heart continues to fail, it becomes larger and blood backs up in the liver.
Emphysema occurs in a higher proportion in patients with decreased alpha 1-antitrypsin (A1AT) levels (alpha 1-antitrypsin deficiency, A1AD). In A1AD, inflammatory enzymes (such as elastase) are able to destroy the alveolar tissue (the elastin fibre, for example). Most A1AD patients do not develop clinically significant emphysema, but smoking and severely decreased A1AT levels (10-15%) can cause emphysema at a young age. In all, A1AD causes about 2% of all emphysema. However, smokers with A1AD are in the highest risk category for emphysema.
While A1AD provides some insight into the pathogenesis of the disease, hereditary A1AT deficiency only accounts for a small proportion of the disease. Studies for the better part of the past century have focused mainly upon the putative role of leukocyte elastase (also neutrophil elastase), a serine protease found in neutrophils, as a primary contributor to the connective tissue damage seen in the disease. This hypothesis, a result of the observation that NE is the primary substrate for A1AT, and A1AT is the primary inhibitor of NE, together have been known as the “protease-antiprotease” theory, implicating neutrophils as an important mediator of the disease. However, more recent studies have brought into light the possibility that one of the many other numerous proteases, especially matrix metalloproteases might be equally or more relevant than NE in the development of non-hereditary emphysema.

The better part of the past few decades of research into the pathogenesis of emphysema involved animal experiments where various proteases were instilled into the trachea of various species of animals. These animals developed connective tissue damage, which was taken as support for the protease-antiprotease theory. However, just because these substances can destroy connective tissue in the lung, as anyone would be able to predict, doesn’t establish causality. More recent experiments have focused on more technologically advanced approaches, such as ones involving genetic manipulation. Perhaps the most interesting development with respect to our understanding of the disease involves the production of protease “knock-out” animals, which are genetically deficient in one or more proteases, and the assessment of whether they would be less susceptible to the development of the disease

Gross Pathology

Pathology of lung showing centrilobular emphysema characteristic of smoking. Closeup of fixed, cut surface shows multiple cavities lined by heavy black carbon deposits. (CDC/Dr. Edwin P. Ewing, Jr., 1973)

Microscopic Pathology

H&E (haematoxylin and eosin) stained lung tissue sample from an end-stage emphysema patient. RBCs are red, nuclei are blue-purple, other cellular and extracellular material is pink, and air spaces are white.

References

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Causes

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

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Overview

Causes

The most common cause is cigarette smoking.

Causes by Organ System

Cardiovascular	No underlying causes
Chemical/Poisoning	No underlying causes
Dental	No underlying causes
Dermatologic	No underlying causes
Drug Side Effect	Thalidomide
Ear Nose Throat	No underlying causes
Endocrine	No underlying causes
Environmental	No underlying causes
Gastroenterologic	No underlying causes
Genetic	No underlying causes
Hematologic	No underlying causes
Iatrogenic	No underlying causes
Infectious Disease	No underlying causes
Musculoskeletal/Orthopedic	No underlying causes
Neurologic	No underlying causes
Nutritional/Metabolic	No underlying causes
Obstetric/Gynecologic	No underlying causes
Oncologic	No underlying causes
Ophthalmologic	No underlying causes
Overdose/Toxicity	No underlying causes
Psychiatric	No underlying causes
Pulmonary	No underlying causes
Renal/Electrolyte	No underlying causes
Rheumatology/Immunology/Allergy	No underlying causes
Sexual	No underlying causes
Trauma	No underlying causes
Urologic	No underlying causes
Miscellaneous	No underlying causes

References

Differentiating Emphysema from other Diseases

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: : Mehrian Jafarizade, M.D [2]

Overview

Emphysema must be differentiated from other diseases presenting with cough, shortness of breath and tachypnea, such as congestive heart failure, asthma, bronchiectasis, and bronchiolitis obliterans, pulmonary embolism, pericarditis, and vasculitis.

Differential Diagnosis

Emphysema should be differentiated from other diseases presenting with chronic cough, shortness of breath and tachypnea. The differentials include the following:^[1]^[2]^[3]^[4]^[5]^[6]^[7]^[8]^[9]^[10]^[11]^[12]^[13]^[14]^[15]^[16]^[17]^[18]^[19]^[20]

Diseases	CT scan and MRI	EKG	Chest X-ray	Tachypnea	Tachycardia	Fever	Chest Pain	Hemoptysis	Dyspnea on Exertion	Wheezing	Chest Tenderness	Nasalopharyngeal Ulceration	Carotid Bruit	Past medical history	Other Findings
Diseases	Diagnostic tests			Physical Examination			Symptoms							Past medical history	Other Findings
Pulmonary embolism	On CT angiography: Intra-luminal filling defect On MRI: Narrowing of involved vessel No contrast seen distal to obstruction Polo-mint sign (partial filling defect surrounded by contrast)	S1Q3T3 pattern representing acute right heart strain	Fleischner sign (enlarged pulmonary artery), Hampton hump, Westermark’s sign	✔	✔	✔ (Low grade)	✔	✔ (In case of massive PE)	✔	–	–	–	–	Hypercoagulating conditions (Factor V Leiden, thrombophilia, deep vein thrombosis, immobilization, malignancy, pregnancy)	May be associated with metabolic alkalosis and syncope
Congestive heart failure	On CT scan: Mediastinal lymphadenopathy Hazy mediastinal fat On MRI: Abnormality of cardiac chambers (hypertrophy, dilation) Delayed enhancement MRI may help characterize the myocardial tissue (fibrosis) Late enhancement of contrast in conditions such as myocarditis, sarcoidosis, amyloidosis, Anderson-Fabry‘s disease, Chagas disease)	Goldberg’s criteria may aid in diagnosis of left ventricular dysfunction: (High specificity) SV1 or SV2 + RV5 or RV6 ≥3.5 mV Total QRS amplitude in each of the limb leads ≤0.8 mV R/S ratio <1 in lead V4	Cardiomegaly	✔	✔	✔	–	–	✔	–	–	–	–	Previous myocardial infarction Hypertension (systemic and pulmonary) Cardiac arrythmias Viral infections (myocarditis) Congenital heart defects	Right heart failure associated with: Hepatomegaly Positive hepato-jugular reflex Increased jugular venous pressure Peripheral edema Left heart failure associated with: Pulmonary edema Eventual right heart failure
Percarditis	On contrast enhanced CT scan: Enhancement of the pericardium (due to inflammation) Pericardial effusion Pericardial calcification On gadolinium-enhanced fat-saturated T1-weighted MRI: Pericardial enhancement (due to inflammation) Pericardial effusion	ST elevation PR depression	Large collection of fluid inside the pericardial sac (pericardial effusion) Calcification of pericardial sac	✔	✔	✔ (Low grade)	✔ (Relieved by sitting up and leaning forward)	–	✔	–	–	–	–	Infections: Viral (Coxsackie virus, Herpes virus, Mumps virus, HIV) Bacteria (Mycobacterium tuberculosis-common in developing countries) Fungal (Histoplasmosis) Idiopathic in a large number of cases Autoimmune Uremia Malignancy Previous myocardial infarction	May be clinically classified into: Acute (< 6 weeks) Sub-acute (6 weeks – 6 months) Chronic (> 6 months)
Pneumonia	On CT scan: (not generally indicated) Consolidation (alveolar/lobar pneumonia) Peribronchial nodules (bronchopneumonia) Ground-glass opacity (GGO) Abscess Pleural effusion On MRI: Not indicated	Prolonged PR interval Transient T wave inversions	Consolidation (alveolar/lobar pneumonia) Peribronchial nodules (bronchopneumonia) Ground-glass opacity (GGO)	✔	✔	✔	✔	–	✔	✔	–	–	–	Ill-contact Travelling Smoking Diabetic Recent hospitalization Chronic obstructive pulmonary disease	Requires sputum stain and culture for diagnosis Empiric management usually started before culture results
Vasculitis	On CT scan: (Takayasu arteritis) Vessel wall thickening Luminal narrowing of pulmonary artery Masses or nodules (ANCA-associated granulomatous vasculitis) On MRI: Homogeneous, circumferential vessel wall swelling	Right or left bundle-branch block (Churg-Strauss syndrome) Atrial fibrillation (Churg-Strauss syndrome) Non-specific ST segment and T wave changes	Nodules Cavitation	✔	✔	✔	✔	✔	✔	–	✔	✔	✔	Takayasu arteritis usually found in persons aged 4-60 years with a mean of 30 Giant-cell arteritis usually occurrs in persons aged > 60 years Churg-Strauss syndrome may present with asthma, sinusitis, transient pulmonary infiltrates and neuropathy alongwith cardiac involvement Granulomatous vasculitides may present with nephritis and upper airway (nasopharyngeal) destruction
Chronic obstructive pulmonary disease (COPD)	On CT scan: Chronic bronchitis may show bronchial wall thickening, scarring with bronchovascular irregularity, fibrosis Emphysema may show alveolar septal destruction and airspace enlargement (Centrilobular- upper lobe, panlobular- lower lobe) Giant bubbles On MRI: Increased diameter of pulmonary arteries Peripheral pulmonary vasculature attentuation Loss of retrosternal airspace due to right ventricular enlargement Hyperpolarized Helium MRI may show progressively poor ventilation and destruction of lung	Multifocal atrial tachycardia (atleast 3 distinct P wave morphologies)	Enlarged lung shadows (emphysema) Flattening of diaphragm (emphysema)	✔	✔	–	–	–	✔	✔	–	–	–	Smoking Alpha-1 antitrypsin deficiency Increased sputum production (chronic bronchitis) Cough	Alpha 1 antitrypsin deficiency may be associated with hepatomegaly

Features Specific for Congestive Heart Failure

Chronic obstructive pulmonary disease (COPD) may be confused with congestive heart failure due to similar presentations like wheezing and shortness of breath. Features specific to congestive heart failure are:

Orthopnea
Paroxysmal nocturnal dyspnea
Fine crackles on ausculatation
Chest X ray findings of cardiac enlargement, pulmonary congestion (Kerley B lines, and pleural effusion)
The peak expiratory flow is low in COPD whereas there is higher flow in heart failure
Comet-tail sign on ultrasonography is a good indicator of heart failure–related dyspnea

Features Specific for Bronchiectasis

Copious purulent sputum
Coarse crackles
Clubbing
CT findings suggestive of Bronchiectasis.

Features Specific for Bronchiolitis Obliterans

History of collagen vascular disease.
Young patient usually without a history of smoking
CT scan shows finding of mosaic attenuation and no evidence of emphysema.

Features Specific for Chronic Asthma

Chronic asthma responds well to bronchodilators.
Normal diffusion capacity of lung on pulmonary function test.

References

↑ Brenes-Salazar JA (2014). “Westermark’s and Palla’s signs in acute and chronic pulmonary embolism: Still valid in the current computed tomography era”. J Emerg Trauma Shock. 7 (1): 57–8. doi:10.4103/0974-2700.125645. PMC 3912657. PMID 24550636.
↑ “CT Angiography of Pulmonary Embolism: Diagnostic Criteria and Causes of Misdiagnosis | RadioGraphics”.
↑ Bĕlohlávek J, Dytrych V, Linhart A (2013). “Pulmonary embolism, part I: Epidemiology, risk factors and risk stratification, pathophysiology, clinical presentation, diagnosis and nonthrombotic pulmonary embolism”. Exp Clin Cardiol. 18 (2): 129–38. PMC 3718593. PMID 23940438.
↑ “Pulmonary Embolism: Symptoms – National Library of Medicine – PubMed Health”.
↑ Ramani GV, Uber PA, Mehra MR (2010). “Chronic heart failure: contemporary diagnosis and management”. Mayo Clin. Proc. 85 (2): 180–95. doi:10.4065/mcp.2009.0494. PMC 2813829. PMID 20118395.
↑ Blinderman CD, Homel P, Billings JA, Portenoy RK, Tennstedt SL (2008). “Symptom distress and quality of life in patients with advanced congestive heart failure”. J Pain Symptom Manage. 35 (6): 594–603. doi:10.1016/j.jpainsymman.2007.06.007. PMC 2662445. PMID 18215495.
↑ Hawkins NM, Petrie MC, Jhund PS, Chalmers GW, Dunn FG, McMurray JJ (2009). “Heart failure and chronic obstructive pulmonary disease: diagnostic pitfalls and epidemiology”. Eur. J. Heart Fail. 11 (2): 130–9. doi:10.1093/eurjhf/hfn013. PMC 2639415. PMID 19168510.
↑ Takasugi JE, Godwin JD (1998). “Radiology of chronic obstructive pulmonary disease”. Radiol. Clin. North Am. 36 (1): 29–55. PMID 9465867.
↑ Wedzicha JA, Donaldson GC (2003). “Exacerbations of chronic obstructive pulmonary disease”. Respir Care. 48 (12): 1204–13, discussion 1213–5. PMID 14651761.
↑ Nakawah MO, Hawkins C, Barbandi F (2013). “Asthma, chronic obstructive pulmonary disease (COPD), and the overlap syndrome”. J Am Board Fam Med. 26 (4): 470–7. doi:10.3122/jabfm.2013.04.120256. PMID 23833163.
↑ Khandaker MH, Espinosa RE, Nishimura RA, Sinak LJ, Hayes SN, Melduni RM, Oh JK (2010). “Pericardial disease: diagnosis and management”. Mayo Clin. Proc. 85 (6): 572–93. doi:10.4065/mcp.2010.0046. PMC 2878263. PMID 20511488.
↑ Bogaert J, Francone M (2013). “Pericardial disease: value of CT and MR imaging”. Radiology. 267 (2): 340–56. doi:10.1148/radiol.13121059. PMID 23610095.
↑ Gharib AM, Stern EJ (2001). “Radiology of pneumonia”. Med. Clin. North Am. 85 (6): 1461–91, x. PMID 11680112.
↑ Schmidt WA (2013). “Imaging in vasculitis”. Best Pract Res Clin Rheumatol. 27 (1): 107–18. doi:10.1016/j.berh.2013.01.001. PMID 23507061.
↑ Suresh E (2006). “Diagnostic approach to patients with suspected vasculitis”. Postgrad Med J. 82 (970): 483–8. doi:10.1136/pgmj.2005.042648. PMC 2585712. PMID 16891436.
↑ Stein PD, Dalen JE, McIntyre KM, Sasahara AA, Wenger NK, Willis PW (1975). “The electrocardiogram in acute pulmonary embolism”. Prog Cardiovasc Dis. 17 (4): 247–57. PMID 123074.
↑ Warnier MJ, Rutten FH, Numans ME, Kors JA, Tan HL, de Boer A, Hoes AW, De Bruin ML (2013). “Electrocardiographic characteristics of patients with chronic obstructive pulmonary disease”. COPD. 10 (1): 62–71. doi:10.3109/15412555.2012.727918. PMID 23413894.
↑ Stein PD, Matta F, Ekkah M, Saleh T, Janjua M, Patel YR, Khadra H (2012). “Electrocardiogram in pneumonia”. Am. J. Cardiol. 110 (12): 1836–40. doi:10.1016/j.amjcard.2012.08.019. PMID 23000104.
↑ Hazebroek MR, Kemna MJ, Schalla S, Sanders-van Wijk S, Gerretsen SC, Dennert R, Merken J, Kuznetsova T, Staessen JA, Brunner-La Rocca HP, van Paassen P, Cohen Tervaert JW, Heymans S (2015). “Prevalence and prognostic relevance of cardiac involvement in ANCA-associated vasculitis: eosinophilic granulomatosis with polyangiitis and granulomatosis with polyangiitis”. Int. J. Cardiol. 199: 170–9. doi:10.1016/j.ijcard.2015.06.087. PMID 26209947.
↑ Dennert RM, van Paassen P, Schalla S, Kuznetsova T, Alzand BS, Staessen JA, Velthuis S, Crijns HJ, Tervaert JW, Heymans S (2010). “Cardiac involvement in Churg-Strauss syndrome”. Arthritis Rheum. 62 (2): 627–34. doi:10.1002/art.27263. PMID 20112390.

Epidemiology and Demographics

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References

Risk Factors

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Overview

Risk Factors

Patients with alpha 1-antitrypsin deficiency (A1AD) are more likely to suffer from emphysema. A1AD allows inflammatory enzymes (such as elastase) to destroy the alveolar tissue. Most A1AD patients do not develop clinically significant emphysema, but smoking and severely decreased A1AT levels (10-15%) can cause emphysema at a young age. The type of emphysema caused by A1AD is known as panacinar emphysema (involving the entire acinus) as opposed to centrilobular emphysema, which is caused by smoking. Panacinar emphysema typically affects the lower lungs, while centrilobular emphysema affects the upper lungs. A1AD causes about 2% of all emphysema. Smokers with A1AD are at the greatest risk for emphysema. Mild emphysema can often develop into a severe case over a short period of time (1–2 weeks).

References

Screening

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References

Natural History, Complications, and Prognosis

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Overview

Emphysema is an irreversible degenerative condition. The most important measure that can be taken to slow the progression of emphysema is for the patient to stop smoking and avoid all exposure to cigarette smoke and lung irritants.

Prognosis

Emphysema is an irreversible degenerative condition. The most important measure that can be taken to slow the progression of emphysema. Pulmonary rehabilitation can be very helpful to optimize the patient’s quality of life and teach the patient how to actively manage his or her care.

Emphysema is also treated by supporting the breathing with anticholinergics, bronchodilators and (inhaled or oral) steroid medication, and supplemental oxygen as required. Treating the patient’s other conditions including gastric reflux and allergies may also improve lung function. Supplemental oxygen used as prescribed (20+ hours/day) is the only non-surgical treatment which has been shown to prolong life in emphysema patients. Other medications are being researched. There are lightweight portable oxygen systems which allow patients increased mobility. Patients fly, cruise, and work while using supplemental oxygen.

Lung volume reduction surgery (LVRS) can improve the quality of life for certain carefully selected patients. It can be done by several different methods, some of which are minimally invasive. In July of 2006 a new treatment, placing tiny valves in passages leading to diseased lung areas, was announced to have good results- but 7% of patients suffered from partial lung collapse. The only known “cure” for emphysema is a lung transplant, although few patients are strong enough physically to survive the surgery. The combination of a patient’s age, oxygen deprivation and the side-effects of the medications used to treat emphysema cause damage to the kidneys, heart and other organs. Transplants also require the patient to take an anti-rejection drug regimen which suppresses the immune system and creates other medical problems.

A study published by the European Respiratory Journal suggests that tretinoin (commercially available as Accutane, an anti-acne drug) derived from vitamin A can reverse the effects of emphysema in mice by returning elasticity (and regenerating lung tissue through gene mediation) to the alveoli.^[1]^[2] While vitamin A consumption is not known to be an effective treatment or prevention for the disease, this research could in the future lead to a cure. A newer follow-up study done in 2006 found inconclusive results (“no definitive clinical benefits”) using Vitamin A (retinoic acid) in treatment of emphysema in humans and stated that further research is needed to reach conclusions on this treatment.^[3]

References

↑ Mao J, Goldin J, Dermand J, Ibrahim G, Brown M, Emerick A, McNitt-Gray M, Gjertson D, Estrada F, Tashkin D, Roth M (2002). “A pilot study of all-trans-retinoic acid for the treatment of human emphysema”. Am J Respir Crit Care Med. 165 (5): 718–23. PMID 11874821.
↑ “Vitamin may cure smoking disease”. BBC News. December 22, 2003. Retrieved 2006-11-18. Check date values in: |date= (help)
↑ Roth M, Connett J, D’Armiento J, Foronjy R, Friedman P, Goldin J, Louis T, Mao J, Muindi J, O’Connor G, Ramsdell J, Ries A, Scharf S, Schluger N, Sciurba F, Skeans M, Walter R, Wendt C, Wise R (2006). “Feasibility of retinoids for the treatment of emphysema study”. Chest. 130 (5): 1334–45. PMID 17099008.

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Diagnosis

Treatment

Case Studies

Case #1

Related Chapters

Template:WikiDoc Sources

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[1] Mao J, Goldin J, Dermand J, Ibrahim G, Brown M, Emerick A, McNitt-Gray M, Gjertson D, Estrada F, Tashkin D, Roth M (2002). “A pilot study of all-trans-retinoic acid for the treatment of human emphysema”. Am J Respir Crit Care Med. 165 (5): 718–23. PMID 11874821.

[2] “Vitamin may cure smoking disease”. BBC News. December 22, 2003. Retrieved 2006-11-18. Check date values in: |date= (help)

[3] Roth M, Connett J, D’Armiento J, Foronjy R, Friedman P, Goldin J, Louis T, Mao J, Muindi J, O’Connor G, Ramsdell J, Ries A, Scharf S, Schluger N, Sciurba F, Skeans M, Walter R, Wendt C, Wise R (2006). “Feasibility of retinoids for the treatment of emphysema study”. Chest. 130 (5): 1334–45. PMID 17099008.

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Emphysema

Overview

Historical perspective

Pathophysiology

Risk Factors

Differential Diagnosis

References

Overview

Historical Perspective

Landmark Events in the Development of Treatment Strategies

References

Overview

Classification

Panacinary (panlobular):

Centroacinary (panacinar and centriacinar):

Other types:

Congenital lobar emphysema (CLE)

Paraseptal emphysema

References

Overview

Pathophysiology

Gross Pathology

Microscopic Pathology

References

Overview

Causes

Causes by Organ System

References

Overview

Differential Diagnosis

Features Specific for Congestive Heart Failure

Features Specific for Bronchiectasis

Features Specific for Bronchiolitis Obliterans

Features Specific for Chronic Asthma

References

References

Overview

Risk Factors

References

References

Overview

Prognosis

References

Diagnosis

Treatment

Case Studies

Related Chapters

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