Post on 26-Mar-2015
Chronic obstructive bronchitis and emphysema
chronic obstructive airway disease(COAD, COLD)
( chronic obstructive pulmonary disease )
COPD
COPD
emphysema bronchitis „pink puffer” „blue bloater”
Percent Change in Age-Adjusted Death Rates, U.S., 1965-1998Percent Change in Age-Adjusted Death Rates, U.S., 1965-1998
00
0.50.5
1.01.0
1.51.5
2.02.0
2.52.5
3.03.0
Proportion of 1965 Rate Proportion of 1965 Rate
1965 - 19981965 - 1998 1965 - 19981965 - 1998 1965 - 19981965 - 1998 1965 - 19981965 - 1998 1965 - 19981965 - 1998
–59%–59% –64%–64% –35%–35% +163%+163% –7%–7%
CoronaryHeart
Disease
CoronaryHeart
Disease
StrokeStroke Other CVDOther CVD COPDCOPD All OtherCauses
All OtherCauses
Evidence-based medicine
(The Global Burden of Disease study)
(Science 1996; 274:740-743.)
4-7% of adult population ( 600 million patients
worldwide)
Prevalence expected to rise 3x in 10 years.
By 2020, it becomes the 3rd most frequent cause of
death ( 4,7 million cases of death – WHO, 1999)
Epidemiology
COPD morbidityin Hungary
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100
150
200
250
2000 2001 2002 2003 2004 2005 2006 2007
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Új betegek Összes regisztrált
COPD is a preventable and treatable disease state characterized by airflow limitation that is not fully reversible. The airflow limitation is usually progressive and associated with an abnormal inflammatory response of the lungs to noxious particles or gases, primarly caused by cigarette smoking. Although COPD affects the lungs, it also produces significant systemic consequences.
ATS/ERS Task Force, 2004
Definition
CIBA Guest Symposium: Terminology, definitions and classifications of chronic
pulmonary emphysema and related conditions (1959)
1./ Obstructive emphysema: abnormal permanent
enlargement of the airspaces distal to the terminal bronchioles, accompanied by destruction of the alveolar walls and without obvious fibrosis.
2./ Chronic bronchitis: the presence of chronic productive cough for 3 months in each of 2 successive years in a patient in whom other causes (heart failure, tbc, bronchiectasis, tumor, lung abscess) of chronic cough have been excluded.
Differential diagnosis of airway obstruction
Chronicbronchitis
Emphysema
Asthma
Airflow obstruction
COPD
Adapted from Snider 1995
Etiology: host factors
Etiology: acquired risk
Effect of smoking on annual decline in lung
function Fletcher C, Peto R: BMJ 1977:i: 1645
Alveolar macrophage
neutrophil chemotactic factorscytokines ( IL-8 )mediators ( LTB4 )
neutrophil
proteázokproteases
neurophil elastasecathepsinesmatrix metalloproteinases
proteaseinhibitors
increased mucus production( chronic bronchitis )
alveolar destruction
( emphysema)
?CD8+lymphocyte
alfa1-antitrypsinSLPI
-
Groups CD8 CD4 CD8/CD4
Healthy nonsmoker 112.8 92.0 1.3
Stable-phase CB 170.6 13.0* 11.8*
Exacerbated CB 121.7 40.1* 4.3§
* p<0.05 with healthy nonsmokers§ p<0.05 with stable CB
T lymphocytes in COPD
Zhu J et al. AJRCCM 2001; 164: 109-16
Cells orchestrating the inflammation in COPD
Oxidativ stress
epithel, macroph.
Pathology
• Large airways: goblet cell metaplasia, increased
mucus production
• Medium and small airways ( 7-9. generation):
inflammation similar to asthma in certain patients
• Small airways ( 13 - 15. generation) : bronchial wall
inflammation, degeneration, fibrosis
• Alveoli: elastin loss and alveolar surface loss
Loss of alveolar attachmentsin smokers
Saetta et al. ARRD 1985
Normal Smoker
Airway muscle thicknessIncrease in COPD
Non-smoker COPD
Saetta. 1998
Small airways in COPDBarnes, NEJM,2004
Causes of Airflow Limitation
• Irreversible
– Fibrosis and narrowing of the airways
– Loss of elastic recoil due to alveolar destruction
– Destruction of alveolar support that maintains patency of small airways
Causes of Airflow Limitation
• Reversible
– Accumulation of inflammatory cells, mucus, and plasma exudate in bronchi
– Smooth muscle contraction in peripheral and central airways
– Dynamic hyperinflation during exercise
Airflowlimitation
=Driving pressure (parenchyma)
Resistance (small airways)
27
Low VA/Q areasHigh VA/Q areas
Alveolar attachments loss
Small airways narrowing
EMPHYSEMA
Airway wall thickening
SMALL AIRWAYS ABNORMALITIES
Barberà et al. ARRD 1990
Alveolar wall destruction
Air space enlargement
Capillary network reduction
Structure - function relationshipsin COPD
. . . .
COPD asthma neutrophils
no AHR*
no bronchodilation
no corticosteroid effect
10 – 40 %
eosinophils AHR*
good bronchodilator effect
good corticosteroid effect
“ Wheezy bronchitis ”
*AHR= airway hyperreactivity
reversibility threshold: 12 –15% (>200ml) FEV1-increase
Characteristics of phenotypes bronchitis emphysema
Dynamic lung volumes decreased decreased ( FEV1 , FEV1/FVC)
Static lung volumes
TLC normal or mild increase increased RV moderate increase increasd
Diffusion capacity normal or mild decreased decrease
Blood gas hypoxaemia, hypercapnia hypoxaemia in end-stage
exercise hypoxaemia: no change, improves hypoxaemia or deteriorates deteriorates
Cor pulmonale frequently seldom
Classification ( GOLD 2006 )
FEV1 (ref%* ) symptoms
cough, sputum mild 80 % morning sputum,
( FEV1/FVC 70% ) minimal breathing dyscomfort
moderate 50 - 80 % dyspnea on moderate exertion with or without wheezing,
discolored sputum, severe 30 – 50 % acute worsening with infection, with
significant erosion of QoL
very severe < 30% n cough, wheezing, breathlessness on minimal exertion
signs of RHF, significantly impaired QoL
Pharm.spir.
Beta-2 agonist
Parasympatho-lytics
Xantin derivate
Systemic consequences/comorbiditiesin COPD
Systemic consequences
Életminőség
e.g. Muscle atrophy/wasting, CHD depression, osteoporosis, anaemia
Air trappingExpiratory flow limitation
Dyspnea
Inactivity
Hyperinflation
Reduced exercisetolerance
COPDCOPD
Deconditioning
COPD
Exacerbation
Airway inflammation and systemic consequences in COPD (theory)
Muscle wasting/atrophy
Inzulin resistance,II. type diabetes
Osteoporosis
CRPCardiovascularevents
TNF IL-6
Liver
?
Tüdő
Localinflammation
GOLD Workshop Report
Four components of COPD Management
GOLD Workshop Report
Four components of COPD Management
1. Asses and monitor disease
2. Reduce risk factors
3. Manage stabil COPD Education PharmacologicGyógyszeres Non-pharmacologic
4. Manage exacerbations
1. Asses and monitor disease
2. Reduce risk factors
3. Manage stabil COPD Education PharmacologicGyógyszeres Non-pharmacologic
4. Manage exacerbations
Effects of smoking intervention and the use of aninhaled anticholinergic bronchodilator on the rateof decline of FEFV1Anthonisen N.R. és mtsai. JAMA 1994: 272, 1497-1505.
Smoking cessation is the only intervention which may retard the steep loss in lung function in COPD
1/3 of patients are able to do this(nicotin replacement, bupropion)
I. mild II. moderate III. severe IV. very severe
airway obstruction (FEV1/FVC < 70%)
FEV1 80% 50% FEV1 < 80% 30% FEV1 < 50% FEV1 < 30% or
without or with symptoms chronic respiratory or right heart failure
Avoidance of risk factors, influenza vaccination
Short acting anticholinergic and/or 2-agonist as needed
One or more long acting bronchodilators,
rehabilitation
inhalative corticosteroids( 3 exacerbation in the previous 3 years)
longterm oxigen treatment(chronic respiratoryy failure)
Surgical treatment ?Treatment of COPD
(GOLD 2003)
Respiratory insufficiency in COPD
pink puffer blue bloater partial global (hypoxaemic/transfer failure) (pump-, ventilatory failure)
acute exacerbation
Non-invasive mechanical ventilation in respiratory insufficiency
Main symptomps in acute exacerbation of COPD
increased dyspnea
wheezing, chest tightness, increased cough and sputum purulence
+/-
reduced exercise tolerance, fever , change in chest x-ray, leukocytosis
+/-
malice, disturbed sleep, daytime sleepiness, depression, confusion (CO2 retention)
AE COPD hospitalisation re-admission death
% of hospitalised patients
Endpoint Denmark1
(n=300)a
The Netherlands2
(n=171)a
Spain3
(n=135)a
USA4
(n=1016)
Mortality
In hospital 9 8 — 11
3 months 19 16 — —
1 year 36 23 22 43
Re-admission
3 months 14 — — —
1 year 46 55 — —
1Eriksen, Ugeskr Laeger 2003
2Groenewegen, Chest 2003
3Almagro, Chest 2002
4Connors, Am J Respir Crit Care Med 1996
Exacerbations of COPD
• Viral infections (Rhino,Infl, Parainfl,Adeno, RSV)• Bacterial infections (H.i.,S.p.,M.c.,P.a.,S.a.,
Enterobact.), atypical( M.p., C.p.)• Inhalation of environmental irritants (NO2,
SO2, PM10, ozone)• deviation from diet• Predisposing factors (smoking, severe
comorbidity, bacterial colonisation in the stable phase)
New strains of bacteria and AE COPDSethi, NEJM 2002
H.influenzae withnew antigen structure
Immune andinflammatory response AE
Role of antibiotics - „fall and rise „ hypothesisMiravitlles M, ERJ 2002
Are antibiotics needed? (Procalcitonin Guided Therapy)
Christ Crain, Lancet 2004
0
20
40
60
80
100
CAP AECOPD Bronchitis Asthma
An
tib
ioti
c p
resc
rip
tio
ns
(%)
Others
Standard group Procalcitonin group
45/45
38/42 27/31
11/29
16/31
4/28
2/3
0/10
9/9
2/15
P=0.03 P<0.0001 P=0.003 P=0.003 P<0.0001
PCT (ng/ml) - < 0,1 not recommanded - > 0,5 strongly recommanded
Antibacterial treatment of AECOPD
pathogens treatment
1./ acute tracheobronchitis atipical agent ? macrolide ?
2./ Chronic bronchitis H. influenzae aminopenicillin/cv without comorbidity M. catarrhalis cefalo. II, III ( FEV1 > 50% ) res. S. pneumoniae ? makrolide II.
3./ Chronic bronchitis with „ „ comorbidity ( FEV1 < 50% ) res. Pneumococcus ! respiratory kinolon
4./ Chronic bronchial infection „ respiratory kinolon Gram-neg enterobact. Ps. eruginosa = ciprofloxacin
COPD Exacerbation - Steroids
• COPD, no steroids
• 30 pack-years
• FEV1 < 1,5 l
• Group A: Placebo
• Group B: Methylprednisolone 4x125 mg i.v. – tappering until day 14 0,7
0,750,8
0,850,9
0,951
1,051,1
1,15
0 1 2 3 14 182
FE
V1
in l
Steroid Placebo
Niewoehner DE. N Engl J Med 1999; 340: 1941-47
Antibiotic Consumption in 26 Countries
Goossens.HA. Lancet 2005; 365:579-87
Penicillin resistent S.pneumoniaeEARSS, 2006