Tujuan dari Respirasi

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Tujuan dari Respirasi

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Title: Tujuan dari Respirasi

1
Tujuan dari Respirasi
adalah untuk menyediakan oksigen bagi seluruh
jaringan tubuh dan membuang karbon dioksida ke
atmosfer
2
Hidung

Udara masuk disaring, dihangatkan dan
dilembabkan oleh mukosa respirasi.
Partikel kasar disaring oleh rambut hidung.
halus terjerat dalam lapisan mukus.
Udara masuk faring bebas debu, suhu sebanding
suhu tubuh, kelembaban hampir 100

3
Rongga torax

Paru adalah organ elastis terletak pada rongga
dada/torax.
Paru dilapisi oleh lapisan tipis kontinu yg
mengandung kolagen jar elastis yg disebut
PLEURA
Pleura Parietalis melapisi rongga dada sedang
Pleura viseralis melapisi paru .
Rongga pleura ruangan yg memisahkan pleura
parietalis viseralis
Cairan pleura lapisan tipis antara pleura
parietalis dg viseralis berfungsi memudahkan
kedua permukaan tersebut bergerak selama
pernapasan untuk mencegah pemisahan torax
paru.
Tekanan rongga pleura lt tekanan atmosfer untuk
mencegah kolaps paru.

4
Rongga torax

3 faktor yg mempertahankan tekanan negatif
intrapleura normal
Jaringan elastis paru memberikan kekuatan kontinu
yg cenderung menarik paru menjauh dr rangka
torax.
Kekuatan osmotik yg terdapat di seluruh membran
pleura.
Kekuatan pompa limfatik.
Diafragma otot berbentuk kubah yg membentuk
dasar rongga torax memisahkan rongga tersebut
dari rongga abdomen.

5
Anatomi Saluran Pernapasan
6
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7
Anatomi Saluran Pernapasan
8
Alveoli

Terdapat 2 tipe sel alveolar
Pneumosit tipe I lap tipis menyebar menutupi gt
90 daerah permukaan.
Pneumosit tipe II tanggung jawab pada sekresi
surfaktan.
Alveolus suatu gelembung gas yang dikelilingi
oleh jaringan kapiler batas antara cairan
gas membentuk tegangan muka yang cenderung
mencegah pengembangan saat inspirasi cenderung
kolaps saat ekspirasi.
Alveolus dilapisi zat lipoprotein (surfaktan)
dapat mengurangi tengangan permukaan resistensi
saat inspirasi mencegah kolaps alveolus
(expirasi).

9
LUNGS 2
Bronchopulmonary segments Lobules Alveolar wall
cell types
respiratory bronchiole
terminal bronchiole
pulmonary artery branch
alveolar sac
10
Alveoli

Pembentukan pengeluaran surfaktan oleh
pneumosit tipe II disintesis secara cepat dari
asam lemak yang diekstraksi dari darah, dg
kecepatan pergantian yg cepat. Bila aliran darah
ke paru terganggu (emboli) akibatnya jumlah
surfaktan pada daerah tersebut berkurang.
Produksi surfaktan dirangsang oleh ventilasi
aktif, volume tidal yg memadai, hiperventilasi
periodik (cepat dalam) yg dicegah oleh kons O2
yang tinggi (inspirasi).
Pemberian O2 kons tinggi jangka lama (pasien dg
ventilasi mekanik) menurunkan produksi
surfaktan menyebabkan kolaps alveolar.

11
Pernafasan terdiri dari 4 proses

Ventilasi Keluar masuknya udara karena adanya
selisih tekanan yang terdapat antara atmosfer dan
alveolus
Distribusi Pembagian udara ke cabang -cabang
bronkhus
Transportasi dan Difusi
- Transport O2 dan CO2 dalam darah dan cairan
tubuh ke dan dari sel
- Difusi O2 dan CO2 antara darah dan
alveoliPertukaran gas-gas antara alveoli dan
kapiler dipengaruhi oleh tekanan parsial O2 CO2
dalam atmosfer
Perfusi Aliran darah yang membawa O2 ke jaringan

12
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13
JENIS RESPIRASI

RESPIRASI EXTERNAL
O2 DIBAWA DARI UDARA LUAR SAMPAI KE KAPILER
2. RESPIRASI INTERNAL
O2 DARI KAPILER SAMPAI KE SEL PADA JARINGAN.

14
RESPIRASI EXTERNAL
15
RESPIRASI INTERNAL
16
INSPIRATION
Active process Boyles Law
Phrenic nerves (C3-5) Thoracic nerves (T1 T11)
17
EXPIRATION
Passive process at rest
elastic recoil surface tension
internal intercostals (11 pairs)
external abdominal oblique
internal abdominal oblique
transversus abdominis
rectus abdominis
760 mmHg
762 mmHg
18
Perubahan diafragma saat inspirasi ekspirasi
19
Otot Pernapasan
20
COMPLIANCE
Compliance is the ease with which the lungs and
thoracic wall can be expanded during inspiration.
Related to two factors
elasticity surface tension
Compliance is decreased with any condition that
destroys lung tissue (emphysema) fills lungs with
fluid (pneumonia) produces surfactant deficiency
(premature birth, near-drowning) interferes with
lung expansion (pneumothorax)
21
PULMONARY VOLUMES, CAPACITIES, AND RATES
maximum inspiration
6000 ml
5000 ml
IRV
VC
TLC
4000 ml
3000 ml
TV
2000 ml
ERV
1000 ml
RV
maximum expiration
SPIROGRAM
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23
Kontrol Pernapasan

Otot pernapasan diatur oleh neuron reseptor
pada pons medula oblongata.
Faktor utama pengaturan pernapasan respon dari
pusat kemoreseptor dalam pusat pernapasan
terhadap tekanan persial CO2 dan pH darah arteri

24
Kontrol Pernapasan

Persarafan parasimpatis/ kolinergik (mll nervus
fagus) menyebabkan kontraksi otot polos bronkus
shg menyebabkan bronkokonstriksi peningkatan
sekresi kel mukosa sel goblet.
Rangsangan simpatis ditimbulkan epinefrin mll
reseptor adrenergik-beta2 menyebabkan relaksasi
otot polos bronkus, bronkodilatasi,
berkurangnya sekresi bronkus.
Sistem saraf nonkolinergik non adrenergik (NANC)
melibatkan berbagai mediator seperti ATP, oksida
nitrat, substance P, dan VIP (vasoactive
intestinal peptide) respon penghambatan, meliputi
bronkodilatasi, dan diduga berfungsi sebagai
penyeimbang terhadap fungsi pemicuan oleh sistem
kolinergik.

25
Kontrol Pernapasan
26
Signs and Symptoms of Pulmonary Disease

Dyspnea subjective sensation of uncomfortable
breathing, feeling short of breath
Ranges from mild discomfort after exertion to
extreme difficulty breathing at rest.
Usually caused by diffuse and extensive rather
than focal pulmonary disease.

27
Derajat Dyspnea
28
Dyspnea cont.

Due to
Airway obstruction
Greater force needed to provide adequate
ventilation
Wheezing sound due to air being forced through
airways narrowed due to constriction or fluid
accumulation
Decreased compliance of lung tissue

29
Signs of dyspnea

Flaring nostrils
Use of accessory muscles in breathing
Retraction (pulling back) of intercostal spaces

30
BATUK

Batuk merupakan gejala tersering penyakit
pernapasan
Batuk merupakan reflex pertahanan yang timbul
akibat iritasi percabangan trakeobronkial
Batuk yang berlangsung lebih dari 3 minggu harus
diselidiki untuk memastikan penyebabnya.
Bronkhitis kronik, asma, tubercolosis dan
pneomonia merupakan penyakit yang secara tipikal
memiliki batuk sebagai gejala yang mencolok

31
Cough may result from

Inflammation of lung tissue
Increased secretion in response to mucosal
irritation
Inhalation of irritants
Intrinsic source of mucosal disruption such as
tumor invasion of bronchial wall
Excessive blood hydrostatic pressure in pulmonary
capillaries
Pulmonary edema excess fluid passes into airways

When cough can raise fluid into pharynx, the
cough is described as a productive cough, and the
fluid is sputum.
Production of bloody sputum is called hemoptysis
Usually involves only a small amount of blood
loss
Not threatening, but can indicate a serious
pulmonary disease
Tuberculosis, lung abscess, cancer, pulmonary
infarction.

Cough that does not produce sputum is called a
dry, nonproductive or hacking cough.
Acute cough is one that resolves in 2-3 weeks
from onset of illness or treatment of underlying
condition.
Us. caused by URT infections, allergic rhinitis,
acute bronchitis, pneumonia, congestive heart
failure, pulmonary embolus, or aspiration.

A chronic cough is one that persists for more
than 3 weeks.
In nonsmokers, almost always due to postnasal
drainage syndrome, asthma, or gastroesophageal
reflux disease
In smokers, chronic bronchitis is the most common
cause, although lung cancer should be considered.

35
SPUTUM

Pembentukan sputum
Orang dewasa normal mukus sekitar 100 ml
dalam saluran napas tiap hari Mukus diangkut
menuju faring dengan gerakan pembersihan silia
yang melapisi saluran pernapasan bila mukus
berlebihan proses pembersihan tidak efektif
mukus tertimbun membran mukosa akan terangsang
mukus dibatukkan keluar sebagai sputum.

36
SPUTUM

Sputum yang berwarna kekuning-kuningan
menunjukkan infeksi.
Sputum yang berwarna hijau merupakan petunjuk
penimbunan nanah timbul karena adanya
verdoperoksidase yang dihasilkan oleh
polimorfonuklear (PMN).
Sputum yang berwarna merah muda dan berbusa
merupakan tanda edema paru akut.
Sputum yang berlendir lekat dan warna abu-abu
atau putih merupakan tanda bronkhitis kronik.
Sedangkan sputum yang berbau busuk merupakan
tanda abses paru atau bronkiektasis.

37
Cyanosis

When blood contains a large amount of
unoxygenated hemoglobin, it has a dark red-blue
color which gives skin a characteristic bluish
appearance.
Most cases arise as a result of peripheral
vasoconstriction result is reduced blood flow,
which allows hemoglobin to give up more of its
oxygen to tissues- peripheral cyanosis.
Best seen in nail beds
Due to cold environment, anxiety, etc.

Central cyanosis can be due to
Abnormalities of the respiratory membrane
Mismatch between air flow and blood flow
Expressed as a ratio of change in ventilation (V)
to perfusion (Q) V/Q ratio
Pulmonary thromboembolus - reduced blood flow
Airway obstruction reduced ventilation
In persons with dark skin can be seen in the
whites of the eyes and mucous membranes.

39
Jari Tabuh

Jari tabuh adalah perubahan bentuk normal falang
distal dan kuku tangan dan kaki serta ditandai
dengan
Kehilangan sudut kuku yang normalnya 160 derajat.
Rasa halus berongga pada dasar kuku.
Ujung jari menjadi besar.
jari tabuh berhubungan dengan peyakit paru (TB,
abses paru, atau kanker paru). Penyakit
kardiovaskuler (tetralogi fallot atau
endokarditis infektif) atau penyakit hati kronik

40
Next

2. Hipoksia (O2 yang tidak adekuat dalam tingkat
jaringan) dan Hipoksemia (PaO2 dibawah normal
normal 80-100 mmhg).
Tanda dan gejala hipoksemia dan hipoksia tidak
spesifik dan mencakup takipnea, dispnea, sakit
kepala, pikiran yang bingung, takikardi, dan
sianosis.
3. Hipokapnia dan hiperkapnia
Hipokapnia didefinisikan sebagai menurunnya
PaCO2 lt35 mmhg. Penyebab langsung selalu
hiperventilasi alveolar (eliminasi CO2 lebih
cepat daripada produksinya).
Hiperkapnia / asidosis respiratorius merupakan
meningkatnya PaCO2 gt45 mmhg. Penyebab langsung
adalah selalu hipoventilasi alveolar (kegagalan
dalam mengeliminasi CO2 secepat produksinya).

41
Pain

Originates in pleurae, airways or chest wall
Inflammation of the parietal pleura causes sharp
or stabbing pain when pleura stretches during
inspiration
Usually localized to an area of the chest wall,
where a pleural friction rub can be heard
Laughing or coughing makes pain worse
Common with pulmonary infarction due to embolism

Inflammation of trachea or bronchi produce a
central chest pain that is pronounced after
coughing
Must be differentiated from cardiac pain
High blood pressure in the pulmonary circulation
can cause pain during exercise that often
mistaken for cardiac pain (angina pectoris)

43
Respiratory Disorders

Respiratory disorder can be classified into
different group
Respiratory tract infection
Common cold,Influenza,Pneumonias,T.B
Disorder of lung inflation
Pleural pain and pleural effusion
Obstructive air way disorders
Bronchial asthma, COPD, Emphysema, Bronchitis
Pulmonary vascular disorder
Lung cancer

44
INFLUENZA

Penyakit yang disebabkan oleh virus influenza.
Gejala yang ditimbulkan antara lain pilek,
hidung tersumbat, bersin- bersin, dan tenggorokan
terasa gatal. Perlu diketahui virus iniselalu
hanya bisa menembus saluran pernafasan atas saja
, sehingga bisa disimpulkansaluran respirasi
yang lebih dalam sangat resisten immun terhadap
virus ini.

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46
Asthma

is a chronic inflammatory disorder of the airways
in which many cells and cellular elements play a
role
In susceptible individuals, this inflammation
causes recurrent episodes of wheezing,
breathlessness, chest tightness and coughing,
particularly at night or in the early morning..

Causes and Triggers
Allergies such as to pollens, mold spores, pet
dander, and dust mites
Infections (colds, viruses, flu, sinus infection)
Exercise
Aspirin or nonsteroidal anti-inflammatory drug
(NSAID) hypersensitivity, sulfite sensitivity
Use of beta-adrenergic receptor blockers
(including ophthalmic preparations)

48
Cont

Irritants such as strong odors from perfumes or
cleaning solutions, air pollution, and tobacco
smoke
Weather (changes in temperature and/or humidity,
cold air)
Strong emotions such as anxiety, laughter,
crying, and stress
Industrial triggers (wood, grain dust, cotton
dust, isocyanate containing paints, aluminum,
hair spray, penicillins)
Beta blockers even in form of eye drops

49
Comorbid condition

Gastroesophageal reflux disease
Chronic sinusitis or rhinitis
OSA (obstructive sleep apnoe)
Obesity
Alergy bronchopulmonary aspergilosis

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51
ASMA

Asma ekstrinsik (alergik)
(alergen, spt debu,blu halus, serbuk)
intrinsik (idiopatik)
(fak nonspesifik spt flu, latihan fisik,
emosi dapat memicu serangan asma)
campuran
(Komponen asma instrinsikEkstrinsik)

52
Two main pathophysiologic types of asthma
Extrinsic asthma common in children, associated
with a genetic predisposition and is precipitated
by a known allergens. It is related to the
formation of antibody IgE in the body
53
Immunological Mechanisms in Respiratory Diseases
54
Patofisiologi Asma
55

Intrinsic asthma tend to develop in adulthood,
and symptoms are triggered by non-allergic
factors such as
Viral infection, irritants which cause epithelial
damage and mucosal inflammation
Emotional upset which mediates excess
parasympathetic input
Exercise which causes water ad heat loss from the
airways

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Pathophysiology
Release of inflammatory mediator produce
bronchial smooth muscle spasm
Vascular congestion
Increase vascular permeability
Edema formation
Production of thick tenacious mucus
Impair mucociliary function
Thickening of air way wall
Increase response of bronchial smooth muscle
Damage epithelium produce hyper responsiveness
and obstruction

58
Faktor2 yang mengakibatkan obstruksi ekspirasi
pada asma bronkial. A. Potongan melintang dari
bronkiolus yang mengalami oklusi akibat spasme
otot, mukosa yang membengkak, dan mukus dalam
lumen, B . Potongan memanjang dari bronkiolus
gambar
59
The mechanism of inflammation in asthma can
be Acute early recruitment of cells to the
airways Subacute resident and recruited cells
are activated to cause a more persistent pattern
of inflammation Chronic cells damage is
persistent and subject to ongoing repair,
permanent change in the airway may occur with
airway remodelling
60
Gambaran klinik

Batuk yang memburuk pada malam hari
Sesak nafas
Mengi atau Wheezing (a high-pitched whistling
sound that occurs when exhaling) due to turbulent
airflow through a narrowed airway
nafas pendek tersengal-sengal.
Produksi sputum meningkat, sulit tidur
Hambatan pernafasanan reversibel
Adanya peningkatan gejala pada saat olahraga,
infeksi virus, eksposur terhadap alergen dan
perubahan musim.
Terbangun di malam hari krn gejala seperti di
atas .

61
Investigations

Pulmonary function testing (spirometry) Forced
expiratory volume (FEV)
Methacholine or histamine challenge testing
Exercise testing
Peak expiratory flow rate monitoring

62
Forced expiratory volume (FEV)
Normal subject
Volume (litres)
Asthma patient
FVC
FEV1
1
2
3
4
Time (second)
63
Impairment
64
Drug categories
Bronchodilators Provide symptomatic relief of
bronchospasm due to acute asthma exacerbation
(short-acting agents) or long-term control of
symptoms (long-acting agents)
Leukotriene receptor antagonists Direct
antagonist of mediators responsible for airway
inflammation in asthma
Corticosteroids Highly potent agents that are
the primary choice for treatment of chronic
asthma and prevention of acute asthma
exacerbations. Numerous inhaled corticosteroids
are used for asthma and include beclomethasone
(Beclovent, Vanceril), budesonide (Pulmicort
Turbuhaler), flunisolide (AeroBid), fluticasone
(Flovent), and triamcinolone (Azmacort).
65
Mast cell stabilizers Prevent the release of
mediators from mast cells, which results in
airway inflammation and bronchospasm. Indicated
for maintenance therapy of mild-to-moderate
asthma or prophylaxis for EIA
5-Lipoxygenase inhibitors Inhibit the
formation of leukotrienes. Leukotrienes activate
receptors that may be responsible for events
leading to the pathophysiology of asthma,
including airway edema, smooth muscle
constriction, and altered cellular activity
associated with inflammatory reactions
66
Three Steps of Asthma Treatment Step 1 -
Control bronchospasm with short- acting b2
agonists or long-acting salmeterol Step 2 -
Control inflammation with inhaled corticosteroids
or leukotriene antagonist Step 3 - Control
severe exacerbation with oral corticosteroids
67
Step 1 Is to control bronchospasm with inhaled
b2 agonists. Short-acting b2agonists are
appropriate for patients with mild, intermittent
asthma who do not require daily maintenance
therapy. Inhaled b2 agonists are effective, work
quickly within 2 to 3 minutes and provide acute
relief for up to 4 to 6 hours Remember that
short-acting b2 agonists are indicated for use as
rescue bronchodilators during acute attacks of
bronchospasm.
68
When daily maintenance therapy is needed for more
persistent symptoms, the long-acting b2 agonist
salmeterol is an excellent and effective choice
in treatment Salmeterol can be taken once or
twice a day as an inhaled bronchodilator The
bronchodilating action of salmeterol is delayed
in onset (20-30 minutes) but frequently lasts 8
to 12 hours when taken properly.
69
Step 2 Is to control inflammation when there is
evidence of persistent or frequently recurring
symptoms with inhaled corticosteroids or
leukotriene antagonists, or the non-steroidal
anti-inflammatory agents cromolyn sodium or
nedocromil sodium This is maintenance
anti-inflammatory therapy without any direct
bronchodilator effect.
70
Inhaled corticosteroids and oral corticosteroids
are used to control inflammation in asthma
Corticosteroids prevent the migration of
inflammatory cells and increase the
responsiveness of airway b2 receptors Corticostero
ids have been shown to reduce acute bronchial
hyperresponsiveness to irritants and may
chronically blunt the early airway response to
irritants with continued use The new inhaled
corticosteroid, fluticasone propionate, appears
to possess a higher potency than other inhaled
corticosteroids. Like other inhaled
corticosteroids, fluticasone is indicated for the
maintenance treatment of asthma as prophylactic
therapy Recent studies have shown that it can
reduce oral prednisone use while improving asthma
control.
71
Inhaled nonsteroidal anti-inflammatory drugs like
cromolyn or nedocromil may reduce symptoms in
patients with mild to moderate asthma They are
frequently prescribed in children and in adults
with allergic asthma They inhibit the activation
of mast cells and eosinophils, block inhaled
neurogenic stimuli, and may reduce airway
temperature changes that can trigger an asthma
attack Nedocromil may allow the reduction of
corticosteroid use in selected patients
72
Step 3 Is to control severe exacerbations with
systemic oral corticosteroids, i.e. prednisone 1
mg/kg or 40 to 60 mg daily for 1 to 2 weeks Many
patients are steroid-dependent and frequently
develop cushingnoid features such as
hyperglycemia, fluid retention, weight gain with
moon facies, and easy bruisability
73
Anticholingeric drugs like ipratropium may have
an adjunctive role in asthma therapy They block
vagal pathways and produce bronchodilation by
decreasing airway vagal tone They are less potent
than b2 agonists and have a slow onset of
action While they may reduce mucus secretion,
there is no evidence that they modulate the
inflammatory response
74
Oral theophylline and intravenous aminophylline
were once the mainstay of asthma treatment,
especially nocturnal asthma Originally thought to
act as a phosphodiesterase inhibitor to increase
cAMP, these methylxanthines are now though to
antagonize adenosine, a mediator of acute
inflammation Theophyllines reverse bronchospasm,
enhance mucociliary clearance, and increase
diaphragmatic contraction
75
However, theophylline is probably useful as an
adjunct to b2 agonists and anti-inflammatory
drugs Any benefit may be diminished somewhat by a
narrow therapeutic range (5 to 15 µg/ml) which
can lead to serious and toxic consequences, e. g.
seizures, tachyarrhythmias when exceeded Its use
in the emergency treatment of asthma is not
recommended but recent evidence suggest it may
modulate chronic asthma symptoms more effectively
than is generally perceived.
76
The use of cytotoxic agents, e. g. methotrexate,
cyclosporine can not be recommended unless
standard therapy with b2 agonists and
anti-inflammatory drugs have failed
77
leukotriene receptor antagonists, Specifically,
LTD4 receptor antagonist and 5-lipoxygenase
inhibitors can completely block the acute phase
response and block part of the delayed phase
response Blocking the generation of leukotrienes
or blocking their actions on cells may be helpful
in control of asthma and treatment of asthma
attacks
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79
DEFINISI PPOM/COPD

Penyakit obstruksi saluran nafas kronis dan
progresif yg ditandai oleh hambatan aliran udara
yg bersifat non reversibel atau reversibel
sebagian bersifat progresif berhubungan dg
respons inflamasi abnormal paru thd partikel atau
gas beracun.

80
Bronkitis kronik emfisema

Meskipun bronkitis kronik dan emfisema merupakan
2 proses yg berbeda, tp penyakit ini sering
ditemukan bersama2 pada penderita COPD.
Merupakan penyebab kematian terbanyak
COPD mnyerang pria 2x lebih banyak dari wanita
karena faktor perokok
Faktor etiologi utama adalah merokok dan polusi
udara

81
FAKTOR RISIKO

Host

Lingkungan

- Genetik Defisiensi alpha 1 anti tripsin atau
antiprotease (menghambat aksi dari enzym
protease)
- Hipereaktivitas bronkus

Asap rokok (faktor risiko utama - sigaret)
Partikel debu bahan kimia perindustrian
Polusi udara
Indoor air pollution from heating and cooking
with biomass in poorly ventilated dwellings
Infeksi
Status sosial

82
PATOGENESA

Inflamasi /Keradangan kronis pd sal. napas,
parenkim paru, sistem vaskuler paru ? pe?
makrofag, limfosit T (CD8), netrofil ? release
mediator LB4, IL8, TNF
Imbalance proteinase anti proteinase
Stres oksidatif
Ketiga faktor diatas akan merusak struktur paru.

83
The theory of interplay

is that this inflammatory process which includes
alveolar macrophages in some way releases
neutrophil chemotactic factors known as (IL-8 )
causing neutrophils to emigrate from the blood
space into the airspace to release elastase .
In normal circumstances alpha-1-antitrypsin
binds to the elastase and prevents it from
binding to elastin thus destroying the structure
of the lungs.

84
Neutrophils

in the blood and air space release more active
oxygen species in smokers, than in non smokers,
these together with the 1017 oxidants in inhaled
cigarette smoke inactivate the alpha-1-antitrypsin
at its active site.
This reduces the ability of alpha-1-antitrypsin
to bind to elastase by a factor of approximately
2000 allowing active ealstase to bind to elastin
and cause the enlargement of the airspace that is
seen in emphysema P-Selectin , L-seletin
adhesions are important for the transport of
inflammatory cells in the systemic circulation .

85
KLINIS

Keluhan utama sesak napas, batuk, dahak
Sesak timbul progresif sp mengganggu aktivitas,
men-dadak memberat bila tjd eksaserbasi
Batuk kronis, memberat pagi hari, dahak mukoid ?
purulen bila eksaserbasi
Suara mengi (wheezing)
Batuk darah ? blood-streaked purulen sputum
(eksa-serbasi)
Nyeri dada (pleuritis, pneumotoraks, emboli
paru)
Anoreksi BB menurun progresif jelek

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87
PATOLOGI

Saluran napas besar
Hipertrofi kelenjar pe ? jumlah sel Goblet ?
hipersekresi mukus
Saluran napas kecil
Recycled injury repair dinding sal. napas ?
remodeling (pe ? kolagen jar. ikat) ?
penyempitan lumen obstruksi sal. napas
Parenkim paru
Destruksi parenkim ? emfisema sentrilobuler
Vaskuler pulmonal, Penebalan dd pembuluh darah

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89
Pathophysiology

The different pathogenic mechanisms produce the
pathological changes which, in turn, give rise to
the physiological abnormalities in COPD
mucous hypersecretion and ciliary dysfunction,
airflow limitation and hyperinflation,
gas exchange abnormalities,
pulmonary hypertension,
systemic effects.

90
Pathophysiology of COPD
91
According to GINA

What is the difference between asthma and COPD
(chronic obstructive lung disease)? COPD is a
collective name for chronic bronchitis and
emphysema, two diseases that are almost always
caused by smoking. Many of the symptoms of COPD
are similar to those of asthma (e.g.
breathlessness, wheezing, production of too much
mucus, coughing).

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93
COPD/PPOM
94
BRONCHITIS KRONIS atau COPD type B

Bronkitis kronik adalah inflamasi kronis
saluran nafas yg ditandai dg udema dan
hiperplasi kelenjar sub mucosal shg terjadi
produksi mukus berlebihan ke batang bronchial
akibatnya terjadi peningkatan resistensi sal
pernafasaan
secara kronik atau berulang dengan disertai
batuk, yang terjadi hampir setiap hari selama
sekurangnya tiga bulan dalam 1 tahun selama 2
tahun berturut turut. .

95
Etiologi

Faktor lingkungan
- Merokok
- Pekerjaan
- Polusi udara
Infeksi berulang
Faktor host
- usia
- jenis kelamin
- penyakit paru yang
sudah ada

96
CHRONIC BRONCHITIS

Chronic bronchitis is defined as "persistent
cough with sputum production for at least 3
months in at least two consecutive years".
The most important cause of chronic bronchitis is
recurrent irritation of the bronchial mucosa by
inhaled substances, as occurs in cigarette
smokers.
The pathological hallmarks of chronic bronchitis
are congestion of the bronchial mucosa and a
prominent increase in the number and size of the
bronchial mucus glands. Copious mucus may be seen
within airway lumens. The terminal airways are
most susceptible to obstruction by mucus.

97
Pathophysiology of chronic bronchitis
Irritants ? Hyperplasia and
hypertrophy of mucous secreting cell
? Thick mucous
?
Air trapping
Sticky coating
? ?

Air way obstruction Impaired ciliary function
?
?
Edema Decrease
mucous clearance
? ?
Bronchial wall
thickness and Lung defense system compromise
inflammation
?
? Vulnerable for infection
? More infection more mucus
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99
CHANGES IN LUNG VOLUMES
100
VENTILATION COST

In COPD work of breathing is greater for any
given level of ventilation than normal.

SEVERE COPD
The cost of work at a given ventilation for
normal and COPD patients (ACSM, 1998)
WORK OF BREATHING
MODERATE COPD
NORMAL COPD
VENTILATION
101

Damage to the epithelium impairs the mucociliary
response that clears bacteria and mucus.
Inflammation and secretions provide the
obstructive component of chronic bronchitis.
In contrast to emphysema, chronic bronchitis is
associated with a relatively undamaged pulmonary
capillary bed.

102
Emphysema or type A COPD

Definition
Abnormal permanent enlargement of air spaces
distal to the terminal bronchioles, accompanied
by the destruction of the walls and without
obvious fibrosis
Emphysema is characterized by loss of elasticity
of the lung and abnormal permanent enlargement of
air spaces with destruction of the alveolar walls
and capillary beds.

103
EtiologiEmphysema

Smoking
the primary risk factor
Long-term smoking is responsible for 80-90 of
cases.
Prolonged exposures to harmful particles and
gases from
passive smoke,
Industrial smoke,
Chemical gases, vapors, mists fumes
Dusts from grains, minerals other materials
Alpha 1-antitrypsin deficiency gtgtemphysema
Genetics
Bronchitis
Asthma

104
Pathophysiology

Exposure to inhaled noxious particles gases
inflammation imbalance of
proteinases and anti-proteinases

Dilatation destruction mucus secretion
105
FIG. 1. Inflammatory mechanisms in COPD.
Cigarette smoke (and other irritants) activate
macrophages in the respiratory tract that release
neutrophil chemotactic factors, including IL-8
and LTB4. These cells then release proteases that
break down connective tissue in the lung
parenchyma, resulting in emphysema, and also
stimulate mucus hypersecretion. These enzymes are
normally counteracted by protease inhibitors,
including 1-antitrypsin, SLPI, and TIMP.
Cytotoxic T cells (CD8) may also be recruited and
may be involved in alveolar wall destruction.
Fibroblasts may be activated by growth factors
releases from macrophages and epithelial cells.
CTG, connective tissue growth factor COB,
chronic obstructive bronchiolitis.
106
Pathophysiology

Affects alveolar membrane
Destruction of alveolar wall
Loss of elastic recoil
Over distended alveoli
Over distended alveoli?
Damage to adjacent pulmonary capillaries
h dead space
Impaired passive expiration
? Impaired gas exchange

Impaired gas exchange
impaired expiration
h CO2 ?
Hypercapnia
Respiratory acidosis
Damaged pulmonary capillary bed
h pulmonary pressure ?
h work load for right ventricle ?
Right side heart failure (due to respiratory
pressure) ?
Cor Pulmonale

107
Gas Exchange is poor because

Loss of alveolar structure base thereby causing
decreased gas exchange surface area
Mechanically, elastance is lost due to the
constant stretching of distal airways
Consequently, these patients are very compliant,
because the natural tendency for the lung to
collapse is inadvertently lost

108

This V/Q mismatch results in relatively limited
blood flow through a fairly well oxygenated lung
with normal blood gases and pressures in the
lung, in contrast to the situation in blue
bloaters. Because of low cardiac output, however,
the rest of the body suffers from tissue hypoxia
and pulmonary cachexia. Eventually, these
patients develop muscle wasting and weight loss
and are identified as "pink puffers."

109
Diagnosis of COPD
EXPOSURE TO RISK FACTORS
SYMPTOMS
cough
tobacco
sputum
occupation
dyspnea
indoor/outdoor pollution
è
GAS DARAH ARTERI LABORATORY TEST CHEST X-RAY
SPIROMETRY
110
Spirometry Normal and COPD
111

Normally, the left side of the heart produces a
higher level of blood pressure in order to pump
blood to the body the right side pumps blood
through the lungs under much lower pressure. Any
condition that leads to prolonged high blood
pressure in the arteries or veins of the lungs
(called pulmonary hypertension) will be poorly
tolerated by the right ventricle of the heart.
When this right ventricle fails or is unable to
properly pump against these abnormally high
pressures, this is called cor pulmonale.

112
Prognosis ?

Indikator umur dan keparahan
Jika ada hipoksia dan cor pulmonale prognosis
jelek
Dyspnea, obstruksi berat saluran nafas, FEV1 lt
0.75 L (20) ?? angka kematian meningkat, 50
pasien berisiko meninggal dalam waktu 5 tahun

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Tujuan Terapi

Memperbaiki keadaan obstruksi saluran nafas
Mencegah dan mengatasi eksaserbasi akut
Menurunkan progresivitas penyakit
Meningkatkan keadaan fisik dan psikis
Menurunkan jumlah hari tidak masuk kerja
Menurunkan lama tinggal di RS
Menurunkan angka kematian

114
NON FARMAKOLOGI

Menghentikan kebiasaan merokok
Rehabilitasi paru-paru secara komprehensif dengan
OR dan latihan pernafasan
Perbaikan nutrisi
Tidak ada obat yang dapat menunda memburuknya
fungsi paru jika pasien tetap merokok

115

Kortikosteroid ?? benefit is very limited,
laporan tentang efektivitasnya masih bervariasi,
kecuali jika pasien juga memiliki riwayat asma
?? Oksigen ?? untuk pasien hipoksemia, cor
pulmonale. Digunakan jika baseline PaO2 turun
sampai lt 55 mmHg
?? Antibiotik ?? digunakan bila ada tanda
infeksi, bukan untuk maintenance therapy
?? Vaksinasi ?? direkomendasikan untuk high-risk
patients vaksin pneumococcus (tiap 5-10 th) dan
vaksin influenza (tiap tahun)
?? a1-proteinase inhibitor ?? utk pasien yang
defisiensi a1- antitripsin ?? digunakan per
minggu, masih mahal ?? contoh Prolastin

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Tahap terapi pada PPOK yang stabil

Tahap 1 Ipratropium bromida (MDI) atau
nebulizer, 2-6 puff 4 x sehari, tunjukkan cara
penggunaan yang tepat, advis pasien ttg
pentingnya penggunaan teratur dan efek samping yg
mungkin timbul (mulut kering rasa pahit), jika
hasil trial perbaikan FEV1 lt 20 ?? step 2
Tahap 2 Tambahkan ß-agonis MDI atau nebulizer,
tunjukkan cara penggunaan yang tepat, advis
pasien ttg pentingnya penggunaan teratur dan efek
samping yg mungkin timbul (takikardi, tremor) ??
jika tidak ada perkembangan hentikan ß-agonis,
jika ada perbaikan tapi kecil ?? step 3

118

Tahap 3 Tambah teofilin,mulai dari 400 mg/hari
dlm bentuk sustained released, sesuaikan dosis
setiap interval 3 hari untuk menjaga serum level
antara 10-15 µg/ml, pantau ESO takikardi, tremor,
nervous, efek GI jika tidak ada perbaikan ??
hentikan teofilin dan ??go to step 4
Tahap 4 Coba dengan kortikosteroid prednison
30-40 mg/hari selama 2-4 minggu, cek dengan
spirometer (perbaikan 20), titrasi dosis ke
dosis efektif terkecil (lt 10 µg sehari),
pertimbangkan penggunaan kortikosteroid inhalasi
?? jika pasien tidak berespon baik ?? kembali ke
steroid oral

119
Terapi antibiotika

?? Berdasarkan evidence terbaru yang tersedia,
antibiotika harus diberikan pada pasien-pasien
PPOK yang
?? Pasien dengan eksaserbasi akut dengan 3 tanda
utama yaitu increased dyspnea, increased sputum
volume, increased sputum purulence (Evidence B),
atau
?? Pasien dengan eksaserbasi akut dengan 2 tanda
utama, jika peningkatan purulensi sputum
merupakan salah satunya (Evidence C)
?? Pasien dengan eksaserbasi parah yang
membutuhkan ventilasi mekanik, baik invasif
maupun non-infvasif (Evidence B)

120
Key points

??PPOK adalah penyakit yang sebenarnya secara
potensial dapat dicegah ?? stop smoking
??Sekali PPOK terjadi ?? penderita akan
memerlukan terapi yang kompleks ?? yang
efikasinya masih diperdebatkan para ahli
??Penyakit ini bersifat progresif dan
ireversibel?? berbiaya besar baik baik personal
maupun masyarakat

121
Difference between bronchitis and emphysema
122
Bronchitis v. Emphysema

Easy to decompensate
Usually relatively easy to treat
Can cause emphysema
Rarely are these patients ever having normal
blood gases

Usually more difficult to decompensate
Difficult to treat
Can be caused by bronchitis
Early, blood gases are normal

123
Patofisiologi pneumotoraks

Akibat peningkatan tekanan
Intrabronkial ( batuk/ bersin )
?
Tekanan diteruskan s/d alveoli
( locus minoris / Bullae - fibrotik pada alveoli
)
?
Alveoli robek sehingga
merobek pleura di sekitarnya
?
Udara masuk intrapleura
?
Pneumotoraks

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Berdasarkan penyebab terjadinya

PNEUMOTORAKS ARTIFISIAL
Bedakan Tu-pleura dan Tu-paru ( dx )
Proteksi Radioterapi Ca mamae ( tx )
Haemoptisis Profuse ( tx )
. PNEUMOTORAKS TRAUMATIK
Akibat trauma pada dada
. PNEUMOTORAKS SPONTAN
Iatrogenik causa ??
Penyakit kronis? TB, COPD, Asma

126
Berdasarkan jenis fistel

PNEUMOTORAKS TERBUKA
P. Intrapleura P. dunia luar ( two way )
Tekanan ekspirasi 2 2
Tekanan inspirasi 2 - 2
PNEUMOTORAKS TERTUTUP
P. Intrapleura ? P. dunia luar (no way )
P awal ? resorbsi paru ? P jadi
? paru belum ngembang sempurna.
Tekanan ekspirasi 4 - 4
Tekanan inspirasi 12 - 1

127
BERDASARKAN DERAJAT KOLAPS

Pneumotoraks Totalis
Pneumotoraks Partialis
Kolaps ( A X B ) ( a X b ) X 100
( A X B )

128
Pneumotoraks parsial
129
Pneumotoraks total
130
Gejala Klinik

Sesak mendadak memberat
- Sesak tak di pengaruhi Posisi
- Batuk
- Dada terasa nyeri / kram / kemeng
- Nampak sakit berat, keluar keringat dingin s/d
syok
- Napas tersengal sengal s/d sianosis

131
Penatalaksanaan Pneumotoraks

Antibiotika penyebab
Anti Tuberkulosa ( OAT )
Anti Tusif ( codein )
Bronkhodilator
Pencahar / Laxan
Bed Rest / hindari kegiatan yang akibatkan
peningkatan tekanan intra pleura ( teriak, bersin
keras, mengejan dan batuk keras )

132
Komplikasi Pneumotoraks

Terjadi Infeksi
Efusi Pleura ( Fluidopneumotoraks )
Empyema ( Pyopneumotoraks )
Terjadi Trauma Hematotoraks
Udara dari cav. Pleura meluas
Pneumomediastium Emfisema Cutis
Udara menekan ke organ sekitar
Tamponade Jantung
Gagal napas

133
Efusi Pleura
134
Efusi Pleura

Adanya Cairan Pleura yang Volume nya
lebih dari Normal ( Vol. normal 1 20 cc )

135
Fisiologi cavum Pleura
136
Fisiologi Efusi Pleura

Volume cairan pleura selalu konstan,
akibat dari
P. hidrostatik 9 mmHg produksi oleh
pleura parietalis
P. koloid osmotik 10 mmHg absorbsi oleh
pleura viseralis

137
Penyebab akumulasi cairan Pleura

? Tekanan koloid osmotik ( Hypolbuminemia )
? Permeabilitas kapiler ( Radang, Neoplasma )
? Tekanan hirostatik ( Gagal jantung )
? Tekanan negatip intrapleura ( Atelektasis )

138
Pemeriksaan Fisik Efisi Pleura

- Inspeksi nampak sakit, gerak dada sisi sakit
tertinggal,nampak lebih cembung
- Palpasi gerak dada sisi sakit tertinggal,
Fremitus raba sisi sakit turun
- Perkusi suara ketok sisi sakit redup
pd.bag.bawah garis Ellis Damoiseau
- Auskultasi suara napas sisi sakit turun
/hilang

139
Sitologi cairan Pleura

- Lekosit gt 25.000 / mm3 ? Empyema
- Netrophil gt ? Pneumonia, TBC, Pancreatitis
- Limphosit gt ? TBC, limphoma, keganasan
- Eosinophil gt ? Emboli , Parasit, Jamur
- Eritrosit 5 10 ribu/mm3 ? Pneumoni,
Keganasan
- Eritrosit 100 ribu / mm3 ? Keganasan, Trauma,
Infark Paru
- Sel ganas ? ditemukan pada 50 60
Keganasan

140
Gambaran Radiologi Efusi Pleura

lt 300 CC Secara fisik tak ada perubahan.
Foto PA sinus masih nampak lancip.
Foto Lat sinus nampak mulai tumpul
gt 500 cc Gerak dada/ fremitus suara/fremitus
raba menurun,suara ketok redup
gt 1000 cc dada cembung, egofoni positip
gt 2000 cc mediastinum terdorong

141
Foto Thorax
Foto Thoraks Perselubungan Pada
hemitoraks Dextra dengan sinus frenicus costalis
kanan tumpul
142
Penatalaksanaan Efusi Pleura

- Evakuasi cairan pleura / torakosentesis
volume pengambilan maksimal 1000 cc
setiap kali pengambilan
- Pemasangan WSD
Efusi Pleura massive
Efusi Pleura haemorhagic
Hematotoraks, Empyema
Chylotoraks, Chiliform

143
FARMAKOLOGI

Antikolinergik inhalasi first line therapy,
dosis harus cukup tinggi 2 puff 4 6x/day
jika sulit, gunakan nebulizer 0.5 mg setiap 4-6
jam prn, exp ipratropium or oxytropium bromide
Simpatomimetik second line therapy
terbutalin, salbutamol
Kombinasi antikolinergik dan simpatomimetik
untuk meningkatkan efektifitas
Metil ksantin ?? banyak ADR, dipakai jika yang
lain tidak mempan
Mukolitik ?? membantu pengenceran dahak, namun
tidak
memperbaiki aliran udara ?? masih kontroversi,
apakah bermanfaat secara klinis atau tidak