Respiratory Pathology

Question 1

ADULT RESPIRATORY DISTRESS SYNDROME: What is it

Answer 1

This is a specific disease of the lung characterised by
1) refractory hypoxaemia
2) alveolar inflammation
3) oedema (new bilateral fluffy infiltrates on x-ray)
pulmonary fibrosis develops later.
4) known cause
5) no evidence of acute cardiac failure (PAWP < 18)

Typically the syndrome is recognised some hours or even days after the initial insult.

Question 2

ARDS Histology

Answer 2

1) Early changes shows interstitial and alveolar oedema.

2) The alveoli contain cell debris, proteinaceous fluid, hyaline membrane and haemorrhage.

3) Chronic inflammation follows; organisation and fibrosis-damage now permanent.

Question 3

ARDS Clinical

Answer 3

1) increased respiratory rate, cyanosis, and, on arterial blood gas analysis, hypercapnia.

2) Chest x-ray shows patchy white clouding.

3) The compliance is reduced, The increased stiffness of the lungs is due to alveolar collapse and oedema.

alveoli are filled with exudate and oedema, a large percentage of pulmonary blood flow goes through unventilated units, giving rise to severe inequality of ventilation and perfusion.

Treatment includes oxygen enrichment, . PEEP often improves oxygenation by decreasing pulmonary oedema and recruiting underventilated alveoli.

A similar condition occurs in infants – infant respiratory distress syndrome. with profound hypoxaemia. Treatment is similar to that of adults, but the addition of synthetic surfactant to inspired oxygen helps correct the underlying defect, i.e. the inability of the premature fetal lung to produce sufficient surfactant.

Question 4

Oxygen delivery: Face mask and nasal cannulae

Answer 4

increase the patient’s inspired oxygen,
depends upon the respiratory pattern, the rate and depth of breathing, and patient’s peak inspiratory flow. If this significantly exceeds the rate of oxygen flowing into the mask, then there will be significant dilution with air.

Question 5

Oxygen delivery: Venturi masks

Answer 5

Oxygen masks utilising the Venturi principle provide accurate concentrations of oxygen of up to 60%, which will exceed the patient’s peak inspiratory flow. These devices rely on using a high flow, low pressure principle generated by passing oxygen through a narrow orifice into a special mask.
Controls rate at which surrounding air enters mask

Venturi masks are fixed performance systems.

Question 6

Harmful effects of oxygen

Answer 6

• depression of ventilation.

• Oxygen can also be directly toxic to the tissues.
Exposing alveoli to 100% oxygen for more than a few hours will result in normal subjects complaining of discomfort and difficulty in breathing. This is because, in the absence of nitrogen, alveoli tend to collapse as oxygen is rapidly removed.

• results in a progressive fall in arterial oxygen tensions, capillaries become increasingly permeable, leading to interstitial oedema,.

• After 48h, organisation and fibrosis occur in a similar fashion to ARDS. .

• In the newborn infant treated with high-inspired oxygen concentrations, a condition called retrolental fibroplasia may develop, with permanent blindness resulting.

Question 7

Pneumothorax: Spontaneous

Answer 7

This most commonly occurs in young males 15–40 and is occasionally bilateral and recurrent.

A primary spontaneous pneumothorax occurs in an otherwise healthy patient usually occurs in tall young men, in whom the negative pressure in the pleural space at the apex of the lung is greater than normal. Rupture of a small bulla (bleb) in this area is the usual cause.

Spontaneous primary < 2cm - no Tx
Sponataneous primary > 2cm - needle

Spontaneous secondary < 2cm - needle
Spontaneous secondary > 2cm - chest drain

Question 8

Secondary pneuomothorax

Answer 8

Secondary spontaneous pneumothorax usually occurs in patients over 30, and is almost always associated with pulmonary disease.

Causes include asthma, chronic obstructive pulmonary disease (COPD), cystic fibrosis, cancer and lung abscess.

Question 9

Tension pneumothorax

Answer 9

This develops when the hole in the pleura remains unsealed, and a 1-way valve develops so that air can pass into the pleural space on inspiration but cannot escape during expiration.

• The pressure in the intrapleural space rises,

• The patient rapidly deteriorates due to reduced venous return, and hypoxaemia caused by shunting through the compressed lung. treatment is insertion of a hollow needle into the affected side of the chest.

• A tension pneumothorax may occur during IPPV of a patient with high pressures or with PEEP.

Question 10

Pulmonary oedema: Pathology

Answer 10

Pulmonary oedema is the abnormal accumulation fluid in the tissues of the lung.

• The epithelium of the capillaries is very permeable to water, small molecules and ions. The alveolar epithelium is permeable to water, but not to small molecules or even ions.

• If excess fluid moves out of the circulation it will cause, first, interstitial oedema. This has little effect on primary function but can be seen on x-ray.

• If fluid continues to move into the lungs it will overwhelm the lymphatics, resulting in alveolar oedema. The alveoli become filled with fluid which increases surface tension forces, causing them to shrink.

• Ventilation of these units ceases, and, while they remain perfused, hypoxaemia results.

Question 11

Pulmonary oedema: causes

Answer 11

1) Raised capillary hydrostatic pressure (commonest cause), usually seen after acute myocardial infarction, left ventricular failure, or transfusion overload. Sudden rises in capillary pressure will result in alveolar oedema.

2) The permeability of the capillaries may also rise, causing fluid to accumulate in the alveoli. This occurs from a variety of causes including endotoxic shock, exposure to irritant gases such as chlorine or nitric oxide, and as part of ARDS.

3) Lymphatic drainage of the lung becomes impaired/obstructed e.g. by tumour cells, then pulmonary oedema will result.

4) Pulmonary oedema can also occur during rapid ascent to high altitude.

5) Neurogenic pulmonary oedema may occur following insult to the central nervous system, usually severe head injury causing massive over- activity of the sympathetic nervous system.

Question 12

Pulmonary oedema: Physiological

Answer 12

1) The compliance of the lung decreases as surface tension causes alveolar collapse.
2) Airway resistance increases, may be partially blocked by oedema. Reflex bronchoconstric- tion also increases resistance.
3) Those alveoli filled with fluid no longer take part in gas exchange, but instead collapse. They continue to be perfused, causing massive VA:VQ mismatch.
4) Pulmonary vascular resistance is increased because of hypoxic vasoconstriction and external pressure on the vessels due to interstitial oedema. There is often diversion of blood to the upper zones.

Question 13

Pulmonary oedema: Clinical

Answer 13

1) Dyspnoea
2) Orthopnoea
3) Paroxysmal nocturnal dyspnea
4) Cough
5) Cyanosis

Breathing is rapid and shallow, driven by arterial hypoxaemia and an effort to minimise the increased work of breathing.

On auscultation fine inspiratory crepitations are heard at the lung bases.
A chest x-ray reveals an enlarged heart with prominent pulmonary vessels.
Interstitial oedema causes short, linear horizontal lines near the pleural surface in the lower zones – the Kerley B lines.

Question 14

Pulmonary oedema: Treatment

Answer 14

1) High concentrations of oxygen
2) Vasodilators
3) Diuretics
4) Ultimately IPPV and PEEP.
5) The application of raised end expiratory pressure decreases oedema in the larger airways and decreases the shunt.

Question 15

Pulmonary embolus

Answer 15

1) A large clot may completely obstruct the pulmonary outflow, resulting in death.
2) Smaller clots may block a single large artery or break up and block several small vessels.
3) The lower regions of the lung have the greatest blood flow and so are most often affected.
4) If the patient survives the initial insult, then there may either be distal infarction or haemorrhage into the affected segment.

The pulmonary artery resistance is only increased with large pulmonary emboli,

right ventricle may fail. Occlusion of the pulmonary artery reduces in alveolar PCO2, causing bronchoconstriction in the small airways.

Physiological dead space and shunt are increased. Hypoxaemia occurs without a corresponding rise in PaCO2, because alveolar ventilation increases.

Question 16

Pulmonary embolus: Clinical and treatment

Answer 16

Larger emboli produce:
1) Shock
2) Central chest pain
3) Sudden collapse
4) Sometimes distended neck veins.
Rapid surgical intervention may be life-saving.

Small pulmonary emboli produce
1) Dyspnoea
2) Pleuritic pain.
3) There may be a raised temperature
4) Productive cough with bloodstained sputum.
5) There may be a tachycardia
6) Auscultation may reveal a pleural rub.
7) ventilation-perfusion scan,

A saddle embolus at the bifurcation of the pulmonary arteries usually causes sudden death.

Occlusion of one of the main pulmonary arteries also frequently leads to death,

Occlusion of a lobar or segmental artery causes sudden onset of chest pain and leads to a wedge-shaped infarct of the peripheral lung tissue.

Treatment is with antithrombolytics, anticoagulation and supplementary oxygen if required.

Question 17

Pleural Effusion

Answer 17

Larger effusions may cause dyspnoea and pleuritic pain. reduced movements on the affected side of the chest, decreased breath sounds, and dullness on percussion.

• The fluid that accumulates is either an exudate or a transudate. An exudate - high protein content = infection or malignancy.

• A transudate is usually the result of capillary hypertension,

• haemothorax.

• Low blood pressure will result in decreased perfusion of alveoli, which will add to alveolar dead space and will lower arterial PO2.

Question 18

Pleural effusion types

Answer 18

• Haemothorax.

• Hydrothorax. This is fluid in the pleural space which may be either a transudate (low protein, content 30 g/L). A transudate may result from liver, renal or cardiac failure. An exudate may result from tumour, infection or inflammation.

• Chylothorax. This is chyle in the pleural space. It is usually due to neoplastic obstruction of thoracic lymphatics. Rarely it may follow trauma.

• Pyothorax (empyema). This is pus in the pleural space.

Rare:
e.g. subphrenic abscess, acute pancreatitis. Meigs’ syndrome

Question 19

Effects of Endotracheal intubation

Answer 19

1. Normal processes of humidification are bypassed
2. reduction in anatomical dead space
3. There is an increase in airway resistance
4. causes profound reflex stimulation, tachycardia and increased blood pressure.

A prolonged attempt at intubation may result in the patient becoming hypoxic. This can be avoided by pre- oxygenation with 100% oxygen as described earlier.

Question 20

Flail chest

Answer 20

If a number of ribs are broken in two places this creates a flail chest, the segment involved moving paradoxically,

Often there is an associated underlying haemothorax, pneumothorax, or lung contusion. Endotracheal intubation and positive pressure ventilation is often required. (esp if sats < 90%)

Question 21

Mesothelioma

Answer 21

There is a strong association between exposure to asbestos and primary malignant mesothelioma.

• (‘blue’ asbestos) and amosite (‘brown’ asbestos) are particularly related. The interval between exposure and development of the disease is around 35 years.

• The tumour develops as nodules on the pleura
form a sheet extending into the lung fissures. Invasion of the chest wall and intercostal nerves occurs, causing severe chest wall pain. Lymphatic spread occurs to the hilar nodes.

• There is no treatment, death occurring usually within two years of diagnosis.

Question 22

Pneumonia types

Answer 22

1. Bronchopneumonia
2. Lobar pneumonia
3. Aspiration pneumonia
4. Atypical pneumonia
5. Legionnaires disease

Question 23

Bronchopneumonia

Answer 23

Occurs old age and infancy and in patients with debilitating disease

• Other predisposing factors include COPD and CF. Post-op due to failure to remove respiratory tract secretions.

• CAUSES: Causative organisms include Streptococcus pneumoniae and Haemophilus influenzae. Rarer causes include Staph. aureus and coliforms. Staph. aureus pneumonia is seen in hospital patients, after influenza, and as a severe secondary bacterial pneumonia in intravenous drug abusers. It is also seen in the immune-compromised. Coliform pneumonia seen in hospital patients, the immunocompromised and those on ventilatory support on ITUs.

•HISTOLOGY: characteristic patchy distribution and tends to be basal and bilateral. Histological examination reveals inflammatory cells in the bronchi and bronchioles, with the alveoli filled with an inflammatory exudate. the areas of inflammation either resolve or heal by scarring.

Question 24

Lobar pneumonia

Answer 24

it may result in referred pain to the abdomen, particularly right lower lobar pneumonia It is commonly caused by Streptococcus pneumoniae and may be seen as part of postsplenectomy sepsis.

• Clinical features These include cough, fever, and ‘rusty’ sputum. Rigors may occur. Acute pleuritic chest pain occurs. four stages of the disease:

1. Congestion. This lasts about 24 h and is due to a protein rich exudate filling the alveoli, with venous congestion.
2. Red ‘hepatisation’. This stage lasts a few days, with inflammatory cells and red cells in the alveolus spaces. There is a fibrinous exudate on the pleura. The lung is red, solid and airless 

3. Grey ‘hepatisation’. There is accumulation of fibrin with destruction of white cells and red cells. The lung appears grey and solid.
4. Resolution. This occurs in 8–10 days. The inflammatory cells and fibrin are reabsorbed, and the underlying lung architecture is preserved.
   This is the classical pattern of lobar pneumonia.

Question 25

Aspiration pneumonia

Answer 25

• may occur include induction of anaesthesia, recovery from anaesthesia, sedation, coma, and severe debility.

Lung abscess and empyema may result. Causative organisms are usually y Streptococcus pneumoniae, and anaerobes

Anaerobes are rarely isolated from sputum.

Question 26

Atypical pneumonia

Answer 26

The main causative organisms are: Mycoplasma pneumoniae, Coxiella burneti, Chlamydia psittaci (BIRDKEEPERS), Chlamydia pneumoniae. Mycoplasma pneumoniae is responsible for most cases of primary atypical pneumonia.

Effective drugs include tetracycline and erythromycin.

Question 27

Legionnaires disease

Answer 27

Legionella pneumophila.
Patients are typically middle-aged smokers, often in poor general health.
spread is by water droplets from contaminated air humidifiers or water storage tanks.
SX initially those of a flu-like illness which progresses to a severe pneumonia and respiratory failure.
HYPONATRAEMIA, URINARY LEGIONELLA

Other features include headache, mental confusion, myalgia, nausea, vomiting, diarrhoea and acute renal failure.
Treatment is usually with erythromycin but, in those failing to respond, rifampicin and ciprofloxacin either singly or in combination are effective drugs.

Question 28

Chest infections in the immunocompromised

Answer 28

1. Pneumocystis jirovecii This is usually a reactivation of latent infection. It is common in AIDS and also in transplant recipients. Diagnosis via bronchial aspirates, bronchial lavage or lung biopsy. Treatment is with intravenous co-trimoxazole. 

2. Candida and Aspergillus Both these organisms cause widespread areas of necrosis. Treatment requires intravenous amphotericin B alone or in combination with 5-fluorocytosine. Oral administration fluconazole, may also be effective. INDIA INK
3. 
Viruses Infection with cytomegalovirus may be due to reactivation of latent infection or transmitted via a transplanted organ. Cytomegalovirus causes diffuse alveolar damage. Characteristic intranuclear inclusions are seen with CMV infections. Treatment is with intravenous ganciclovir.

Question 29

Bronchiectasis

Answer 29

permanent dilatation of the bronchi and bronchioles. Recurrent infection and inflammation lead to further airway damage and destruction of lung tissue.

• The condition results from bronchial obstruction with distal infection or severe infection alone. There is destruction of the alveolar walls, especially interstitial elastin, and fibrosis of the lung parenchyma.

• Clinical features include a cough productive of large amounts of foul-smelling sputum, together with dyspnea

KARTAGENER AND YOUNG SYNDROME

Question 30

Bronchiectasis: Complications

Answer 30

Complications include
1. Pneumonia
2. Lung abscess
3. Empyema
4. Septicaemia
5. Amyloid formation
6. Pulmonary fibrosis
7. Cor pulmonale.
8. Remote abscesses, e.g. cerebral abscesses and meningitis, may also occur.

The chief congenital cause is cystic fibrosis, although it is also seen in immunodeficiency syndromes.

Acquired causes include whooping cough and measles in child- hood, tuberculous mediastinal lymph nodes, and bronchial tumours.

Question 31

Lung abscess

Answer 31

There may be a single lung abscess or the condition may be multiple. They occur usually in patients who are malnourished, cachectic, or immunocompromised.
Causes include:
1. Aspiration pneumonia
2. Bronchiectasis
3. Carcinoma
4. Inhaled foreign bodies
5. Infected pulmonary infarcts following pulmonary embolus, and intra- venous drug abuse.

Question 32

Lung carcinoma: Causes

Answer 32

• Cigarette smoking
• Occupational hazards e.g. asbestos
• Pulmonary fibrosis

Question 33

Lung carcinoma: Cigarette smoking

Answer 33

The association between cigarette smoking and small cell lung cancer is well established.

Progressive changes occur in the bronchial mucosa, squamous metaplasia occurring initially, followed by dysplasia. There is an increased risk in passive smokers.

Question 34

Lung carcinoma: Occupational

Answer 34

Occupational hazards
1) Asbestos A latent period of approximately 20 years Adenocarcinoma is the most common tumour. Asbestos exposure amplifies the risks of smoking.

2) Radioactive gases Radioactive gases may also predispose to lung cancer, e.g. radon exposure in miners.

3) Other factors There is an increased risk of lung cancer in workers in industries involved with nickel, chromium and cadmium (metal refining/ smelting), arsenic (vineyard workers exposed to arsenical insecticides), mustard gas and coal tar distillates.

Question 35

Lung carcinoma: Pulmonary fibrosis

Answer 35

Pulmonary fibrosis Some peripheral tumours may arise in areas of scarring, e.g. old tuberculous foci or infarcts. There is a significant increase of lung adenocarcinoma in patients with pulmonary fibrosis and honeycomb lung.

Question 36

Lung carcinoma: Clinical

Answer 36

Clinical features:
Many primary lung cancers may be asymptomatic and seen on routine chest x-ray. The commonest presenting symptoms are cough, haemoptysis, dyspnoea, chest pain, wheeze, hoarseness and recurrent chest infections. 


Question 37

Lung carcinoma: Complications

Answer 37

• Thoracic: pleural effusion, recurrent laryngeal nerve palsy (hoarseness)

• Superior vena caval obstruction: cyanosis, oedema, venous engorgement of the head, neck, arms, chest and upper abdomen with brawny non-pitting oedema of the neck

• Horner’s syndrome: ptosis, miosis, enophthalmos, anhidrosis, especially with Pancoast tumour (invasive cancer of the apex of the lung)

• Metastatic (cachexia, malaise); brain (headaches, fits, personality change); bone (pathological fractures); liver (jaundice); adrenal (Addison’s disease)

• Non-metastatic (extra pulmonary); hormonal (ADH, ACTH from small cell carcinomas), PTH from squamous cell carcinomas; hypercalcaemia; myasthenic neuropathy; hypertrophic pulmonary osteoarthropathy; thrombophlebitis migrans; gynaecomastia; clubbing.

Metastases occur to regional lymph nodes and via the blood stream to liver, bone, brain and occasionally to adrenal glands.

Question 38

Lung carcinoma: morphology

Answer 38

Most tumours arise from bronchi close to the hilum. Some arise peripherally, and it is these small peripheral adenocarcinomas which are amenable to surgery if detected prior to metastatic spread. Four histological types are recognised:

• Adenocarcinoma (30–45%);

• Squamous cell carcinoma (35–40%)

• Small cell (oat cell) carcinoma (15–25%)

• Undifferentiated large cell carcinoma (rarest)

Question 39

Lung carcinoma: Adenocarcinoma

Answer 39

Adenocarcinomas These are usually peripheral. They are associated with pulmonary fibrosis, honey- comb lung and asbestosis.

Question 40

Lung carcinoma: Squamous

Answer 40

Squamous cell carcinoma This type of cancer is most closely associated with smoking. The tumour occurs in the hilar regions usually in areas of squa- mous metaplasia and dysplasia. Spread to hilar nodes is common but distant metastases occur late.

PTHrp

Question 41

Lung carcinoma: Small cell

Answer 41

Small cell (oat cell) carcinoma This type of cancer usually arises in the hilar region. They metastasise early, often producing large secondary deposits. In some cases the primary tumour remains very small.

Question 42

Lung carcinoma: Undifferentiated large cell carcinomas

Answer 42

Undifferentiated large cell carcinomas These are usually centrally placed and are highly aggressive tumours associated with necrosis and haemorrhage.

Question 43

Secondary lung tumours

Answer 43

more common than primary lung cancers. They arise either by blood or lymphatic spread. the lymphatics may be diffusely involved, a condition known as lymphangitis carcinomatosa.
Pulmonary metastases may occur from:
• sarcomas
• carcinomas
• lymphomas.

Carcinomas that commonly give rise to lung secondaries include:
• Breast
• Kidney
• Gastrointestinal tract.

Question 44

Lung carcinoma: Coin lesions

Answer 44

are due either to granulomatous disease or to neoplasms. Radiographically defined as an intrapulmonary lung lesion 3 cm or less in diameter that is not associated with adenopathy or atelectisis. Diagnosis is by radiology.

Malignant causes include:
• primary bronchogenic carcinoma
• Bronchoalveolar carcinoma

• carcinoid tumour

• metastasis

Benign causes include:
1) hamartoma
2) infectious granuloma, e.g. tuberculosis,

non- 
specific granulomas;
3) Wegener’s granulomatosis
4) Sarcoidosis;
5) Rheumatoid nodule;
6) Healed pulmonary infarct;
7) Arteriovenous fistula
8) Anthrosilicotic nodule. 
Lesions >1 cm in diameter have a probability of being malignant and lesions of >3cm in diameter are very highly likely to be malignant.

Question 45

What is empyema

Answer 45

pus within pleural cavity

Question 46

Causes of empyema

Answer 46

pulmonary infection
other infection e.g. subphrenic abscess
surgery
penetrating chest wall injury

Question 47

Common organisms in empyema

Answer 47

gram positive e.g. staph aureus and strep pnuemoniae

secondary to surgery - gram negative organisms

Question 48

complications of empyema

Answer 48

Systemic sepsis
Lung collapse
Bronchopleural fistula
pleural scarring

Question 49

Organisms in lung abscess

Answer 49

Organisms include Streptococcus pneumoniae, Haemophilus influenzae, Staphylococcus aureus, Klebsiella, and Entamoeba histolytica, the latter spreading from the liver via the diaphragm.