The Respiratory System

3.3a The physiology of the respiratory system

This section concentrates on the physiology and pathology of the respiratory system, looking at the structure and function of the respiratory system in health.

The upper respiratory tract

The upper respiratory tract leads from the entrance of the respiratory system at the nose to the end of the trachea, the tube that directs the inhaled air into the chest cavity (thorax) towards the lungs.

The function of the upper respiratory tract is to provide a plentiful supply of warm, clean and moist air to the lungs. To help it perform this function it consists of wide air spaces and is lined by a specialized form of epithelium. The respiratory epithelium consists largely of ciliated columnar cells, but it also has many mucus-secreting (goblet) cells.

The water-containing mucus moistens the air that rushes through the respiratory tract, and picks up dirt particles and other foreign bodies present in the air. Cilia are structures akin to microscopic hairs on the surface of cells. They are powered by the energetically charged molecule ATP to move in coordinated waves. In the respiratory tract the cilia beat in an upward direction. Their function is to cause an upward movement of the mucus, allowing the foreign material to be moved away from the delicate lung tissue and up to the back of the throat, from where it can be swallowed or expectorated.

The connective tissue layer below the respiratory epithelium has a number of lymphocytes scattered throughout its length. These respond to foreign antigens by producing antibodies and attracting other immune cells. This is an important aspect of the protection of the respiratory tract from infection.

The important parts of the upper respiratory tract are the nose, pharynx, larynx and trachea.

The nose

In the breathing of a healthy person at rest, all air is drawn in through the nostrils into the nasal cavity. This space has a deeply ridged surface that has a rich blood supply. This means that the current of air comes into contact with a large area of warm epithelium before its descent towards the lungs. In addition to the cilia on the epithelial cells, body hairs are present in the opening of the nose to filter out any large foreign particles.

Opening out into the nasal cavity are the sinuses. These are cavities deep within the facial bones that have narrow passageways leading into the nasal cavity. Their function is to give the voice a resonant quality, the loss of which is apparent in anyone who has suffered from a head cold, when the sinuses become filled with thick secretions. A tiny duct leading from each eye also opens into this space. This continually drains away tears from the eyes. The runny nose that accompanies a bout of crying is a result of the excess tears flooding into the nose through this duct.

The nose is the specialized sense organ for smell. To perform this function, delicate nerves originating from the base of the brain penetrate the bone above the nasal cavity to supply the nasal lining. These are sensitive to the chemicals in the incoming air, which become dissolved in the mucus. The sense of smell is also important to enrich the experience of taste. Occasionally, in a head injury, these nerves become permanently severed, even though there may be no other major brain damage. The person may recover fully but be left without a sense of smell and with a highly impaired sense of taste.

Other nerves in the nose are very sensitive to the irritation that can result from foreign particles and from inflammation of the lining of the nose. These nerves can trigger the protective reflex of the sneeze, which is a very effective mechanism for expelling unwanted material from the nasal cavity.

EXCHANGE OF GASES IN THE ALVEOLI

The blood that enters the capillaries surrounding the alveoli has originated from the pulmonary arteries. These large vessels originate from the right ventricle of the heart and carry deoxygenated blood pumped by the right side of the heart. The blood is deoxygenated because the cells of the body tissues have used up all the oxygen in the process of cellular respiration. As well as being deoxygenated, this blood is also carrying a high concentration of carbon dioxide, the by-product of cellular respiration. In contrast, the air inspired into the alveoli is rich in oxygen from the outside air, and carries very little carbon dioxide. Therefore, there is a tendency for the oxygen in the alveoli to move into the deoxygenated blood in the capillaries. This movement occurs readily, as oxygen can diffuse with no restriction through the cell membranes of the alveolar and capillary walls. At the same time, there is a movement of carbon dioxide out of the capillary blood and into the alveolar air. This exchange of the two gases of respiration occurs very rapidly.

The capillaries that leave the alveoli converge to form the pulmonary veins, which return all this blood to the left side of the heart. This blood is now rich in oxygen, and has been cleared of carbon dioxide. The pulmonary veins are the only veins in the body that carry oxygenated blood. All the other veins carry blood away from the body tissues, and this blood is, of course, deoxygenated.

The air left in the alveolus now contains more carbon dioxide than oxygen, and is expelled to the outside world by the process of expiration, so that the whole process can begin afresh with the next in-breath.

This process of exchange of gases is assisted by the fact that there are millions of alveoli, each with its own rich blood supply. In some conditions, such as emphysema, the delicate structure of the alveoli is damaged and their number is reduced (see Section 3.3e). This severely impairs the process of exchange of gases, so that the blood does not get replenished with an adequate amount of oxygen, and carbon dioxide fails to be fully cleared.

The lungs

The lungs consist of the branching air passages of the bronchi and bronchioles, and the thousands of alveoli clustered around the ends of the bronchioles. The lungs are surrounded and supported by elastic connective tissue, which has the tendency to cause the fully expanded lung to contract. The lungs sit within the thorax, which is protected by the rib cage and its supportive muscles, and they rest on the sheet of muscle below known as the diaphragm.

In normal, quiet breathing the cycle of inspiration and expiration occurs at about 15 times per minute (4 seconds/cycle). There is an automatic reflex that originates from a control center in the base of the brain that sets this regular rhythm. Nerves travel down from this control center to stimulate the synchronized and rhythmic muscular contraction of the rib cage and diaphragm.

All variations in the resting respiratory rate are brought about by changes that take place in the breathing control center in the brain. The breathing control center is essential for maintaining homeostasis of the levels of oxygen and carbon dioxide in the arterial blood. The oxygen level must, of course, be maintained at a high concentration, whereas the level of carbon dioxide must not be allowed to rise too high. To perform this role, the breathing control center contains cells that are very sensitive to the level of carbon dioxide in the blood. A miniscule rise in the level of carbon dioxide leads to an increase in the breathing rate so that excess carbon dioxide can be breathed out of the body. If the level of carbon dioxide drops, so does the rate of breathing. The levels of carbon dioxide in the blood can then build up again.

The control center in the brain is also sensitive to drops in the concentration of oxygen in the blood. However, the responsiveness of the control center to carbon dioxide also indirectly controls the homeostasis of oxygen in the blood, as increased external respiration will increase oxygen levels, and reduced external respiration will reduce oxygen levels.

Any voluntary wish to modulate the breathing, such as for speech, singing or laughing, generates nerve impulses from other parts of the brain (the cerebral hemispheres) to the control center of breathing, which then alters the breathing rate accordingly. The sneeze and cough reflexes involve a direct link between the irritated nerve endings and the control center.

3.3b The investigation of the respiratory system

The bulk of minor respiratory disease, particularly infectious disease affecting the upper respiratory tract, is managed in the UK entirely by the doctor (general practitioner (GP)). More severe problems affecting the nose and throat may be referred for the opinion of a specialist in diseases of the ear, nose and throat (otorhinolaryngologist).

A patient with any other severe respiratory disease will be referred by their GP to a specialist in respiratory medicine. These doctors are commonly known as chest physicians.

If a surgical operation is necessary, the chest physician will refer the patient to a thoracic surgeon. Very often the thoracic surgeon is also skilled in heart surgery, in which case they are more accurately described as a cardiothoracic surgeon.

The most common investigations of the respiratory system include:

•a thorough physical examination

•laryngoscopy to examine the vocal cords

•microscopic examination of the sputum

•pulse oximetry

•lung function tests to assess the mechanics of the breathing

•blood tests relevant to lung function

•chest X-ray imaging, computed tomography (CT) scans and bronchoscopy to visualize the lungs

•biopsy of the lung tissue

•radioisotope scanning.

Physical examination

Examination of the sputum

A patient with an infection or a possible tumor may be requested to produce a sample of phlegm. When examined by microscope, this can reveal the presence of infectious organisms, and occasionally, in cancer, will demonstrate cancerous cells. In the case of infection, the sample can be used to test for sensitivity to a range of antibiotics.

Pulse oximetry

This simple non-invasive test involving a probe applied to the finger tips can give a rapid estimation of the blood oxygen levels, and is now an important aspect in the assessment of the severity of lower respiratory disease.

Lung function tests

Lung function tests are performed when disease of the lower respiratory tract is suspected. These tests require the patient to blow into a machine that measures the force and volume of the out-breath, and detects the changes that are characteristic of the diseases that lead to restricted breathing, such as asthma and emphysema. These tests are straightforward and painless for the patient to perform.

The most simple of these tests is the peak expiratory outflow assessment, which is done using a peak flow meter. This is a hand-held tool that the patient can be taught to use at home. Its main purpose is to assess the severity of asthma in a patient on ongoing treatment, although it does not provide as detailed or helpful information as the more complex tests available in a hospital outpatient department. A more complex examination of lung function includes assessment by means of a spirometer. This will provide a graphical computer printout that describes the rate and quantity of air flow throughout a prolonged expiration. Assessment of exhaled nitric oxide, a marker of the inflammation of asthma, and also carbon monoxide, a marker of cigarette smoking and carbon monoxide poisoning, may be performed. Both these tests also require the patient to exhale into a machine.

Blood tests

Serum samples can be used to examine for antigens of infectious agents and for antibodies to confirm the presence of infection. Certain antibodies can also indicate the tendency to allergy, which is common in asthmatics.

Blood tests can also reveal other markers of chronic respiratory disease such as autoantibodies in connective tissue diseases and anticholinesterase levels in sarcoidosis.

In the investigation of lower respiratory tract disease, a sample of arterial blood is drawn from the radial artery to measure the concentration of oxygen and carbon dioxide in the blood.

Chest X-ray imaging

This test is performed on all patients with suspected lower respiratory tract disease. Most serious disease, such as pneumonia, cancer, emphysema and lung fibrosis, will show characteristic changes on a chest X-ray image. However, in asthma, even when severe, the chest X-ray image usually appears normal.

Computed tomography (CT) scan

This test is most commonly used to assess the size and spread of lung cancer. A CT scan will reveal not only the lung tissue, but also the lymph nodes deep within the chest. It can also indicate changes caused by other chronic lung diseases such as pulmonary fibrosis and asbestosis.

Figure 3.3b-I shows a CT scan of the lungs in a patient with advanced lung cancer. This is a slice of the upper chest presented as if the patient is lying on their back with their feet facing the viewer. The white structures are bones, and the sternum, one vertebral body, some ribs and the scapulae are visible. The very black areas are regions of normal air spaces in the lungs. The cancer is clearly seen as a gray shadow invading the normal lung tissue.

Figure 3.3b-I A CT scan of the lung indicating a large area of cancerous tissue (arrow)

The less-invasive technique of magnetic resonance imaging (MRI) is less valuable in imaging of the tissues of the lung because the respiratory movements affect the quality of the images.

This invasive test involves the passage of a flexible telescope into the wider air passages of a sedated patient. The tube can be inserted as far as the larger bronchioles. Tumors can be seen directly by means of this technique.

Alternatively, salt water can be squirted down the tip of the tube to retrieve cells from the deeper parts of the lungs in cases of possible infection or cancer when sputum does not reveal any features of disease. This technique is known as broncho-alveolar lavage.

Biopsy of the lung tissue

Biopsy involves the removal of a piece of lung tissue for examination under the microscope. The biopsy can be taken from the bronchi or bronchioles through the bronchoscope. Biopsy of the pleura can be taken through a small incision in the skin overlying a gap between the ribs. Sometimes a thoracic surgeon is required to open up the chest to remove tissue from deep in the chest.

Biopsy is most commonly used to confirm the diagnosis of cancer, but can also be used when sarcoidosis or infection is suspected, but cannot be detected by any other means.

Fluid can also be drawn from between the pleura by means of a syringe needle inserted between the ribs into the space. This is used only in those conditions that have caused fluid to accumulate in this space, known as pleural effusion. Such conditions include cancer of the bronchus, pneumonia and pulmonary edema.

Radioisotope scanning

Radioisotope scanning may be used to examine for possible blockages to blood flow in the lungs, usually a result of blood clot emboli. The blood is injected with a safe radioactive marker with a very short half-life (i.e. its activity declines to insignificant levels very rapidly). Defects in blood perfusion of the lungs can then be revealed by means of scanning the lungs for radioactivity.

3.3c Diseases of the upper respiratory tract

Minor diseases of the upper parts of the respiratory tract such as coughs, colds and flu are a well-recognized part of normal life. Conditions that affect the structures progressively further down the respiratory tract, such as the tonsils, larynx and trachea, are seen in conventional medicine as more significant conditions. Nevertheless, on the whole, most acute conditions of the upper half of the respiratory tract are relatively benign.

The conditions of the upper respiratory tract studied in this section are:

•Acute infections of the upper respiratory tract:

–the common cold

–sinusitis

–tonsillitis and pharyngitis

–glandular fever (infectious mononucleosis)

–laryngitis, tracheitis and croup

–epiglottitis

–influenza (flu)

•Allergic rhinitis