Pulmonary pleurae

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Pulmonary pleurae
2313 The Lung Pleurea.jpg
Lung detail showing the pleurae. The pleural cavity is exaggerated since normally there is no space between the pulmonary pleurae.
Details
Pronunciation /ˈplʊərə/
System Respiratory system
Nerve intercostal nerves, phrenic nerves, vagus nerve
Identifiers
Latin pleurae pulmonarius
MeSH D010994
TA98 A07.1.02.001
TA2 3322
TH H3.05.03.0.00001
FMA 9583
Anatomical terminology

The pulmonary pleurae (sg.: pleura) [1] are the two flattened sacs ensheathing each lung, locally appearing as two opposing layers of serous membrane separating the lungs from the mediastinum and the inside surfaces of the surrounding chest walls.

Contents

The portion of the pleura that covers the surface of each lung is often called the visceral pleura. This can lead to some confusion, as the lung is not the only visceral organ covered by the pleura. The pleura typically dips between the lobes of the lung as fissures, and is formed by the invagination of lung buds into each thoracic sac during embryonic development. [2] The portion of the pleura seen as the outer layer covers the chest wall and is often called the parietal pleura. It lines the inner surfaces of the thoracic cavity on each side of the mediastinum, and can be subdivided into mediastinal (covering the lateral surfaces of the fibrous pericardium, oesophagus and thoracic aorta), diaphragmatic (covering the upper surface of the diaphragm), costal (covering the inside of rib cage) and cervical (covering the underside of the suprapleural membrane) pleura. The visceral and the mediastinal parietal pleurae are connected at the root of the lung ("hilum") through a smooth fold known as pleural reflection, and a bell sleeve-like extension of visceral pleura hanging under to the hilum is known as the pulmonary ligament.

Between the two layers of the pleura is what historically has been referred to as a potential space, which in reality is an actual space of about 15 μm. This is called the pleural cavity (also pleural space) [2] . It contains a tiny amount of serous fluid (pleural fluid) secreted by the pleurae, at a pressure below the atmospheric pressure under healthy conditions. The two lungs, each bounded by a two-layered pleural sac, almost fill the thoracic cavity.

Anatomy

Diagrammatic view of exaggerated pleural space. Diagram showing the lining of the lungs (the pleura) CRUK 306.svg
Diagrammatic view of exaggerated pleural space.
Cytology of the normal mesothelial cells that line the pleurae, with typical features. Wright's stain. Cytology of normal mesothelium.jpg
Cytology of the normal mesothelial cells that line the pleurae, with typical features. Wright's stain.

Each pleura comprises a superficial serosa made of a simple monolayer of flat (squamous) or cuboidal mesothelial cells with microvilli up to 6  μm (0.00024  in ) long. The mesothelium is without basement membrane, and supported by a well-vascularized underlying loose connective tissue containing two poorly defined layers of elastin-rich laminae. The costal parietal pleurae also have adipocytes in the subserosa, which present as subpleural/extrapleural fats and are histologically considered belonging to the endothoracic fascia that separates the subserosa from the inner periosteum of the ribs. Both pleurae are quite firmly attached to their underlying structures, and are usually covered by surface glycocalyces that limit fluid loss and reduce friction.

The enclosed space between the parietal and visceral pleurae, known as the pleural space, is normally filled only by a tiny amount (less than 10  mL or 0.34  US fl oz) of serous fluid secreted from the apical region of the parietal pleura. The combination of surface tension, oncotic pressure, and the fluid pressure drop caused by the inward elastic recoil of the lung parenchyma and the rigidity of the chest wall, results in a normally negative pressure of -5 cm H2O (approximately −3.68  mmHg or −0.491  kPa) within the pleural space, causing it to mostly stay collapsed as a potential space that acts as a functionally vacuumous interface between the parietal and visceral pleurae. Contracting the respiratory muscles expands the chest cavity, causing the attached parietal pleura to also expand outwards. If the pleural functional vacuum stays intact, the pleural space will remain as collapsed as possible and cause the visceral pleura to be pulled along outwards, which in turn draws the underlying lung also into expansion. This transmits the pressure negativity into the alveoli and bronchioli, thus facilitating inhalation. [4] [5]

Visceral pleura

The visceral pleura (from Latin : viscera, lit. 'organ') covers the lung surfaces and the hilar structures and extends caudally from the hilum as a mesentery-like band called the pulmonary ligament. Each lung is divided into lobes by the infoldings of the pleura as fissures. The fissures are double folds of pleura that section the lungs and help in their expansion, [6] allowing the lung to ventilate more effectively even if parts of it (usually the basal segments) fail to expand properly due to congestion or consolidation.The function of the visceral pleura is to produce and reabsorb fluid. [7] It is an area that is insensitive to pain due to its association with the lung and innervation by visceral sensory neurons. [8]

Visceral pleura also forms interlobular septa (that separates secondary pulmonary lobules). [9] Interlobular septa contains connective tissue, pulmonary veins, and lymphatics. [10]

Parietal pleura

The parietal pleura (from Latin : paries, lit. 'wall') lines the inside of the thoracic cavity which is set apart from the thoracic wall by the endothoracic fascia. The Parietal includes the inner surface of the rib cage and the upper surface of the diaphragm, as well as the side surfaces of the mediastinum, from which it separates the pleural cavity. It joins the visceral pleura at the pericardial base of the pulmonary hilum and pulmonary ligament as a smooth but acutely angled circumferential junction known as the hilar reflection. [11]

The parietal pleura is subdivided according to the surface it covers.

Neurovascular supply

As a rule of thumb, the blood and nerve supply of a pleura comes from the structures under it. The visceral pleura is supplied by the capillaries that supply the lung surface (from both the pulmonary circulation and the bronchial vessels), and innervated by the nerve endings from the pulmonary plexus.

The parietal pleura is supplied by blood from the cavity wall under it, which can come from the aorta (intercostal, superior phrenic and inferior phrenic arteries), the internal thoracic arteries (pericardiacophrenic, anterior intercostal and musculophrenic branches), or their anastomoses. Similarly, its nerve supply is from its underlying structures — the costal pleura is innervated by the intercostal nerves; the diaphragmatic pleura is innervated by the phrenic nerve in its central portion around the central tendon, and by the intercostal nerves in its periphery near the costal margin; the mediastinal pleura is innervated by branches of the phrenic nerve over the fibrous pericardium. [12]

Development

The visceral and parietal pleurae, like all mesothelia, both derive from the lateral plate mesoderms. During the third week of embryogenesis, each lateral mesoderm splits into two layers. The dorsal layer joins overlying somites and ectoderm to form the somatopleure; and the ventral layer joins the underlying endoderm to form the splanchnopleure. [13] The dehiscence of these two layers creates a fluid-filled cavity on each side, and with the ventral infolding and the subsequent midline fusion of the trilaminar disc, forms a pair of intraembryonic coeloms anterolaterally around the gut tube during the fourth week, with the splanchnopleure on the inner cavity wall and the somatopleure on the outer cavity wall.[ citation needed ]

The cranial end of the intraembryonic coeloms fuse early to form a single cavity, which rotates anteriorly and apparently descends inverted in front of the thorax, and is later encroached by the growing primordial heart as the pericardial cavity. The caudal portions of the coeloms fuse later below the umbilical vein to become the larger peritoneal cavity, separated from the pericardial cavity by the transverse septum. The two cavities communicate via a slim pair of remnant coeloms adjacent to the upper foregut called the pericardioperitoneal canal. During the fifth week, the developing lung buds begin to invaginate into these canals, creating a pair of enlarging cavities that encroach into the surrounding somites and further displace the transverse septum caudally — namely the pleural cavities. The mesothelia pushed out by the developing lungs arise from the splanchnopleure, and become the visceral pleurae; while the other mesothelial surfaces of the pleural cavities arise from the somatopleure, and become the parietal pleurae.[ citation needed ]

Function

As a serous membrane, the pleura secretes a serous fluid (pleural fluid) that contains various lubricating macromolecules such as sialomucin, hyaluronan and phospholipids. These, coupled with the smoothness of the glycocalyces and hydrodynamic lubrication of the pleural fluid itself, reduces the frictional coefficient when the opposing pleural surfaces have to slide against each other during ventilation, thus help improving the pulmonary compliance.

The adhesive property of the pleural fluid to various cellular surfaces, coupled with its oncotic pressure and the negative fluid pressure, also holds the two opposing pleurae in close sliding contact and keeps the pleural space collapsed, maximizing the total lung capacity while maintaining a functional vacuum. When inhalation occurs, the contraction of the diaphragm and the external intercostal muscles (along with the bucket/pump handle movements of the ribs and sternum) increases the volume of the pleural cavity, further increasing the negative pressure within the pleural space. As long as the functional vacuum remains intact, the lung will be drawn to expand along with the chest wall, relaying a negative airway pressure that causes an airflow into the lung, resulting in inhalation. Exhalation is however usually passive, caused by elastic recoil of the alveolar walls and relaxation of respiratory muscles. In forced exhalation, the pleural fluid provides some hydrostatic cushioning for the lungs against the rapid change of pressure within the pleural cavity.[ medical citation needed ]

Clinical significance

Pleuritis or pleurisy is a inflammatory condition of pleurae. Due to the somatic innervation of the parietal pleura, pleural irritations, especially if from acute causes, often produce a sharp chest pain that is worse by breathing, known as pleuritic pain.[ citation needed ]

Pleural disease or lymphatic blockages can lead to a build-up of serous fluid within the pleural space, known as a pleural effusion. Pleural effusion obliterates the pleural vacuum and can collapse the lung (due to hydrostatic pressure), impairing ventilation and leading to type 2 respiratory failure. The condition can be treated by mechanically removing the fluid via thoracocentesis (also known as a "pleural tap") with a pigtail catheter, a chest tube, or a thoracoscopic procedure. Infected pleural effusion can lead to pleural empyema, which can create significant adhesion and fibrosis that require division and decortication. For recurrent pleural effusions, pleurodesis can be performed to establish permanent obliteration of the pleural space. [14]

See also

Related Research Articles

<span class="mw-page-title-main">Thoracic cavity</span> Chamber of the body of vertebrates that is protected by the rib cage

The thoracic cavity is the chamber of the body of vertebrates that is protected by the thoracic wall. The central compartment of the thoracic cavity is the mediastinum. There are two openings of the thoracic cavity, a superior thoracic aperture known as the thoracic inlet and a lower inferior thoracic aperture known as the thoracic outlet.

<span class="mw-page-title-main">Body cavity</span> Internal space within a multicellular organism

A body cavity is any space or compartment, or potential space, in an animal body. Cavities accommodate organs and other structures; cavities as potential spaces contain fluid.

<span class="mw-page-title-main">Pleural cavity</span> Thin fluid-filled space between the two pulmonary pleurae (visceral and parietal) of each lung

The pleural cavity, pleural space, or interpleural space is the potential space between the pleurae of the pleural sac that surrounds each lung. A small amount of serous pleural fluid is maintained in the pleural cavity to enable lubrication between the membranes, and also to create a pressure gradient.

<span class="mw-page-title-main">Pericardium</span> Double-walled sac containing the heart and roots of the great vessels

The pericardium, also called pericardial sac, is a double-walled sac containing the heart and the roots of the great vessels. It has two layers, an outer layer made of strong inelastic connective tissue, and an inner layer made of serous membrane. It encloses the pericardial cavity, which contains pericardial fluid, and defines the middle mediastinum. It separates the heart from interference of other structures, protects it against infection and blunt trauma, and lubricates the heart's movements.

<span class="mw-page-title-main">Respiratory tract</span> Organs involved in transmission of air to and from the point where gases diffuse into tissue

The respiratory tract is the subdivision of the respiratory system involved with the process of respiration in mammals. The respiratory tract is lined with respiratory epithelium as respiratory mucosa.

<span class="mw-page-title-main">Thoracic diaphragm</span> Sheet of internal skeletal muscle

The thoracic diaphragm, or simply the diaphragm, is a sheet of internal skeletal muscle in humans and other mammals that extends across the bottom of the thoracic cavity. The diaphragm is the most important muscle of respiration, and separates the thoracic cavity, containing the heart and lungs, from the abdominal cavity: as the diaphragm contracts, the volume of the thoracic cavity increases, creating a negative pressure there, which draws air into the lungs. Its high oxygen consumption is noted by the many mitochondria and capillaries present; more than in any other skeletal muscle.

<span class="mw-page-title-main">Pleurisy</span> Disease of the lungs

Pleurisy, also known as pleuritis, is inflammation of the membranes that surround the lungs and line the chest cavity (pleurae). This can result in a sharp chest pain while breathing. Occasionally the pain may be a constant dull ache. Other symptoms may include shortness of breath, cough, fever, or weight loss, depending on the underlying cause. Pleurisy can be caused by a variety of conditions, including viral or bacterial infections, autoimmune disorders, and pulmonary embolism.

<span class="mw-page-title-main">Pleural effusion</span> Accumulation of excess fluid in the pleural cavity

A pleural effusion is accumulation of excessive fluid in the pleural space, the potential space that surrounds each lung. Under normal conditions, pleural fluid is secreted by the parietal pleural capillaries at a rate of 0.6 millilitre per kilogram weight per hour, and is cleared by lymphatic absorption leaving behind only 5–15 millilitres of fluid, which helps to maintain a functional vacuum between the parietal and visceral pleurae. Excess fluid within the pleural space can impair inspiration by upsetting the functional vacuum and hydrostatically increasing the resistance against lung expansion, resulting in a fully or partially collapsed lung.

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<span class="mw-page-title-main">Thoracotomy</span> Surgical procedure

A thoracotomy is a surgical procedure to gain access into the pleural space of the chest. It is performed by surgeons to gain access to the thoracic organs, most commonly the heart, the lungs, or the esophagus, or for access to the thoracic aorta or the anterior spine. A thoracotomy is the first step in thoracic surgeries including lobectomy or pneumonectomy for lung cancer or to gain thoracic access in major trauma.

<span class="mw-page-title-main">Mediastinum</span> Central part of the thoracic cavity

The mediastinum is the central compartment of the thoracic cavity. Surrounded by loose connective tissue, it is an undelineated region that contains a group of structures within the thorax, namely the heart and its vessels, the esophagus, the trachea, the phrenic and cardiac nerves, the thoracic duct, the thymus and the lymph nodes of the central chest.

<span class="mw-page-title-main">Serous membrane</span> Smooth coating lining contents and inner walls of body cavities

The serous membrane is a smooth tissue membrane of mesothelium lining the contents and inner walls of body cavities, which secrete serous fluid to allow lubricated sliding movements between opposing surfaces. The serous membrane that covers internal organs is called visceral, while the one that covers the cavity wall is called parietal. For instance the parietal peritoneum is attached to the abdominal wall and the pelvic walls. The visceral peritoneum is wrapped around the visceral organs. For the heart, the layers of the serous membrane are called parietal and visceral pericardium. For the lungs they are called parietal and visceral pleura. The visceral serosa of the uterus is called the perimetrium. The potential space between two opposing serosal surfaces is mostly empty except for the small amount of serous fluid.

<span class="mw-page-title-main">Hemothorax</span> Blood accumulation in the pleural cavity

A hemothorax is an accumulation of blood within the pleural cavity. The symptoms of a hemothorax may include chest pain and difficulty breathing, while the clinical signs may include reduced breath sounds on the affected side and a rapid heart rate. Hemothoraces are usually caused by an injury, but they may occur spontaneously due to cancer invading the pleural cavity, as a result of a blood clotting disorder, as an unusual manifestation of endometriosis, in response to Pneumothorax, or rarely in association with other conditions.

<span class="mw-page-title-main">Chylothorax</span> Medical condition

A chylothorax is an abnormal accumulation of chyle, a type of lipid-rich lymph, in the space surrounding the lung. The lymphatics of the digestive system normally returns lipids absorbed from the small bowel via the thoracic duct, which ascends behind the esophagus to drain into the left brachiocephalic vein. If normal thoracic duct drainage is disrupted, either due to obstruction or rupture, chyle can leak and accumulate within the negative-pressured pleural space. In people on a normal diet, this fluid collection can sometimes be identified by its turbid, milky white appearance, since chyle contains emulsified triglycerides.

Hemopneumothorax, or haemopneumothorax, is the condition of having both air (pneumothorax) and blood (hemothorax) in the chest cavity. A hemothorax, pneumothorax, or the combination of both can occur due to an injury to the lung or chest.

<span class="mw-page-title-main">Thoracic wall</span> Boundary of the chest cavity

The thoracic wall or chest wall is the boundary of the thoracic cavity.

<span class="mw-page-title-main">Root of the lung</span> Anatomical structure

The root of the lung is a group of structures that emerge at the hilum of each lung, just above the middle of the mediastinal surface and behind the cardiac impression of the lung. It is nearer to the back than the front. The root of the lung is connected by the structures that form it to the heart and the trachea. The rib cage is separated from the lung by a two-layered membranous coating, the pleura. The hilum is the large triangular depression where the connection between the parietal pleura and the visceral pleura is made, and this marks the meeting point between the mediastinum and the pleural cavities.

<span class="mw-page-title-main">Costodiaphragmatic recess</span>

The costodiaphragmatic recess, also called the costophrenic recess or phrenicocostal sinus, is the posterolateral fringe of the pleural space, a potential space around the lung inside the pleural cavity. It is located at the acutely angled junction ("reflection") between the costal and diaphragmatic parietal pleurae, and is interpreted two-dimensionally on plain X-rays as the costophrenic angle. It measures approximately 5 cm (2.0 in) vertically and extends from the eighth to the tenth rib along the mid-axillary line.

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<span class="mw-page-title-main">Mediastinal shift</span> Medical condition

Mediastinal shift is the deviation of the mediastinal structures towards one side of the chest cavity, usually seen on chest radiograph. It indicates a severe asymmetry of intrathoracic pressures. Mediastinal shift may be caused by volume expansion on one side of the thorax, volume loss on one side of the thorax, mediastinal masses and vertebral or chest wall abnormalities. Another radiologic sign, which is a component of mediastinal shift, is tracheal deviation. Tracheal deviation, with the trachea located in the superior mediastinum, is an indicator of upper mediastinal shift while a shift in the position of the heart, located within the middle mediastinum, represents a lower mediastinal shift.

References

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