The lungs are two sponge-like, cone-shaped structures that fill most of the chest cavity. Their essential function is to provide oxygen from inhaled air to the bloodstream and to exhale carbon dioxide.
Humans have two lungs, the left lung, and the right
lung. They are of different sizes and are divided into multiple lobes. A healthy lung has a pinkish appearance, and if you
could see it outside the body, it would look like a squishy, rubbery structure.
The lungs are located a little toward the posterior
part of the human body, just below the collarbone, extending down to the diaphragm, the muscular partition that separates
the chest and abdominal cavities. The left and right lungs are situated on the
two sides of the body with the heart, another vital organ in the thoracic
cavity, located a little in front of, and at the middle of them. They are also
surrounded by the rib cage, along with other organs in the chest cavity.
Structure and Anatomy of the Lungs
A person's lungs are
not the same size. The right lung is a little wider than the left lung, but it
is also shorter. The right lung is shorter because it has to make room for the
liver, which is right beneath it. The left lung is narrower because it must
make room for the heart.
Typically, a man's lungs
can hold more air than a woman's. At rest, a man's lungs can hold around 750
cubic centimetres of air, while a woman's can hold around 285 to 393 cc.
The Lungs Structure |
Each lung has an apex, base, root, and hilum or hilus of the lung, as well as three surfaces, keeping the lung connected to the sides of the thorax.
The apex is the
superior part of the lungs, with its highest point located above the first rib,
extending through the superior opening of the thoracic cavity, into the
inferior floor of where the neck starts..
The base is the
concave lower surface of the lung that rests over the diaphragm. Structures
including the bronchus, bronchial veins and arteries, pulmonary artery, two of
the pulmonary veins, pulmonary plexus of nerves (anterior and posterior), and
lymphatic vessels bundle together to form the root of the lungs.
This root not only connects the two lungs with each other but also keeps them
suspended in the thoracic cavity.
The structures of the root enter/leave the lung via the hilum. It is the wide depressed area located
just a little higher than the centre of the medial surface of the lungs.
Segmental Anatomy
In adults, each lung is 25cm to 30cm long, with the
right lung being a little larger than the left lung as the former has three
lobes while the latter only has two.
If the surface of the lungs could be spread out flat,
the total surface area of the two lungs together would be over forty times
greater than that of the outer surface of the human body, making them one of
the largest organs.
Right Lung
The right lung is divided
into the superior (upper), middle and inferior (lower) lobes. These are further
separated into ten segments.
Left Lung
The left lung is a little smaller than the right one
(to make space for the heart), and is divided into the superior (upper) and
inferior (lower) lobes. Even though there are only two lobes, the upper lobe
has a projection, referred to as the lingula (meaning ‘little tongue’ in Latin)
that serves as an equivalent to the middle lobe of the right lung.
Fissures of the Lung: Both the left and right lungs have an oblique fissure separating the
superior lobes from the inferior lobes, while in the right lung there is a
horizontal fissure to keep the middle and superior lobes apart.
Surfaces and Borders of the Lung
Pleura and
Pleural Cavity: A pleura is a two-layered serous (fluid-filled)
membrane that covers the lungs, providing a cushion to protect it from trauma
and also to facilitate the process of respiration. There are two pleurae in the
human body, covering the two lungs.
The outer layer or parietal pleura lines
the inner walls of the chest cavity, while the inner or visceral pleura is
attached to the outer surface of the lungs. The two layers form a hollow space
between themselves, which is known as the pleural cavity and is filled
with pleural fluid, so the two pleural layers do not stick to each other.
Mediastinum
or The Space Between the Two Lungs: The area around
the middle of the thorax, between the right and left pleural sacs, is known as the
mediastinum. The space is divided into the inferior and superior
mediastinum. The inferior mediastinum is larger between the two and further
separated into the posterior, middle, anterior and mediastinum.
Diaphragm: It is the convex
or dome-shaped sheet of muscle that both the lung bases rest upon. The
diaphragmatic surface of both the lungs is concave to accommodate the shape of
the diaphragm. It is one of the vital muscles in the respiratory system, it
separates the chest cavity from the abdominal cavity.
The Three Lung Surfaces
Costal Surface: The convex, smooth surface, facing the inner surface of the wall
of the thorax. It covers the largest area among the three surfaces of the lung. The costal pleura keeps it separated from the ribs
and the deepest intercostal muscles (muscles running between the ribs, keeping
the rib cage flexible).
Mediastinal Surface:
The surface between the left and right lungs, it
houses the hilum. It also covers the part of the lungs next to the heart. The
left lung has a deep indentation, referred to as the cardiac notch, along its
mediastinal surface to make space for the apex of the heart.
These two surfaces meet each other at the apex, while they are separated at the base by the inferior
border of the lung. The smooth and rounded area at the back, where the costal
surface and the mediastinal surface meets, is marked as the posterior border.
Diaphragmatic Surface: As the name suggests, this
is a concave basal surface, facing the diaphragm. The right lung has a deeper
concave base as it is positioned higher to make space for the liver located beneath.
Respiratory Area of the Lungs (Lung Parenchyma): These
are structures in the lungs directly responsible for the
function of respiration collectively form the lung parenchyma. It includes the
bronchial tubes, blood vessels, alveoli, and alveolar
ducts.
Bronchi and Bronchioles: As the windpipe reaches the lungs, it divides into the left and right primary
bronchus, which then enters the left and right lung respectively. Once inside
the lungs, the bronchi divide into narrower tubes called bronchioles, while this again branch into terminal
bronchioles, the smallest respiratory tubes in human lungs. This intricate
structure in each lung is called the bronchial tree. Both bronchi and
bronchioles are encircled with hyaline cartilage rings to help them maintain
their shape.
Alveoli: Tiny air-filled
sacs, alveoli are the primary functioning units of the lungs, the
actual site of gas exchange. A healthy person has 300 to 700 million alveoli
(480 million in average), meaning there are
around 150 to 350 million alveoli in each lung.
The inner walls of the alveoli are lined
with a thin layer of water and surfactant, known as the pulmonary surfactant, a protein-lipid mixture secreted by type
II alveolar cells. It plays a crucial role in reducing the surface tension of
the alveoli to prevent them from collapsing during gas exchange. This, in turn,
helps the lungs to maintain their shape.
Vasculature of the Lungs: Each lung has one pulmonary artery and two pulmonary veins. The
pulmonary artery carries deoxygenated blood to the lungs where it receives
oxygen and then is carried back into the heart by the pulmonary veins. .There are usually two bronchial arteries on the left
and one on the right, to supply the lung roots, visceral pleura, bronchi, and
other supporting lung tissues with oxygen-rich blood.
The bronchial veins drain the bronchi and
the structures in the hilum, as well as some other supporting structures.
Functions of Lungs
The lungs are responsible for inhalation and
exhalation, the method in which the body gets oxygen and gets rid of carbon
dioxide. An adult person generally takes 15-20 breaths per minute, and about
20,000 breaths per day.
Function of Lungs in Respiratory System
Gas Exchange
When we inhale, the air enters through the nasal cavity, traveling down via the pharynx, larynx, and trachea to enter the lungs via the two primary bronchi.
Then it reaches the alveoli, the small air sacs in the lungs where the gas
exchange occurs, through the bronchioles.
The one-cell thick walls of the alveoli have an
intricate network of blood capillaries. As the oxygen-rich air reaches these
alveoli, the blood flowing through the capillaries takes up the oxygen in the
method of diffusion occurring across the thin walls of the alveoli and the
capillaries (the process in which a substance moves from an area of low
concentration to an area of high concentration). Similarly, the carbon dioxide
carried by the blood from the different organs and tissues of the body are
absorbed by the alveoli so they can be excreted along with the exhaled air.
Gas exchange in the lungs |
Total Lung Capacity (TLC) and Lung Compliance
TLC refers to the maximum volume of air the lungs of
an adult person can hold. It is the sum of the air released by the lung after a
maximum exhalation (vital capacity or VC) and the volume of air left behind
within the lungs after a deepest exhalation (residual volume or RV). The TLC of
human lungs is 6 litres.
Lung compliance is the measurement of the lungs’ capacity to expand with the changes in
air pressure during breathing. Both TLC and lung compliance are measured for
the diagnosis and treatment of various lung disorders.
Function of Lung muscles
The lungs function as a pair of bellows, pulling in
fresh air into the body when they expand, and expelling the impure air when
they compress. However, there are no muscles in the lungs to control this
expansion and compression. The diaphragm helps in pumping the lungs, with the
help of the abdominal muscles, and intercostal muscles.
The diaphragm and abdominal muscles contract and
expand to increase and decrease the volume of the lungs, while the intercostal
muscles control the space within the rib cage. During inhalation, the diaphragm
relaxes and extends towards the abdominal cavity to make the air from outside
rush into the vacuum within the lungs, with the intercostal muscles making sure
that the rib cage has enough space to accommodate the inflated lungs.
Similarly, during exhalation, the diaphragm pushes upward into the lungs so
they recoil, putting pressure on the alveoli, which then expel the carbon
dioxide-rich air.
Air purification function of lungs
When we inhale, the air that enters the respiratory
tract is usually full of impurities like dust particles, pollen, etc. Some of
these get trapped in the nasal cavity by nose hairs to cleanse
the air partially. The rest of the cleaning is done by the mucus membrane lining the airways, the
trachea, bronchi, and bronchioles, where any remaining foreign particles are
trapped in the sticky mucus secreted by goblet cells. It makes sure no harmful
substance comes in contact with the blood capillaries during gas exchange.
Then, the respiratory cilia, the tiny hair-like growths covering the inner
walls, sweep the impurities stuck in the mucus back towards the opening of the
respiratory tract, where they can be excreted through the nose or mouth.
Circulatory Function of Lungs
The oxygen-rich blood travels through the pulmonary
veins into the left atrium, and then the left ventricle of the heart, from
where it is pumped out to reach each and every cell in the body. Then, the
cells receive the oxygen and send the carbon dioxide produced by the cellular
functions into the blood to be carried by the superior and inferior vena cava
veins to the right atrium, from where it reaches the right ventricle. This
deoxygenated blood is then pumped back to the lungs by the right ventricle via
the pulmonary artery. There, it releases carbon dioxide and gets oxygen so it
can again supply the whole body.
Diseases and Associated Conditions of the lungs
Lung Cancer: There
are three types of this lung cancer, non-small cell, small cell, and lung
carcinoid tumour. These three vary in their rate of growth of the cancerous
cells, requiring different treatment options. The non-small cell type is the
most commonly occurring lung cancer, with subtypes including squamous cell
carcinoma and large cell carcinoma. Excessive smoking is one of the most common
causes of lung cancer, and common symptoms include wheezing, coughing up blood,
and breathing troubles. Standard treatment measures include chemotherapy,
radiation, and surgery.
Asthma: One of the
most common breathing and lung-related disorders, asthma is characterised by
inflamed and swollen airways that make it difficult for air to pass through
them, leading to symptoms like shortness of breath, congestion, wheezing,
coughing, chest tightness, and fatigue. The condition also leads to excess
mucus production which accumulates in the airways, blocking them. Asthma has no
cure, with treatment including medications, inhaler, and certain lifestyle
changes for management.
Pneumonia: A
condition usually caused by a bacterial infection, pneumonia leads to
inflammation and fluid accumulation within the alveoli of the lungs. It may
cause chest pain, trouble breathing, congestion, fever, sweating and chills,
coughing, and appetite loss. Treatment includes antibiotics and other
medications along with lots of rest.
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