The main mediator of air flow during respiration is the bronchiole. These tiny airways are wrapped in smooth muscle, which allows them to contract or relax in order to restrict or increase air flow in the lung. The trachea and bronchioles are cartilaginous rather than muscular, and are unable to constrict, while the wall of the alveolar sac is also devoid of smooth muscle, made up only of epithelial cells, capillaries, and connective tissue.

The largest airway structure is the trachea. This branches into two smaller bronchi, which enter the left and right lung and bifurcate further into smaller bronchioles. The bronchioles give way into the smallest structures of the lung, the tiny grape-like clusters of alveoli.

There are five lobes total in the human lungs: the right lung has three lobes (the upper lobe, the middle lobe, and the lower lobe) while the left lung has two lobes (the upper lobe and the lower lobe).

The topmost part of the lungs is the apex. This area extends into the neck above the 1st rib and is the location auscultated for a diagnosis of a pancost tumor. The lingula of the lung is a small flap of the lowest part of the upper lobe of the left lung. The hilum is the entry point of the lung for the bronchi, pulmonary artery and vein, and nerves. The trachea is not a part of the lung at all; it is the cartilaginous tube that connects the pharynx and larynx to the lung.

There are two types of alveolar cells: type I cells and type II cells. Each cell type has a unique function within the alveolus, and the dysfunction of either cell type results in serious respiratory pathology. Type I cells are simple squamous epithelial cells that account for about 95% of all alveolar cells. They are the primary cells responsible for diffusion of gasses across the respiratory membranes. Type I alveolar cells are responsible for secreting surfactant, which facilitates the diffusion of substances across the epithelium.

Carbon dioxide has paracrine effects in the airway, causing the smooth muscle of bronchioles to relax. When the partial pressure of carbon dioxide in the alveoli increases, the bronchioles dilate. This allows for increased ventilation.

Type II alveolar cells secrete pulmonary surfactant, a lipoprotein complex that is essential for lung function. This surfactant acts to break up the surface tension of fluid coating the lung airspaces, allowing for alveolar compliance and reducing the buildup of fluid in the lung. Lack of surfactant can lead to atelectasis, or collapse of part of the lung.

Dead space is the volume of air that remains in the trachea, bronchi, and bronchioles during respiration. It does not enter the alveoli and so does not participate in gas exchange. In the average adult, the amount of air left in the dead space after expiration is .

The diaphragm is innervated by the phrenic nerve. This nerve exits the spine at C3-C5. In the case of spinal cord trauma, if injury occurs above C3, the diaphragm is no longer able to function on its own and breathing assistance is generally required.

Tidal breathing is the term for relaxed inhalation and exhalation (as opposed to maximum inspiration and forced exhalation). The average volume of air breathed into and out of the respiratory system during tidal breathing is .