The nasal cavity is a roughly cylindrical, midline, airway passage that extends from the nasal ala anteriorly to the choana posteriorly. It is divided in the midline by the nasal septum. On each side, it is flanked by the maxillary sinuses, and roofed by the frontal, ethmoid, and sphenoid sinuses, in an anterior to posterior fashion. While seemingly simple, sinonasal anatomy is composed of intricate and subdivided air passages and drainage pathways that connect the sinuses.
There are 4 paired sinuses in humans. They are all in line with pseudostratified columnar epithelium.
The function of the paranasal sinuses is debated. However, they are implicated in several roles:
To develop a strong understanding of paranasal sinus anatomy, it is also important to understand the anatomical relationships of the sinuses to surrounding structures. The lateral nasal wall contains many structures and recesses that are important for understanding paranasal sinus anatomy.
The maxillary sinus is located under the eyes in the maxillary bone. Adjacent structures include the lateral nasal wall, the orbital floor, and the posterior maxillary wall which contains the pterygopalatine fossa. The maxillary sinus is innervated by the infraorbital nerve (CN V2). The maxillary and facial arteries supply the sinus, and the maxillary vein supplies venous drainage. As mentioned already, the maxillary sinus drains into the ethmoid infundibulum. There is typically only one ostium per maxillary sinus; however, cadaver studies have shown 10% to 30% have an accessory ostium. The size of the maxillary sinus at adult stage is approximately 15 mL, making it the largest paranasal sinus.
The frontal sinus is located superior to the orbit and within the frontal bone. The typical volume at the adult stage is 4 to 7 mL. The frontal sinus drains into the frontal recess via the middle meatus. As noted previously, this drainage can be variable, either medial or lateral to the uncinate, depending on its attachment. The frontal sinus vasculature consists of the supraorbital and supratrochlear arteries and ophthalmic and supraorbital veins. Similarly, it's innervation is provided by the supraorbital and supratrochlear nerves (CNV1). Several anatomical spaces/structures are important to frontal sinus anatomy:
The sphenoid sinuses are located centrally and posteriorly within the sphenoid bone. They drain into the sphenoethmoidal recess located within the superior meatus. The sphenopalatine artery supplies the sinus, and venous drainage is via the maxillary vein. Innervation is provided by the sphenopalatine nerve, which is comprised of parasympathetic fibers and CN V2. The typical adult size is 0.5 to 8 mL. Several important structures have a close anatomical relationship to the sphenoid sinus. The carotid artery is located adjacent to the lateral wall of the sinus, and in 25% of patients, it is dehiscent in this area. The optic nerve is also located adjacent to the lateral wall of the sinus and can be dehiscent in up to 5% of individuals.
Development of the paranasal sinuses is heralded by the appearance of a series of ridges or folds on the lateral nasal wall at approximately the eighth week of gestation, known as the ethmoturbinals. Six to 7 folds emerge initially, but eventually, only 3 to 4 ridges persist through regression and fusion.
As development progresses, furrows form between these ethmoturbinals, which leads to the establishment of rudimentary meati and recesses.
The frontal sinus originates from anterior pneumatization of the frontal recess into the frontal bone. The frontal sinus does not appear until the age of 5 to 6 years old. The sphenoid sinus develops during the third month of gestation. During this time, the nasal mucosa invaginates into the posterior portion of the cartilaginous nasal capsule to form a pouch-like cavity. The wall surrounding this cartilage is ossified in the later months of fetal development. Then, during the second and third year of life, the cartilage is resorbed, and the cavity becomes attached to the body of the sphenoid. By the sixth or seventh year of life, pneumatization of the sphenoid sinus progresses, and by the 12th year, the pneumatization is complete with pneumatization of the anterior clinoids and pterygoid process. The maxillary sinus is the first to develop in utero. The maxillary sinus shows a biphasic growth pattern, with growth at 3 and 7 to 18 years of age. The ethmoid sinuses are comprised of 3 to 4 air cells at birth. And by the time an individual reaches adulthood, they consist of 1 to 15 aerated cells.
The major artery of the maxillary sinus is the internal maxillary artery, a branch of the external carotid artery. The ethmoid and frontal sinuses have a variety of blood supplies, including meningeal vessels for the cribriform plate above the ethmoid sinuses, as well as the posterior wall of the frontal air cells. The sphenoid sinuses may derive blood supply from small branches of the cavernous internal carotid arteries. Rarely, an aneurysm of the internal carotid artery may invaginate into the sphenoid sinus, making endovascular coiling the preferred technique for aneurysm obliteration.
The major nerve running below the frontal sinus is the first division of the fifth cranial nerve. The major nerve of the inferior aspect of the maxillary sinus is the second division of the fifth cranial nerve. This nerve has sensory but no specific motor functions, as opposed to the third division of cranial nerve five, the latter of which has both sensory (primarily skill of the jaw and the teeth) and motor functions (primarily muscles of mastication).
The frontalis muscle runs over the frontal skull and sinus region and is part of the mechanism of facial expression. The levator muscles of the lips are anchored over the maxillary sinuses. The zygomatic projection of the maxilla is part of the anchorage of the masseter muscle, a powerful closure of the jaw.
Nasal anatomy differs significantly among individuals; certain anatomic variations are relatively common. The variations may contribute to mechanical obstruction of the osteomeatal complex leading to rhinosinusitis.
Concha bullosa is defined as aeration of the middle turbinate. This variation can be either unilateral or bilateral. If large, a concha bullosa in the middle turbinate may lead to obstruction of the middle meatus or infundibulum.
The nasal septal deviation is an asymmetric bowing of the nasal cartilaginous septum. Such a bowing may compress the middle turbinate in a lateral fashion, which may lead to narrowing of the middle meatus. This variation is often congenital, but may also be secondary to nasal trauma.
The middle turbinate usually curves medially toward the nasal septum. However, when the turbinate curves laterally, the resultant anatomic variant is known as a paradoxical middle turbinate. Such a variant can narrow or obstruct the nasal cavity, middle meatus, or infundibulum.
The uncinate process is a structure that has multiple variations between individual patients. The superior attachment of the uncinate process has three major variations that help determine the anatomic configuration of the frontal recess and its drainage:
Haller cells are ethmoid air cells that extend laterally over the medial aspect of the roof of the maxillary sinus. If large enough, they may cause narrowing of the infundibulum. Onodi cells are lateral and posterior extensions of the posterior ethmoid cells. Horizontal septations around the sphenoid sinus delineate them. Importantly, these cells may surround the optic nerve tract, which can increase the risk of injury to the optic nerve during surgery.
Lastly, the height of the ethmoid roof can vary between patients and vary between each side in the same patient. When there is asymmetry of ethmoid roof height in a patient, the risk of intracranial penetration during FESS is higher.
These are only a few of the anatomic variations seen in sinonasal anatomy. While they represent the most common variations, the importance of having a sound understanding of the 3-dimensional anatomy is paramount to safe and effective endoscopic sinus surgery.
Treatment of inflammatory disease of the paranasal sinuses involves both medical therapy and surgical treatment. There are several general guidelines for chronic sinusitis when considering surgical management:
Paranasal sinuses are prone to inflammation and infection. If the paranasal sinuses become blocked from secretions or a mass, the drainage of mucus is interrupted, and sinusitis can result. The maxillary sinus may be involved from any process in the teeth or the gums. The frontal and maxillary sinuses may be involved in allergies. Depending on the cause, sinusitis is treated with corticosteroids, decongestant, nasal irrigation, and hydration. Rarely surgical intervention may be required to enhance drainage.
Malignancies of the paranasal sinuses are rare. The majority of cancers occur in the maxillary sinus and are more common in men than women. Maxillary sinus malignancies occur between ages 45 to 70, and the most frequent is a sarcoma. Even though metastases are rare, these malignancies are locally invasive and destructive. Diagnosis in most cases is delayed, and the prognosis is poor.
Acute rhinosinusitis (ARS) and chronic rhinosinusitis (CRS) are both defined as symptomatic inflammation of the nose and paranasal sinuses. The 2 are distinguished based on the duration of the complaints. Generally speaking, acute rhinosinusitis is widely considered to be an infectious disorder. On the other hand, chronic rhinosinusitis is typically defined as an inflammatory disorder. In ARS, the underlying etiology is typically viral or bacterial, and occasionally fungal. The pathogenesis of ARS involves infection followed by tissue invasion.
The most widely accepted classification system divides CRS into CRS with and without nasal polyps (CRSwNP and CRSsNP, respectively) based on nasal endoscopy. Originally, it was felt that CRSsNP was a disease process characterized by persistent inflammation that led to incomplete resolution of ARS. CRSwNP, on the other hand, was felt to be a noninfectious disease process with unclear etiology, perhaps related to atopy. Current research has instead revealed that the etiology and pathogenesis of either form of CRS is much more complex.
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