Kiesselbach's plexus, also known as Little's area, is an anastomotic vascular network located in the anterior inferior quadrant of the nasal septum, overlying the septal cartilage at the entrance to the nasal cavity.[1][2] It is formed by the convergence of five arterial branches: the sphenopalatine artery (a branch of the maxillary artery), the anterior and posterior ethmoidal arteries (branches of the ophthalmic artery), the septal branch of the superior labial artery (a branch of the facial artery), and the greater palatine artery (another branch of the maxillary artery).[1][2][3] This plexus receives blood supply from both the internal and external carotid artery systems, with venous drainage primarily through the facial vein, ophthalmic veins, and pterygoid plexus.[2]The primary function of Kiesselbach's plexus is to provide oxygenated blood to the nasal mucosa, facilitating the warming and humidification of inhaled air to optimize gas exchange in the lungs.[1] Clinically, it is the most common site of anterior epistaxis (nosebleeds), accounting for 80-90% of cases due to the fragile nature of the overlying mucosa, which is susceptible to trauma, dryness, temperature extremes, and irritation.[4][3] Anterior nosebleeds originating here are typically less severe than posterior epistaxis and can often be managed with simple measures like nasal packing or cauterization, though recurrent bleeding may necessitate further evaluation for underlying coagulopathies or vascular anomalies.[3]Named after the 19th-century German otolaryngologist Wilhelm Kiesselbach (1839-1902), who first described it, the plexus's superficial location and rich vascularity make it a focal point in otorhinolaryngology, particularly in pediatric populations where nosebleeds are frequent.[1][2]
Anatomy
Location
Kiesselbach's plexus is an anastomotic arterial network located in the anterior inferior quadrant of the nasal septum, overlying the septal cartilage, and is also referred to as Little's area or Kiesselbach's triangle.[5][2] This region lies just above the nasal vestibule and is in close proximity to the anterior nasal mucosa, distinguishing it from the more posterior aspects of the nasal cavity that involve different vascular territories.[6][3]The plexus exhibits a vertical orientation positioned immediately behind the columella, with extensions that traverse the nasal floor and connect to the venous plexus along the lateral nasal wall.[7] This positioning facilitates its role as a key vascular hub in the anterior nasal structures, formed by the convergence of multiple arterial branches.[8]Due to its superficial location, Kiesselbach's plexus is readily accessible for clinical examination via anterior rhinoscopy using a nasal speculum, allowing direct visualization of the mucosal surface without invasive procedures.[6]
Arterial Contributions
Kiesselbach's plexus is an anastomotic network formed by the convergence of five primary arteries on the anteroinferior aspect of the nasal septum.[5] These arteries originate from both the internal and external carotid systems, providing a redundant blood supply to this region.[8]The contributing arteries include the anterior ethmoidal artery, which arises from the ophthalmic artery (a branch of the internal carotid artery); the sphenopalatine artery, originating from the maxillary artery (external carotid system); the greater palatine artery, also from the maxillary artery via its descending palatine branch; the septal branch of the superior labial artery, derived from the facial artery (external carotid system); and the posterior ethmoidal artery, from the ophthalmic artery.[5][8]Each artery follows a distinct path to reach the nasal septum. The anterior ethmoidal artery enters the nasal cavity through the anterior ethmoidal foramen near the cribriform plate, then descends along the septum.[5] The sphenopalatine artery passes through the sphenopalatine foramen to supply the posterior septum via its septal branches.[8] The greater palatine artery ascends from the palate through the incisive canal to reach the anterior septum.[5] The septal branch of the superior labial artery travels superiorly from the upper lip along the anterior nasal septum.[8] The posterior ethmoidal artery, when contributory, enters via the posterior ethmoidal foramen and supplies more posterior aspects of the septum.[8]These vessels interconnect to form a dense, capillary-rich plexus without a dominant arterial supply, ensuring robust vascularization through mutual anastomoses.[5]Anatomical variations occur, particularly in branch patterns and symmetry, as observed in cadaveric studies. For instance, the sphenopalatine artery typically bifurcates into 2–4 posterior septal branches upon entering the nasal cavity, though up to 10 branches have been noted in some specimens; asymmetries between nasal sides are common, and the posterior ethmoidal artery contributes less consistently, sometimes absent in the anterior plexus region.[8]
Function
Blood Supply to Nasal Structures
Kiesselbach's plexus serves as a critical arterial anastomosis that delivers oxygenated blood to the anteroinferior portion of the nasal septum, specifically nourishing the overlying mucosa and the quadrangular septal cartilage beneath it. This targeted vascular supply ensures the viability and structural integrity of these tissues, which are essential for the nose's role in respiratory physiology.[5]By maintaining robust perfusion to the nasal mucosa, the plexus supports key functions such as the regulation of humidity and temperature in inspired air, as well as the indirect facilitation of particle filtration through the secretion of protective mucus by well-vascularized epithelial cells. The rich blood flow promotes mucosal health, preventing desiccation and enabling the tissue to trap airborne particles effectively before they reach the lower airways.[5][9][10]The venous drainage of Kiesselbach's plexus connects to the extensive nasal venous plexus, allowing deoxygenated blood to recirculate efficiently into larger venous channels, including the facial vein, ophthalmic veins, and pterygoid plexus, thereby completing the local circulatory loop. This integration enhances overall nasal vascular efficiency without compromising tissue oxygenation.[10][5][2]In comparison to other nasal regions, Kiesselbach's plexus demonstrates a notably higher density of anastomoses, formed by converging arterial branches, which provides redundant blood pathways and greater resilience against potential vascular disruptions in this vulnerable anterior area.[5]
Hemodynamic Role
Kiesselbach's plexus serves as a critical anastomotic network in the nasal vasculature, integrating arterial contributions from both the internal and external carotid systems to provide redundancy in blood supply. This anastomosis, formed by branches such as the anterior and posterior ethmoidal arteries (from the internal carotid via the ophthalmic artery) and the sphenopalatine, greater palatine, and septal branch of the superior labial arteries (from the external carotid via the maxillary and facial arteries), enables collateral circulation that prevents ischemia in the event of occlusion or compromise in any single contributing vessel.[5][11][2] The redundant pathways ensure continuous perfusion to the anterior nasal septum, minimizing the risk of localized tissue hypoxia during fluctuations in arterial inflow.[12]The hemodynamic interplay within the plexus also facilitates the integration of contributions from the internal carotid system and the external carotid system, promoting balanced blood distribution across the nasal mucosa. By linking these divergent arterial territories, the plexus supports stable laminar flow in the superficial mucosal vessels.[8] This equalization is essential for maintaining consistent vascular tone in the erectile tissue of the nasal septum, which aids in airflow modulation.[5]Furthermore, the plexus plays a key role in nasal thermoregulation and humidification by delivering a substantial volume of blood to the mucosal surface, enabling rapid heat and moisture exchange with inhaled air. The dense capillary bed allows for efficient warming of cooler ambient air to body temperature and near-total humidification, preventing desiccation of the respiratory epithelium.[5] This vascular response is dynamically regulated to accommodate changes in airflow, temperature, or humidity, with the plexus supporting engorgement or vasoconstriction as needed.[13] In physiological high-flow states, such as during increased respiratory demands or environmental stress, the network's capacity for elevated perfusion contributes to its overall resilience but also underscores inherent vascular fragility under conditions like dehydration or inflammation, where altered hemodynamics may exacerbate flow imbalances.[5]
Clinical Significance
Association with Epistaxis
Kiesselbach's plexus serves as the primary site for the majority of anterior epistaxis cases, accounting for approximately 90% of such nosebleeds due to its superficial location and the friable nature of its anastomotic vessels on the anterior nasal septum.[3] This vulnerability arises from the plexus's rich vascular network, which is prone to rupture under minor trauma or irritation, making it a focal point for bleeding that is often visible upon nasal examination.[14]Several risk factors contribute to epistaxis originating from Kiesselbach's plexus, categorized into environmental, traumatic, local, and systemic elements. Environmental factors, such as dry air and low humidity, desiccate the nasal mucosa, increasing susceptibility to vessel fragility and bleeding.[15] Traumatic causes include habitual nose picking and direct nasal injury, which commonly affect the anterior septum in susceptible individuals.[16] Local irritants like mucosal inflammation from infections or allergic rhinitis further exacerbate vessel permeability in the region.[17] Systemically, conditions such as hypertension and use of anticoagulant medications heighten the risk by promoting vascular instability or impairing hemostasis.[18]Epistaxis linked to Kiesselbach's plexus exhibits a bimodal age distribution, with peak incidence in children under 10 years—often due to exploratory behaviors like nose picking—and in adults over 50 years, frequently associated with comorbidities like hypertension.[3][19] It is more common in males than females.[19] In pediatric populations, the condition is particularly prevalent among children aged 3 to 5 years, reflecting developmental habits that target the anterior nasal area.[20]Anterior epistaxis from Kiesselbach's plexus is typically distinguishable from posterior bleeds, presenting as visible, unilateral bleeding that is easier to localize, in contrast to posterior epistaxis originating from Woodruff's plexus, which accounts for only 5-10% of cases and often manifests bilaterally or profusely due to deeper vascular involvement.[21]
Diagnostic and Therapeutic Approaches
Diagnosis of bleeding originating from Kiesselbach's plexus, a frequent site of anterior epistaxis, typically involves direct visualization using a nasal speculum and light source to identify the bleeding site during an anterior rhinoscopy.[3] If the bleeding point is not readily apparent or for suspected posterior involvement, nasal endoscopy provides enhanced visualization of the nasal cavity to locate the source accurately.[14] In refractory cases unresponsive to initial measures, computed tomography (CT) angiography may be employed to assess vascular anatomy and identify potential arterial sources contributing to persistent epistaxis.[22]Conservative management begins with manual compression by pinching the nostrils together for 10-15 minutes to apply direct pressure on the nasal vasculature, often effectively controlling mild anterior bleeds.[23] Topical vasoconstrictors, such as oxymetazoline spray or drops combined with lidocaine, promote localized vasoconstriction and anesthesia, achieving hemostasis in approximately 65% of cases without further intervention.[24] Adjunctive humidification of the nasal mucosa, using saline sprays or environmental humidifiers, helps prevent mucosal drying and supports ongoing management by maintaining moisture in the nasal passages.[25]For cases not controlled by conservative methods, interventional approaches include chemical cauterization with silver nitrate or electrical cauterization using bipolar devices to directly seal the bleeding vessel in the plexus, often under endoscopic guidance.[23] Nasal packing with absorbable materials or balloons provides tamponade to achieve hemostasis, particularly for moderate anterior bleeds, though it requires monitoring for displacement.[23] In persistent or severe epistaxis, surgical options such as endoscopic sphenopalatine artery ligation target proximal vascular supply, while endovascular embolization offers a minimally invasive alternative with success rates around 90% and low major complication rates.[26][27]Recent advances in treating refractory anterior epistaxis include coblation therapy using radiofrequency, which has shown effectiveness in managing recurrent bleeds, particularly in hereditary hemorrhagic telangiectasia, with average durations of benefit around 25 months.[28]Laser therapies, such as potassium titanyl phosphate or diode lasers, have demonstrated efficacy in reducing recurrence rates in children with recurrent bleeds, especially when combined with treatment for underlying allergic rhinitis.[29]A key complication of aggressive cauterization in the Kiesselbach's area is septal perforation, resulting from excessive tissue necrosis on opposing septal surfaces, which can lead to nasal crusting and obstruction if bilateral treatment is overapplied.[23][30]
Historical Context
Early Descriptions
The recognition of epistaxis, or nosebleeding, dates back to ancient medical texts, where it was often described as a symptom of internal imbalances or external factors such as injury and heat, with vague allusions to bleeding originating from nasal structures but lacking precise anatomical localization of vulnerable sites.[31] For instance, Hippocratic writings from the 5th century BCE noted methods to staunch nasal blood flow, such as compressing the nasal alae, yet did not delineate specific vascular regions within the nose.[32] Similarly, medieval and Renaissance accounts treated epistaxis as a purifying process or lunar-induced event, without identifying a distinct hemorrhagic zone on the nasal septum.[31]A pivotal advancement occurred in 1879 when American surgeon James Lawrence Little, based on clinical observations in surgical pathology, first described a specific vascular lesion on the anterior nasal septum as a primary source of epistaxis.[33] In his seminal paper, Little detailed four cases of recurrent nosebleeds originating from this "hitherto undescribed lesion," characterized by a superficial, friable vascular area approximately half an inch in diameter, located on or near the cartilaginous septum and prone to ulceration and hemorrhage due to its rich capillary network.[33] He emphasized its role in over 90% of observed epistaxis incidents, attributing the site's vulnerability to minor trauma or inflammation, and advocated for targeted cauterization as treatment.[33]Little's observations, drawn from his experience as a professor of surgery at the University of Vermont, underscored the clinical importance of this anterior septal region—later termed "Little's area"—and laid the groundwork for understanding its hemodynamic significance, predating comprehensive vascular dissections.[33] This work influenced subsequent anatomical studies, including the formal naming of the plexus by Wilhelm Kiesselbach in 1884.[34]
Naming and Recognition
Kiesselbach's plexus is named after Wilhelm Kiesselbach (1839–1902), a German otolaryngologist and professor of otology at the University of Erlangen, who provided a detailed description of the arterial anastomosis in the anterior nasal septum in his 1884 article "Ueber spontane Nasenblutungen," published in the Berliner Klinische Wochenschrift.[34] This work highlighted the region's vascular vulnerability to spontaneous bleeding, establishing Kiesselbach's foundational contribution to nasal anatomy.The eponym "Kiesselbach's plexus" directly honors his seminal description, reflecting the convention of attributing anatomical features to key researchers; alternative designations include Kiesselbach's area or Kiesselbach's triangle, emphasizing the localized triangular zone on the nasal septum.[2] Prior to Kiesselbach, American surgeon James Lawrence Little (1836–1885) offered an early account of the area in 1879, identifying it as a site of epistaxis in his publication "A hitherto undescribed lesion as a cause of epistaxis, with four cases" in The Hospital Gazette.[34]During the 20th century, the plexus achieved broader acknowledgment in medical education and literature, with integration into authoritative texts such as the 20th edition of Gray's Anatomy (1918), which referenced its vascular significance in nasal septum descriptions.[35] This period also saw the development of pedagogical aids, including the mnemonic "Kiesselbach drives his Lexus with his LEGS," devised to facilitate recall of the plexus's arterial contributors in clinical training.[36]Initial accounts, including Kiesselbach's, focused on four primary arterial sources, overlooking the posterior ethmoidal artery's potential involvement; subsequent anatomical studies from the mid-20th century onward incorporated this vessel, refining the understanding of the plexus's full composition.[2]