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Subdural hygroma

A subdural hygroma is an accumulation of in the , the compartment between the and the enveloping the and . Unlike a , which consists of blood from ruptured vessels, a hygroma typically features clear or slightly xanthochromic fluid and arises from disruptions in circulation rather than hemorrhage. It is a relatively common posttraumatic , occurring in approximately 4–6% of patients with , though incidence can reach 31.6% following mild . Subdural hygromas most frequently develop as a complication of , where mechanisms such as arachnoid membrane tears or bridging vein disruptions allow to leak into the . Other causes include neurosurgical procedures like or , iatrogenic factors such as for intrathecal , and rarely, spontaneous occurrences such as in spontaneous intracranial hypotension. They can also occur in abusive head trauma in infants. Risk factors encompass advanced age (particularly ≥70 years), presence of on initial imaging, use of , and lower platelet counts, while basal skull fractures may offer protective effects. In some cases, hygromas can progress to chronic subdural hematomas, with conversion rates reported between 5% and 58%. Clinically, many subdural hygromas remain asymptomatic and resolve spontaneously, but symptomatic cases may present with , , , altered mental status, focal neurological deficits, seizures, or instability due to and increased . Diagnosis relies on , with computed tomography (CT) revealing hypodense fluid collections isodense to , and (MRI) providing superior detail to differentiate from hematomas or other lesions like benign enlargement of the subarachnoid space. In contexts such as abusive head trauma, the presence of hygromas strongly indicates prior injury and warrants investigation for additional abuse signs. Management is predominantly conservative, involving observation, , , and analgesics, as most cases do not adversely affect long-term . Surgical intervention, such as burr-hole drainage, subdural-peritoneal shunting, or epidural blood patching, is reserved for symptomatic progression, significant , or exceeding 3–5 mm. Complications can include recurrence, neurological deterioration, or, rarely, fatal outcomes, particularly in vulnerable populations like the elderly or those with underlying malignancies.

Background

Definition

A subdural hygroma is defined as an accumulation of (CSF) within the , resulting from the mechanical separation of the arachnoid membrane from the . This separation creates a where CSF collects, distinguishing it from other subdural collections such as hematomas, which involve blood products. Unlike subdural effusions, which may contain proteinaceous fluid without clear CSF origin, hygromas primarily consist of CSF that has leaked through a tear in the arachnoid or via a ball-valve mechanism at the arachnoid-dura interface. Anatomically, the subdural hygroma occupies the space between the and the , most commonly presenting as a crescentic collection along the cerebral convexities, following the contour of the surface without crossing sutures or extending into the . This location reflects the subdural space's confinement by dural reflections, such as the and tentorium cerebelli, and the fluid's tendency to layer dependently over the hemispheric surfaces. Subdural hygromas are classified based on into traumatic (post-injury collections), iatrogenic (following neurosurgical procedures or CSF diversion), and idiopathic or spontaneous types, where no clear precipitant is identified. A subtype known as hematohygroma occurs when minor bleeding mixes with the CSF, resulting in a blood-tinged fluid collection that bridges the features of hygroma and . The terminology evolved in the early 20th century, with initial descriptions of post-traumatic subdural fluid collections appearing during World War I, credited to Professor Erwin Payr in 1916, who documented hygroma-like effusions in wounded soldiers. The term "subdural hygroma" was formalized in 1934 by Walter Dandy, building on earlier 19th-century observations by Charles Horace Mayo in 1894 of cystic subdural masses, shifting recognition from inflammatory or neoplastic entities to traumatic CSF accumulations.

Epidemiology

Subdural hygromas occur in approximately 5-20% of patients with closed , with reported incidences varying based on severity and patient demographics. Reported incidences in mild vary; for example, one study found 31.6% with follow-up imaging, while others report rates around 4-6%. These collections are more frequently observed following , and their development is influenced by factors such as the extent of shrinkage or disruption of the arachnoid membrane. The condition shows a predominance, with approximately 82% of cases occurring in males in some series. The condition predominates in the elderly population, where brain atrophy from age-related changes increases susceptibility, particularly after minor . Studies indicate that patients aged 60 years and older with traumatic subdural hygromas face a heightened risk of progression to chronic , occurring in about 25% of cases. In contrast, subdural hygromas are rare in young adults due to greater resilience and less atrophy. Among infants, the condition arises more commonly owing to the compressible nature of developing tissue, often in association with non-accidental or birth-related events, though specific incidence rates for hygromas remain less precisely quantified than for subdural hematomas, which affect 12-25 per 100,000 infants annually. Comorbidities such as chronic and anticoagulation therapy significantly elevate risk, primarily through exacerbation of atrophy and impaired in settings. has been associated with 12-21% of chronic subdural collections in affected patients, as persistent intake promotes cerebral volume loss. Anticoagulant use, including agents like , correlates with increased occurrence post-, with studies up to 2023 reporting odds ratios up to 2.5 for bleeding-related complications that may contribute to hygroma formation. Geographic or seasonal variations are not well-established, though —a known precipitant due to transient shrinkage—may indirectly heighten incidence in arid regions or during periods of loss, as noted in case series from diverse settings.

Pathophysiology

Etiology

Subdural hygroma primarily arises from disruptions that allow cerebrospinal fluid (CSF) to accumulate in the subdural space, most commonly due to head trauma of varying severity. Minor or severe traumatic brain injuries can cause tears in the arachnoid membrane, creating a one-way valve mechanism that permits CSF entry while preventing its egress, leading to hygroma formation in approximately 4-6% of head injury cases. Cranial surgeries, such as decompressive craniectomy or post-craniotomy procedures, frequently result in iatrogenic arachnoid disruption, with subdural hygroma occurring in over 90% of decompressive craniectomy patients due to surgical trauma exposing the subdural compartment to CSF. Infections like bacterial meningitis can also precipitate hygroma by inflaming the meninges and compromising the arachnoid barrier, particularly in pediatric populations where post-meningitis hygromas develop as a complication of altered CSF dynamics. Additionally, spontaneous CSF leaks, often linked to spontaneous intracranial hypotension, contribute by reducing intracranial pressure and causing compensatory subdural fluid collections. Predisposing factors that facilitate subdural hygroma development include conditions that enlarge the or lower . Brain , prevalent in older adults, widens the potential subdural space, making it more susceptible to fluid accumulation following minor insults; this vulnerability aligns with higher incidence rates in those aged 70 years and older. Ventriculoperitoneal shunts, used for management, reduce intracranial pressure and promote hygroma formation by altering CSF flow and pressure gradients. Iatrogenic events, such as lumbar punctures, can induce CSF leaks that lead to brain sagging and subsequent hygroma, especially in patients with underlying low CSF pressure states. Severe may exacerbate these risks by further diminishing intracranial volume, though it is less commonly documented as a standalone factor. Rare etiologies encompass idiopathic occurrences, particularly in , where hygromas in infants under one year may arise without identifiable or , potentially linked to developmental arachnoid vulnerabilities. Associations with coagulopathies, such as those induced by anticoagulant therapy, can predispose to hygroma progression, though they more frequently influence hemorrhagic transformations. Neoplasms, including ruptured , represent another uncommon cause, where cyst rupture into the mimics traumatic fluid accumulation. The timeline of subdural hygroma onset varies by , with acute forms developing rapidly post-, often within 1 to 40 days (mean approximately 8 days), driven by immediate arachnoid disruption. In contrast, chronic hygromas evolve more gradually over weeks, influenced by persistent low-grade CSF leakage or unresolved predisposing factors like in aging populations.

Pathogenesis

The of subdural hygroma involves the mechanical disruption of the dural-arachnoid interface, typically initiated by that causes a tear in the . This tear allows (CSF) to leak from the subarachnoid space into the subdural compartment, leading to the accumulation of fluid between the dura and arachnoid layers. The separation often occurs at the dural border cell layer, where the absence of robust fibers facilitates the ingress of CSF following shearing forces from . A critical aspect of this process is the formation of a one-way valve mechanism at the site of the arachnoid tear, which permits unidirectional flow of CSF into the while impeding its back into the subarachnoid compartment. This ball-valve effect traps the fluid, promoting persistent accumulation. Additionally, osmotic gradients contribute to expansion, as proteins and cellular debris within the subdural collection increase local , drawing further water influx across semipermeable membranes and exacerbating the hygroma's volume. The progression of subdural hygroma unfolds in distinct stages, beginning with the initial accumulation of hypodense fluid that closely resembles CSF in composition and . Over time, this collection may become encapsulated by the development of neomembranes formed from fibroblasts and inflammatory cells along the dural surface, potentially stabilizing the . Interaction with blood products, such as from minor bridging vein disruptions, can lead to the formation of mixed hygromas or transition toward chronic through repeated microhemorrhages within the encapsulated space. Several factors influence the size and growth of the hygroma, notably reduced (), which creates additional space within the subdural compartment by allowing parenchymal shift away from the dura. In advanced cases, significant buildup can compress underlying cortical veins, impairing venous and further promoting local hypoperfusion and , which sustains the pathological expansion.

Clinical Manifestations

Signs and Symptoms

Subdural hygromas are frequently , particularly when small and without significant , and are often discovered incidentally on following or routine scans. When symptoms occur, they typically arise from or increased and include mild, progressive , , and . In adults, especially the elderly, or altered mental status may predominate, alongside focal neurological deficits such as if the hygroma compresses adjacent . Seizures can also manifest, particularly in cases with cortical irritation. These presentations are often linked to a history of minor , though detailed etiology is discussed elsewhere. Larger hygromas or those exerting may lead to more pronounced altered mental status, ranging from drowsiness to severe confusion. Supratentorial hygromas, the most common location along cerebral convexities, typically produce hemispheric symptoms, while rare infratentorial cases may cause cerebellar signs like . In pediatric patients, symptoms often reflect developmental vulnerabilities and include , , seizures, , and bulging due to elevated . Head enlargement and altered consciousness are also noted, particularly in infants with progressive collections.

Complications

Subdural hygromas can exert a on surrounding , leading to and potential of neural structures. In cases of significant accumulation, this may result in , where the 's central structures deviate from their normal position, increasing . Severe progression can precipitate herniation syndromes, including paradoxical herniation following decompressive procedures, which involves downward of due to differences across the craniectomy defect. If an underlying is present, subdural hygromas carry a of progression to subdural , a purulent collection that can exacerbate neurological compromise through inflammation and formation. This transformation is uncommon but documented in cases following hygroma evacuation, where bacterial contamination, such as , leads to secondary within the subdural . Over time, untreated or progressive subdural hygromas may evolve into chronic subdural hematomas, as repeated episodes of minor bleeding into the hygroma alter its composition from clear -like material to blood-laden fluid. This transformation, driven by neomembrane formation and osmotic gradients that promote hemorrhage. Additionally, recurrent hygromas are observed in approximately 25% of surgically treated cases, often due to persistent leakage or incomplete resolution of the underlying tear in the arachnoid . Hydrocephalus represents a rare complication of subdural hygroma, arising from impaired cerebrospinal fluid flow across the and . particularly those with large or bilateral collections that obstruct CSF pathways, necessitating interventions like ventriculoperitoneal shunting.

Diagnosis

Clinical Assessment

The clinical of suspected subdural hygroma begins with a high index of suspicion in at-risk populations, such as elderly individuals with a history of falls or postoperative patients exhibiting altered , as these scenarios frequently precede the development of cerebrospinal fluid accumulation in the . Suspicion should also arise in cases involving recent head trauma, even mild, or iatrogenic factors like neurosurgical procedures. History taking is crucial and should probe for recent trauma, such as falls or accidents, which are common causes in traumatic cases, surgical interventions such as or . Patients may report common symptoms such as or altered mental status, which integrate into the overall evaluation. focuses on a comprehensive neurological to identify deficits, including evaluation of mental status for or , motor strength (e.g., in extremities), cranial nerve function (e.g., for or ), and focal signs like instability. Fundoscopy should be performed to check for indicating possible raised , while are monitored for Cushing's triad (, , irregular respiration) as evidence of intracranial hypertension. Risk stratification employs standardized tools like the (GCS) to gauge severity, with scores of 13 or higher in mild often correlating with favorable natural recovery, whereas lower scores signal higher risk and poorer outcomes. This initial bedside evaluation guides urgency and directs toward confirmatory steps without relying on imaging interpretations.

Imaging

(CT) is the initial imaging modality of choice for suspected subdural hygroma due to its availability and speed in acute settings. On non-contrast , subdural hygroma appears as a crescentic, hypodense collection along the cerebral convexity, with attenuation values typically ranging from 0 to 20 Hounsfield units (HU), closely matching (CSF). This collection does not enhance following contrast administration and usually manifests 1 to 9 days post-traumatic event, with a mean appearance around 9 days. Magnetic resonance imaging (MRI) provides superior characterization of subdural hygroma, particularly in ambiguous cases. On MRI, the lesion is hypointense on T1-weighted sequences and hyperintense on T2-weighted sequences, with signal intensity matching CSF; it suppresses on fluid-attenuated inversion recovery (FLAIR) sequences, confirming its CSF-like composition. Post-gadolinium administration may reveal subtle enhancement of surrounding membranes, indicating neomembrane formation without parenchymal invasion. The cortical vein sign on MRI further confirms a true subdural location, where superficial cortical veins are displaced inward and do not traverse the collection, distinguishing it from subarachnoid space widening in atrophy. Advanced imaging techniques aid in excluding complications. Diffusion-weighted imaging (DWI) demonstrates no restricted diffusion in subdural hygroma, helping to rule out infectious processes like or , which show characteristic hyperintensity and low apparent diffusion coefficient values. MR venography is employed when cortical vein is suspected, revealing flow voids or filling defects in venous structures that may contribute to hygroma formation or progression. Serial imaging plays a crucial role in management by monitoring for spontaneous resolution, stability, or progression to chronic . Follow-up scans, typically performed at intervals based on clinical status, assess changes in size, density, and ; most hygromas resolve within weeks to months without intervention.

Subdural hygroma must be differentiated from several conditions that present with extracerebral fluid collections, particularly on , as clinical symptoms such as , altered mental status, or focal deficits can overlap. Key differentials include chronic , which appears hyperdense or mixed density on non-contrast due to products, in contrast to the hypodense, CSF-attenuating appearance of hygroma (typically 0-15 Hounsfield units); the two entities share a complex etiological relationship, with hygromas sometimes evolving from or coexisting with hematomas, but hygromas lack significant membranes or septations early on. presents with widened sulci and subarachnoid spaces without or , whereas hygroma exerts mild compressive effects on adjacent brain parenchyma. Arachnoid cysts, another mimic, are well-defined, intra-arachnoid collections with smooth margins and no communication with the unless ruptured, distinguishing them from the more diffuse, crescentic subdural distribution of hygromas; rupture of an can rarely lead to secondary hygroma formation, but primary cysts show homogeneous CSF signal without surrounding hemorrhage. In pediatric populations, benign enlargement of the subarachnoid space (BESS) mimics hygroma radiologically but lacks and is associated with normal development rather than or , often resolving spontaneously. Other important mimics include subdural empyema, which clinically suggests infection with fever and , and shows peripheral enhancement on contrast /MRI along with restricted diffusion on diffusion-weighted imaging, unlike the non-enhancing, free-flowing CSF-like fluid in hygroma. Tension appears as lucent gas collections compressing the brain (e.g., sign on ), typically post-surgical or traumatic, contrasting with the fluid density of hygroma and often accompanied by acute neurological deterioration due to elevated . Distinguishing features rely on imaging characteristics such as and signal (hygroma matches CSF on all sequences without blood products or proteinaceous content), enhancement patterns (absent in hygroma, present in or ), and clinical context, where a history of favors hygroma over congenital lesions like cysts. On MRI, the cortical vein sign is particularly useful: in , superficial cortical veins traverse the extracerebral spaces, while in hygroma, veins are displaced laterally against the inner table, confirming a true subdural collection. Diagnostic algorithms typically begin with non-contrast to identify hypodense crescentic collections over the convexities; if ambiguous, proceed to MRI for tissue characterization, ruling out via gradient-echo sequences for blood or via diffusion and contrast imaging. Flowcharts emphasize serial imaging to monitor evolution, with hygroma confirmed by stability or resolution without intervention, versus progression in or acute changes in / requiring urgent management.

Management

Conservative Approaches

Conservative management is the preferred initial approach for subdural hygromas that are asymptomatic or minimally symptomatic, focusing on close monitoring to allow for potential spontaneous resolution. Observation protocols generally involve serial imaging every 1-2 weeks to assess for changes in hygroma size, , or progression to , with clinical evaluations for neurological symptoms at each follow-up. This approach is particularly suitable for cases without significant or neurological deficits, as identified through prior clinical assessment. Supportive measures play a key role in optimizing conditions for resolution. If the patient is on anticoagulants or antiplatelet agents and there is evidence of risk for hemorrhagic transformation, discontinuation may be considered under medical supervision. Pharmacological interventions are reserved for specific complications or mild symptoms. Antiepileptic drugs, like or , are indicated only if seizures develop, as prophylactic use is not routinely recommended due to limited evidence of benefit in preventing post-traumatic seizures associated with hygromas. Studies on conservatively managed subdural collections report resolution rates around 66% within several months, particularly when hygromas are small and patients adhere to protocols. There are no formal clinical guidelines specific to subdural hygroma management; approaches are often guided by principles for related subdural collections, emphasizing symptom-based decisions.

Surgical Interventions

Surgical interventions are reserved for symptomatic subdural hygromas that cause , neurological deficits, or fail , typically involving evacuation of the collection to alleviate . The choice of procedure depends on the hygroma's size, location, loculation, and patient factors, with burr-hole serving as the initial standard approach for most accessible, non-loculated collections. Burr-hole drainage is the most common operative technique for symptomatic subdural hygromas, involving the creation of one or two small holes in the under local or general to access and aspirate the fluid, often with placement of a subdural catheter for continuous drainage over several days. This method is indicated for hygromas exceeding 7 mm in thickness with associated symptoms such as altered or seizures, achieving resolution in approximately 59% of pediatric cases and improving scores in adults with traumatic etiologies. with saline may be incorporated during the to clear and reduce reaccumulation risk, though it is not always necessary for simple hygromas. For loculated, thick, or recurrent hygromas where burr-hole access is inadequate, provides wider exposure to evacuate the collection, separate membranes, and perform to prevent fluid reaccumulation. This approach is particularly useful in post-decompressive craniectomy cases with hygromas causing , allowing simultaneous drainage and for structural restoration, leading to radiological resolution within 2-6 weeks and clinical improvement in reported cases. Shunting procedures, such as subdural-peritoneal or ventriculoperitoneal shunts, are employed for persistent or recurrent hygromas unresponsive to , diverting fluid to the via a with a to regulate flow. In adults, unvalved subdural-peritoneal shunts resolve collections in most cases within 14 days, while in pediatric patients with post-surgical hygromas, programmable shunts effectively clear bilateral collections and resolve symptoms like without long-term deficits. Complication rates for shunting include in approximately 5-33% of cases and obstruction or formation in select instances. Postoperative care following surgical intervention includes prophylactic antibiotics, such as cephalosporins, administered for 24 hours to prevent , particularly with drain placement. Patients are monitored closely for recurrence through serial computed tomography imaging, typically within the first week and at follow-up intervals, to assess fluid reaccumulation or complications like , with recurrence rates around 25% in traumatic cases requiring potential reintervention.

Prognosis

Short-Term Outcomes

Subdural hygromas, particularly small ones without significant mass effect, frequently undergo spontaneous absorption under conservative management, with an initial observation period of 2 to 4 weeks to assess for brain re-expansion and resolution without intervention. Larger or symptomatic hygromas may require drainage, with post-procedure imaging often demonstrating marked improvement in symptoms and hygroma volume within days. Success metrics for interventions such as burr-hole drainage include good clinical outcomes (Glasgow Outcome Scale 4-5) achieved in 73-94% of patients shortly after treatment. Early recurrence risk following ranges from 10% to 30%, with rates around 25-33% reported after burr-hole evacuation, often necessitating re-intervention in affected cases. This risk is influenced by underlying brain atrophy, which impairs re-expansion and promotes fluid re-accumulation. Factors affecting short-term success include patient age, with younger individuals (≤40 years) showing higher resolution rates (up to 65% good outcomes) compared to older patients (>40 years, around 55-57% good outcomes), as well as initial hygroma size and the presence of associated hemorrhage, which can complicate and increase recurrence likelihood. Overall, over 85% of traumatic subdural hygromas resolve spontaneously within three months, highlighting a generally favorable acute-phase when managed appropriately.

Long-Term Considerations

Subdural hygromas often resolve spontaneously over time, with many patients experiencing no lasting neurological deficits. In cases following mild , approximately 20.7% achieve complete resolution within three months, while 25.9% show a decrease in size and 7.2% remain stable, indicating a favorable trajectory for in or mildly symptomatic individuals. Overall remains good, as the presence of a subdural hygroma does not significantly alter long-term functional outcomes, such as those measured by the Glasgow Outcome Scale, compared to patients without hygromas. However, a notable long-term risk is progression to chronic , occurring in 5% to 58% of cases, with rates around 25% to 33% reported in traumatic settings; this conversion is more common in elderly patients over 60 years, potentially necessitating surgical intervention. Such progression can lead to prolonged symptoms like , , or , and in severe instances, contribute to increased . In post-decompressive craniectomy scenarios, subdural hygromas are associated with extended hospital stays—averaging 30 days longer—though they do not independently worsen mortality or overall recovery. Long-term neurological considerations include potential cognitive decline, with post-traumatic brain injury elevating risk by 1.5 to 3 times, particularly in older adults where brain atrophy may exacerbate persistence. For patients aged 70 and above, annual follow-up exceeding one year, incorporating cognitive assessments and imaging, is recommended to monitor for subtle sequelae like mild visual disturbances or . In pediatric cases, conservative approaches typically yield full recovery within one year, but early surgical intervention may benefit those with delayed consciousness improvement, reducing progression to in up to 60% of untreated instances.

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