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Epidural blood patch

An epidural blood patch (EBP) is a minimally invasive in which a small volume of a patient's own (autologous) blood is injected into the of the to seal a dural tear and stop the leakage of (CSF), most commonly to treat post-dural puncture (PDPH) following or epidural . This technique addresses the symptoms of intracranial caused by CSF loss, such as severe positional headaches that worsen when upright and improve when lying down. EBPs were first described in 1960 by American surgeon James B. Gormley, who reported successful relief of PDPH symptoms in two patients by injecting 2–3 mL of autologous blood through a spinal needle into the at the site of the original dural puncture. Since then, the procedure has become the gold standard for managing PDPH that persists despite conservative treatments like , , analgesics, and , particularly when symptoms last beyond 24–48 hours or impair daily function. Indications extend beyond iatrogenic PDPH to include spontaneous intracranial hypotension (SIH), CSF fistulas from trauma or surgery, and certain chronic headaches with a postural component. The procedure typically involves positioning the patient in a lateral decubitus or seated position, followed by sterile preparation and identification of the using a loss-of-resistance with a Tuohy or spinal needle, often at the level of the original puncture (usually L3–L4 or L4–L5). Approximately 15–20 mL of freshly drawn autologous blood is then slowly injected (over 30–60 seconds) into the until the patient experiences mild or fullness, after which they remain for 1–2 hours to allow clotting and sealing. For spontaneous intracranial hypotension (SIH), targeted EBPs, guided by or to the exact leak site, have shown higher success rates (up to 87%) compared to non-targeted "blind" approaches (around 56%). EBPs are generally safe and effective, with immediate or rapid symptom relief in about 85% of cases for PDPH, and up to 90% success after a repeat patch if the first fails (failure rate 15–20%). Common side effects include transient backache (incidence ~80%, resolving within 4 weeks), during injection, or mild fever, while rare complications encompass , , or rebound intracranial . Contraindications include active , local , , or patient refusal. Ongoing research explores optimal timing, volume, prophylactic use in high-risk cases, and alternative injectates like for refractory leaks. As of 2025, consensus guidelines from the confirm EBP as the gold standard for PDPH, with initial success rates of 70–90%.

Indications and Uses

Post-dural puncture headache

Post-dural puncture headache (PDPH) is defined as a that develops within 5 days following a dural puncture procedure, caused by (CSF) leakage through the puncture site, leading to reduced . According to the , third edition (ICHD-3), diagnostic criteria require: A. dural puncture has been performed; B. has developed within 5 days of the dural puncture; C. has at least two of the following characteristics: (1) postural nature (worsens within 15 min after sitting or standing, improves within 30 min after lying flat); (2) accompanied by ; (3) accompanied by ; (4) accompanied by hypacusia; (5) accompanied by and/or ; D. not better accounted for by another ICHD-3 diagnosis. The hallmark symptom of PDPH is a severe positional , typically frontal or occipital, that intensifies within minutes of assuming an upright posture and resolves or improves promptly upon lying . Accompanying features often include , , , , , and auditory disturbances such as hypacusia. Symptoms usually emerge 24 to 48 hours after the procedure, though they can appear as early as immediately or as late as 5 days post-puncture. PDPH occurs in approximately 50% (up to 80% in obstetric cases) of cases following unintentional dural puncture during epidural placement, with the overall risk of such puncture estimated at 1% to 1.5% in obstetric epidural procedures. The incidence of PDPH is notably higher in pregnant women, affecting 76% to 85% of those experiencing dural puncture, attributed to factors including elevated levels, increased intra-abdominal pressure, and potential . The epidural blood patch serves as the primary definitive treatment for PDPH when conservative measures—such as , , , and analgesics—fail to provide relief after 24 to 48 hours of symptom onset. It is particularly indicated for severe, cases that significantly impair daily function or persist beyond initial conservative .

Spontaneous intracranial hypotension

Spontaneous intracranial hypotension (SIH) is defined as a condition characterized by resulting from a spontaneous (CSF) leak, typically due to dural tears or underlying connective tissue disorders such as Ehlers-Danlos syndrome. Unlike iatrogenic causes, these leaks often arise without trauma or procedure, leading to reduced CSF volume and . The incidence of SIH is rare, estimated at 5 per 100,000 persons annually, and it predominantly affects women aged 30 to 50 years. Symptoms typically include an that worsens in the upright position and improves when lying down, often with an insidious onset that can delay recognition; additional manifestations may involve , , or . Imaging may reveal complications such as subdural hematomas or hygromas, contributing to diagnostic complexity. Diagnosis relies on clinical features corroborated by imaging and lumbar puncture findings, including MRI with gadolinium contrast that demonstrates diffuse pachymeningeal enhancement and brain sagging, alongside low CSF opening pressure below 6 cm H₂O. If initial conservative management—such as bed rest, hydration, and caffeine—fails, the epidural blood patch (EBP) serves as the first-line interventional therapy for SIH. Targeted EBP, guided by leak localization through CT myelography, enhances efficacy by delivering autologous blood directly to the site of CSF leakage. Approximately 35-60% of SIH cases may necessitate multiple EBPs for symptom control, with long-term resolution achieved in 70-90% of patients following appropriate intervention. This approach addresses the diagnostic challenges of occult leaks, improving outcomes in this underrecognized disorder.

Other applications

Epidural blood patches (EBPs) have been applied to treat (CSF) leaks resulting from trauma, such as or spinal incidents, where conservative measures fail to resolve persistent leakage and associated symptoms like or neurological deficits. In these cases, EBP serves as an interventional option to seal the dural defect and restore CSF pressure, with reports indicating symptom relief in select patients through targeted injection at the leak site. For post-surgical CSF leaks, particularly following spine surgery or procedures involving dural , EBPs offer a minimally invasive alternative to surgical repair, demonstrating cessation of leakage in small cohorts without additional complications. Success in these applications relies on imaging-guided placement to address the specific leak location, often using volumes of 10-20 mL of autologous blood to achieve and pressure equalization. In pediatric patients with post-dural puncture headache (PDPH) or related CSF leaks, EBPs are adapted with reduced blood volumes, typically 0.2-0.3 mL/kg body weight (e.g., 4-6 mL for a 20-30 kg ), and the procedure is often performed under or general to ensure safety and cooperation, effectively alleviating symptoms refractory to conservative treatments like and . Case series and reports highlight high efficacy in children, with rapid resolution of headaches lasting weeks, though the procedure requires careful dosing to account for smaller and lower CSF volumes. EBPs have been explored in rare instances for chronic subdural hematoma associated with CSF hypotension, where the patch not only seals underlying leaks but also facilitates hematoma resolution by normalizing dynamics. Evidence from case reports shows neurological improvement post-EBP, particularly when combined with to confirm leak , though it is not a standard first-line therapy. Emerging applications include CSF-venous fistulas, identifiable via dynamic or myelography, where EBPs provide transient symptom relief by compressing fistulous connections, but often require adjunctive interventions like due to limited long-term sealing efficacy. These uses are supported primarily by case series rather than large trials, underscoring EBPs' role as a bridge therapy in complex, non-headache-dominant CSF disorders. Targeted approaches, such as caudal or transforaminal EBPs, enhance precision for leaks in challenging locations like the sacral or foraminal regions, allowing direct blood deposition via alternative epidural access points when lumbar interlaminar injection is impractical. Overall, while effective in niche scenarios, these applications remain investigational, with outcomes varying based on leak anatomy and supported mainly by observational data from small patient groups.

Procedure

Relevant anatomy

The is a within the vertebral canal, located between the and the ligamentum flavum posteriorly, extending from the to the sacral hiatus. It contains loose areolar , including epidural fat, , lymphatics, and spinal nerve roots as they traverse to the intervertebral foramina. The dimensions of the increase caudally along the spine, measuring approximately 1–1.5 mm in depth at the level, 2.5–3 mm at T6, and 5–6 mm at L2, with variations influenced by individual anatomy and body habitus. The forms the outermost meningeal layer in the , consisting of a tough, fibrous that encloses the and (CSF) within the subarachnoid space. In the spinal region, unlike the cranial dura, it comprises a single layer of dense and fibers, providing a protective barrier around the and nerve roots. Punctures of the dura, often occurring at lumbar levels such as L3–L4 or L4–L5 during procedures like spinal anesthesia, can lead to CSF leakage into surrounding tissues. For epidural procedures, a approach is typically preferred to minimize risks associated with higher spinal levels, as the usually terminates above in adults, reducing the chance of direct . Key anatomical landmarks include the spinous processes and interspinous ligaments, which guide midline needle insertion between L2–L3, L3–L4, or L4–L5 interspaces. The proximity of the to the subarachnoid space varies from 1 to 5 mm, depending on the anteroposterior distance between the ligamentum flavum and the dura, which can be as narrow as 1 mm ventrally and up to 2–3 mm dorsally in the region. The amount of epidural fat within this space varies with age, body weight, and obesity, generally increasing with higher body mass index and potentially leading to greater needle resistance or false loss-of-resistance sensations during identification of the space. In obese individuals, expanded epidural fat can alter the space's compliance and compress the dural sac, though it does not uniformly correlate with all body composition metrics.

Preparation and insertion

The epidural blood patch procedure is typically performed by anesthesiologists or interventional radiologists in a controlled setting such as an operating room or interventional suite. Patient preparation begins with obtaining and establishing intravenous access for monitoring and hydration. The patient is positioned in the lateral decubitus or sitting position, with the former preferred to minimize symptom exacerbation; the back is then prepped and draped using strict aseptic technique, including chlorhexidine-alcohol or application. Autologous blood is drawn sterilely by an assistant using an 18- or 20-gauge angiocatheter from the antecubital vein, typically 15-20 mL, though volumes up to 30 mL may be collected depending on patient tolerance and procedural needs. A 16- to 18-gauge Tuohy needle is then advanced into the epidural space at the site of the prior dural puncture or one level below, using the loss-of-resistance technique with saline or air to confirm entry; optional fluoroscopic or guidance may be employed for precise localization. Once the epidural space is accessed, the autologous blood is injected slowly at a rate of approximately 0.5 mL per second, incrementally up to 15-20 mL standard volume, or until the patient experiences resistance or back fullness, at which point injection ceases to avoid complications. The needle is removed, and the patient is instructed to lie flat in a for 1-2 hours post-procedure to facilitate blood spread and clotting. Variations include blind lumbar interlaminar injection for standard cases versus targeted approaches, such as CT- or fluoroscopy-guided placement at the identified cerebrospinal fluid leak site, which may use smaller volumes (e.g., 5 mL for transforaminal) and is reserved for complex or refractory leaks. Relief from symptoms, such as headache, is often immediate in approximately 50% of cases following the procedure.

Mechanism of action

The primary mechanism of the epidural blood patch involves the injection of autologous blood into the , where it coagulates to form a fibrin clot that adheres to the and seals the dural defect responsible for (CSF) leakage. This clotting process is mediated by platelets, which aggregate at the site to initiate , and fibrinogen, which is converted to to create a stable plug that halts CSF egress. The resulting clot typically spans approximately 4-5 intervertebral levels, extending rostrally from the injection site to cover the leak effectively. In addition to sealing the defect, the injected blood exerts a mass effect that compresses the dural sac, thereby increasing intrathecal CSF pressure and providing an immediate effect against further leakage. This compression modulates gradients by reducing compliance and limiting CSF redistribution from cranial to spinal compartments during postural changes, which alleviates symptoms such as . The volume of blood (typically 15-20 ) generates epidural pressure sufficient to displace CSF cephalad, contributing to rapid symptom relief within minutes to hours. Over time, the blood patch triggers a secondary inflammatory response that promotes dural through and deposition, leading to a more permanent seal. activity becomes widespread around 7 days post-injection, supporting tissue repair at the defect site. The initial provides immediate relief, with full clot maturation and sealing occurring within 24-48 hours, while the clot resolves within 7-13 hours, allowing natural to take precedence.

Clinical Considerations

Contraindications

Absolute contraindications to epidural blood patch (EBP) include conditions that pose an unacceptable risk of serious complications, such as , local or systemic infection, and patient refusal. , particularly when the international normalized ratio (INR) exceeds 1.5 or platelet count falls below 50,000/μL, is prohibited due to the heightened risk of formation during needle insertion or blood injection. Local infection at the puncture site or systemic infections like bacteremia, septicemia, or are also absolute contraindications, as the procedure could exacerbate infection spread into the . Febrile illness is similarly contraindicated to avoid introducing pathogens into the . Patient refusal or inability to cooperate renders the procedure unethical and unsafe. Relative contraindications encompass factors that increase procedural risks but may allow EBP in select cases with careful risk-benefit assessment, including fever, spinal deformities such as , at the injection site, immunosuppression (e.g., from or ), and recent anticoagulation use. These conditions warrant heightened caution; for instance, gross anatomic deformities or significant may complicate needle placement and increase the chance of unintended dural puncture. In immunosuppressed patients, the risk of is elevated, though EBP has been performed successfully in some cases of hematological when absolute criteria are absent. Recent anticoagulation requires reversal or sufficient washout period to mitigate risks. EBP should be avoided in septic patients to prevent potential spread of infection to the epidural or intrathecal spaces. If undiagnosed (CSF) infection is suspected, a diagnostic may be necessary prior to considering EBP to rule out contraindications. Pre-procedure evaluation is essential for selection and includes laboratory assessments such as a (CBC) to check platelet levels and a coagulation panel (including prothrombin time/INR and ) to identify . Imaging, such as (MRI) or computed tomography (CT), should be reviewed to detect spinal anomalies, degenerative changes, or that could influence procedural feasibility.

Risks and complications

The epidural blood patch (EBP) procedure, while generally safe, carries several potential risks and complications, ranging from common transient effects to rare serious adverse events. The most frequent complications include transient at the injection site, occurring in approximately 80% of cases and typically resolving within four weeks without intervention. Leg or radicular irritation due to blood by-products is also common, often mild and self-limited, alongside occasional mild exacerbation of or . These effects are usually managed conservatively with and analgesics, and patients are advised to monitor symptoms for resolution over days to weeks. Rarer complications, affecting less than 1% of patients, encompass infections such as or , which necessitate prompt therapy and urgent evaluation if signs like fever, , or purulence emerge. , , and are exceptionally uncommon, with documented in fewer than a dozen historical cases, presenting with symptoms like severe pain and lower limb dysesthesias that may require and supportive for potential . Allergic reactions to the autologous blood used in EBP are virtually nonexistent due to its origin from the patient. Rebound intracranial hypertension, characterized by elevated cerebrospinal fluid pressure post-procedure, occurs in 7% to 27% of cases and may manifest as positional headaches, , or visual disturbances, typically within 48 hours. Management involves medications like or topiramate, with for drainage providing immediate relief in symptomatic patients; repeat is recommended for persistent or worsening symptoms to out ongoing issues like . Overall, while serious events are infrequent, close post-procedure monitoring is essential to mitigate risks.

Effectiveness and Evidence

Success rates

The epidural blood patch (EBP) demonstrates high efficacy in treating leaks, with success rates varying by condition and procedural details. For post-dural puncture (PDPH), immediate relief following the first EBP occurs in 50-80% of cases, based on data from randomized controlled trials (RCTs) and observational studies. With repeat procedures, cumulative success reaches up to 98%. For spontaneous intracranial (SIH), initial success rates range from 70% to 90%, as reported in cohort studies and meta-analyses. Recent meta-analyses (2021-2023) highlight procedural influences on outcomes, showing a 77% success rate with blood volumes exceeding 20 mL compared to 66% with smaller volumes. Targeted EBPs, guided by to the leak site, achieve % success versus 56% for blind techniques. Long-term efficacy is also robust, with approximately 85% of patients experiencing sustained relief at one year post-procedure, and around 20% requiring a second EBP for initial non-response. These findings derive from RCTs, prospective cohorts, and large observational datasets, establishing EBP as the gold standard intervention per (ASA) guidelines.

Factors influencing outcomes

Several factors have been identified that influence the success of epidural blood patch (EBP) in treating spontaneous intracranial (SIH) and post-dural puncture (PDPH), including procedural timing, injected, placement technique, and characteristics of the (CSF) leak. Delayed administration of EBP more than 48 hours after symptom onset is associated with improved outcomes compared to early intervention, as it allows for better localization of the leak and reduced inflammation at the site. Larger volumes of autologous blood, particularly exceeding 22.5 mL, correlate with higher success rates by enabling greater spread and tamponade effect over the leak site, with one study reporting a 3.8-fold increase in response when combined with limited anterior epidural CSF collection. Targeted EBP, guided by imaging to the precise leak location, yields success rates of approximately 87% on the first attempt, outperforming blind techniques. Conversely, early EBP administration within 48 hours, smaller injected volumes, and blind placement are negative predictors of success, often leading to incomplete symptom relief or the need for repeat procedures. In SIH cases with multiple leaks identified on , repeat EBP rates range from 17% to 28%, as diffuse leakage complicates complete sealing. Leak multiplicity on preoperative further predicts poorer initial response, necessitating multilevel or repeated interventions. A 2025 systematic review and meta-analysis comparing targeted versus non-targeted EBP in SIH found an odds ratio (OR) of 2.55 (95% CI: 0.66–9.79) for early symptom relief favoring targeted approaches, though the difference was not statistically significant (p=0.2), highlighting the role of precise placement in potentially enhancing efficacy despite high study heterogeneity.

Alternatives to Epidural Blood Patch

Conservative management

Conservative management serves as the initial, non-invasive approach to treating post-dural puncture headache (PDPH) caused by (CSF) leaks, aiming to alleviate symptoms and promote spontaneous resolution before considering more advanced interventions. This strategy is recommended as first-line therapy due to its low risk and potential for symptom relief in a significant proportion of cases. Key non-pharmacologic measures include bed rest for 24 to 48 hours to minimize CSF leakage by reducing changes, oral or intravenous hydration targeting 2 to 3 liters per day to maintain intravascular volume and support CSF production, and analgesics such as acetaminophen or nonsteroidal drugs (NSAIDs) to manage pain. These supportive therapies are routinely initiated upon PDPH and can lead to symptom improvement in many patients without additional . Pharmacologic options target cerebral vasoconstriction and pain modulation. Caffeine, administered as 300 to 500 mg intravenously or orally once or twice daily, acts as an adenosine antagonist to constrict cerebral vessels and has demonstrated significant headache relief compared to placebo in randomized trials, with low-certainty evidence supporting its use for transient symptom reduction. Theophylline, a similar methylxanthine, provides better pain relief than placebo or conventional analgesics alone, as shown in systematic reviews. For cases with neuropathic pain components, gabapentin at doses of 300 to 400 mg three times daily has been effective in reducing headache severity, outperforming placebo in some clinical studies; however, recent guidelines (as of 2025) advise against routine use due to limited evidence. High-flow oxygen therapy at 12 liters per minute via a non-rebreather mask, often combined with metoclopramide, offers acute relief by inducing cerebral vasoconstriction, with case series reporting symptom reduction in treated patients. These measures are typically trialed for 24 to 72 hours, during which approximately 50% of mild PDPH cases resolve spontaneously, and up to 75% improve within the first week with supportive care alone. Failure to achieve adequate relief prompts reassessment and potential escalation of therapy.

Interventional options

When conservative measures fail or epidural blood patch (EBP) is contraindicated, such as in cases of , several interventional alternatives exist for managing post-dural puncture headache (PDPH) or (CSF) leaks. These options aim to provide relief or seal the leak with varying degrees of invasiveness and efficacy, though they are generally considered adjunctive rather than first-line per clinical guidelines, with recent (as of August 2025) advising against routine use of many due to low-certainty . The sphenopalatine () block is a involving topical or transnasal application of local to the sphenopalatine , offering rapid relief for PDPH by modulating autonomic pathways. Small studies and case series report pain relief in 70-90% of patients with quicker short-term onset compared to EBP, and one 2024 institutional series suggested avoidance of EBP in about 67% of postpartum cases; however, a 2023 found no long-term superiority over , and recent guidelines (as of 2025) advise against routine use due to low-certainty . It is especially useful as a bridge therapy when EBP is delayed or contraindicated. Intravenous (IV) cosyntropin, a synthetic (ACTH) analog, promotes CSF production to counteract and has shown response rates of around 80% in small randomized trials for PDPH treatment, with long-term efficacy (at days 3 and 7) comparable to EBP, though initial relief may be slower; overall success is lower than EBP's typical 75% rate, and recent guidelines (as of 2025) advise against routine use due to limited evidence, making it a potential option in where invasive procedures pose bleeding risks. For persistent CSF leaks, an epidural fibrin glue patch serves as an alternative sealant, particularly in patients suitable for image-guided intervention. Small series demonstrate success with 3-5 mL of injected epidurally, providing durable closure in cases without the need for autologous blood, though guidelines recommend it only for cases or when EBP is contraindicated. In severe, refractory leaks, surgical dural repair offers definitive treatment through direct suturing or grafting, achieving success rates of approximately 90% but with higher morbidity, including and longer recovery compared to less invasive options like EBP.

History and Development

Origins

The epidural blood patch (EBP) emerged as a response to the increasing prevalence of post-dural puncture headache (PDPH), a common complication of spinal and epidural , which saw rising use in and following amid the postwar and advancements in regional techniques. During this period, the demand for effective pain relief in labor grew, but PDPH often prolonged recovery and caused significant patient discomfort, prompting innovative treatments to seal dural leaks caused by needle punctures. The procedure was first described in 1960 by surgeon James B. Gormley, who reported injecting 2-3 mL of autologous into the to treat PDPH in seven patients, including himself after a myelogram, achieving immediate and lasting relief. Gormley's approach was inspired by clinical observations that "bloody taps"—accidental injection of during dural puncture—were associated with fewer subsequent headaches, suggesting that could coagulate and seal the leak. Independently in the same year, Turkish-American anesthesiologist Turan Ozdil developed a similar concept for PDPH treatment and prevention, initially testing it on dogs to confirm rapid dural sealing before applying it prophylactically in humans. Early adoption in the involved small case series, with Ozdil and collaborator W. Forrest Powell reporting no PDPH in 100 prophylactic cases compared to a 15% incidence in controls, though the transdural injection method proved impractical for routine use. These initial reports established the foundational principle of using autologous blood to promote and dural repair. By , anesthesiologist Anthony J. DiGiovanni refined the technique into a standardized epidural approach, injecting 10-15 mL of blood to achieve broader coverage for unknown leak sites, as detailed in a series of 37 patients with high rates. DiGiovanni's work, conducted at Wilford Hall USAF Center, facilitated wider training and acceptance of EBP by the 1970s, particularly in obstetric settings where epidural was increasingly common.

Key advancements

The introduction of image guidance, such as and , for epidural blood patch (EBP) procedures in the 1980s marked a significant by improving targeting accuracy over landmark-based techniques, enhancing the to seal dural tears more precisely, particularly on the ventral . This shift from blind to image-guided approaches substantially increased success rates, with targeted EBPs achieving 87% treatment success compared to 56% for blind EBPs in cases of spontaneous intracranial hypotension. Studies in the late , building on early work, optimized for EBPs, establishing 20 mL as the standard for adult interlaminar approaches to maximize while minimizing risks like side effects from larger volumes. This evidence-based refinement evolved the procedure from empirical application to a more standardized intervention, with injections typically halted if patient discomfort or resistance occurs before reaching the full volume. Recent meta-analyses, including one published in 2025, have evaluated targeted versus non-targeted EBPs, showing marginal trends toward higher early symptom relief ( 2.551) and overall positive outcomes ( 1.681) with targeted approaches, though differences were not statistically significant due to heterogeneity in studies. In 2024, research identified key predictors of EBP failure, such as administration within 48 hours of symptom onset ( 3.689 for failure) and shallower depth, informing better patient selection and timing. Long-term outcome studies from the same year demonstrated sustained benefits, with 54% of patients achieving clinically meaningful improvements in physical and 45% in severity over an average of 521 days post-EBP, particularly among those with positional pain relief pre-treatment. Pediatric protocols have also advanced, recommending 0.2–0.3 / of autologous under or general anesthesia, performed at the puncture site or one level below, with patients kept for at least 2 hours afterward to optimize spread and relief. Guidelines from the in discuss alternatives like sphenopalatine blocks for post-dural puncture , though evidence remains insufficient for routine recommendation alongside EBPs.