Fact-checked by Grok 2 weeks ago

Brain biopsy

A brain biopsy is a surgical procedure in which a small sample of is removed from the for laboratory analysis, typically to diagnose tumors, infections, or other neurological disorders by examining cells under a . This procedure is essential when imaging tests like MRI or scans cannot definitively identify the nature of an abnormality, providing critical information on whether a is cancerous, its grade, and appropriate treatment options. Brain biopsies are commonly performed in two main ways: stereotactic needle biopsy, a minimally invasive technique using computer-guided imaging to insert a thin needle through a small hole in the , or open biopsy during a , where a larger section of the is temporarily removed to access the tissue. The stereotactic method is preferred for deep or hard-to-reach lesions to minimize damage to surrounding healthy brain tissue, often conducted under with or general . The procedure typically lasts 30 minutes to two hours, depending on the approach and location of the target area, and is guided by preoperative scans for precision. While biopsies offer high diagnostic accuracy, often exceeding 90% in identifying tumor types, they carry risks including , , seizures, and potential neurological deficits such as weakness, speech impairment, or memory loss due to proximity to vital structures. Benefits include enabling targeted therapies like or , avoiding unnecessary treatments for benign conditions, and improving through early, precise , particularly for conditions like gliomas or where non-invasive tests are inconclusive. Advances in and stereotaxy have reduced complication rates to under 5% for severe events in experienced centers.

Overview

Definition and Purpose

A brain biopsy is a surgical procedure involving the removal of a small sample of brain tissue for microscopic examination to identify abnormalities such as tumors, infections, or degenerative diseases. This diagnostic approach allows pathologists to analyze cellular and structural features that cannot be fully assessed through non-invasive methods alone. The primary purpose of a brain biopsy is to confirm diagnoses in cases where imaging techniques like MRI or scans provide inconclusive results, enabling precise identification of the underlying . It guides decisions by providing definitive information on the nature of the lesion, such as distinguishing primary brain tumors from metastatic ones originating elsewhere in the body. Additionally, the tissue sample undergoes pathological analysis to determine specific characteristics, including tumor grade or infectious agents, which directly influences therapeutic strategies. In terms of basic , brain biopsies target specific regions such as the , which contains neuronal cell bodies, or the , comprising myelinated axons, depending on the suspected location to ensure representative sampling. For neoplastic lesions, the demonstrates a high diagnostic yield, typically 90-95%, making it a reliable for establishing a definitive in most cases.

Historical Development

The origins of brain biopsy trace back to the late 19th century, when surgical interventions for suspected intracranial tumors began to incorporate tissue sampling for pathological examination. In 1879, Scottish surgeon William Macewen performed the first documented successful resection of a brain tumor—a meningioma in a young patient—relying on clinical localization and antisepsis principles; the removed tissue was examined to confirm the diagnosis, marking an early milestone in diagnostic neurosurgery. This approach, though invasive via open craniotomy, laid the groundwork for biopsy as a means to differentiate tumors from other lesions, with survival outcomes improving due to better postoperative care. In the early 20th century, Harvey Cushing, often regarded as the father of modern neurosurgery, significantly advanced brain biopsy practices through his systematic surgical treatment of brain tumors at Johns Hopkins Hospital starting in 1901. Cushing conducted over 2,000 brain tumor operations, meticulously collecting and classifying specimens for histopathological analysis, which enabled precise tumor typing and influenced global standards for diagnostic accuracy. His emphasis on minimizing blood loss and maximizing exposure during open procedures reduced operative mortality from around 40% to under 10% by the 1920s, establishing biopsy-resection hybrids as routine for tumor diagnosis. Mid-20th-century innovations introduced stereotaxy, transforming biopsy from to targeted intervention. In 1947, Ernest A. Spiegel and Henry T. Wycis developed the first human-applicable stereotactic apparatus, a three-dimensional frame system that allowed precise needle access to deep structures without extensive exposure, initially for functional procedures but quickly adapted for biopsies. This built on the 1908 animal frame by Victor Horsley and Robert Clarke, enabling safer sampling of inaccessible lesions. By the 1970s, the advent of computed tomography (CT) scanning facilitated the widespread adoption of needle-based stereotactic biopsies, improving localization accuracy to millimeters and reducing the need for open surgery. The modern era began in the 1980s with the integration of (MRI) into stereotactic systems, enhancing soft-tissue contrast for superior target visualization and further minimizing invasiveness. This shift allowed biopsies of eloquent or deep-seated lesions with diagnostic yields exceeding 90% and complication rates below 5%. In the , frameless stereotaxy emerged as a pivotal advancement, utilizing optical or electromagnetic without rigid head frames, offering greater comfort and procedural flexibility while maintaining submillimeter precision comparable to frame-based methods. These developments have solidified image-guided as the gold standard, prioritizing safety and efficacy in contemporary .

Clinical Indications

Common Conditions Requiring Biopsy

Brain biopsy is primarily indicated for suspected primary tumors, such as gliomas, where alone cannot definitively distinguish between tumor types or confirm , guiding decisions like surgical resection or . Similarly, in cases of metastases from systemic cancers, addresses diagnostic uncertainty when imaging features overlap with other lesions, particularly in patients without a known . These procedures are essential when advanced imaging modalities, including MRI and , fail to provide conclusive histopathological evidence. In immunocompromised patients, such as those with , brain biopsy is crucial for diagnosing infectious etiologies including cerebral abscesses, , and (PML), where opportunistic infections present as mass lesions mimicking tumors on imaging. For PML specifically, biopsy confirms JC virus infection through histopathological demonstration of demyelination and viral inclusions, especially when analysis is inconclusive. This approach yields high diagnostic accuracy in AIDS-related intracranial masses, often identifying treatable infections that alter management. For non-neoplastic conditions, brain biopsy aids in evaluating unexplained inflammatory processes, such as suspected primary angiitis of the or atypical presentations resembling , where tissue analysis differentiates inflammatory from demyelinating pathology. In dementia workups, it is indicated for rapidly progressive cases to confirm or exclude prion diseases like Creutzfeldt-Jakob disease (CJD), revealing spongiform changes or alternative diagnoses such as . Biopsy in these scenarios identifies inflammatory or degenerative etiologies in up to 57% of undiagnosed cases. Brain biopsies are more commonly performed in adults over 40 years old, reflecting the higher incidence of both neoplastic and degenerative neurological diseases in this demographic. For non-tumor neurological diseases, the diagnostic yield of brain biopsy approximates 50-62%, with repeat procedures increasing success rates by identifying conditions like or that inform targeted therapies.

Diagnostic Role and Necessity

Brain biopsy serves a critical diagnostic role when non-invasive methods, such as blood tests, (EEG), or like (MRI), fail to provide sufficient specificity for confirming in suspected brain lesions. It is typically indicated as a of last resort following an exhaustive non-invasive , particularly in cases of unexplained neurological decline or ambiguous imaging findings that suggest but do not definitively identify conditions like tumors or inflammatory processes. A key necessity arises in the molecular subtyping of brain tumors, where biopsy-obtained tissue enables precise genetic profiling, such as detection of (IDH) mutations in gliomas, which are essential for accurate classification and prognostic assessment under frameworks like the guidelines. This subtyping distinguishes between IDH-mutant and wild-type tumors, influencing survival predictions and therapeutic eligibility. In clinical , brain directly guides treatment decisions by confirming diagnoses that inform targeted therapies, including regimens, radiation protocols, or surgical interventions, and facilitates through genomic analysis that identifies actionable mutations. For instance, IDH mutation status can determine responsiveness to specific inhibitors, thereby optimizing patient outcomes and avoiding ineffective treatments. Studies indicate that results lead to management changes, such as shifts in therapeutic approach, in a majority of cases. Alternatives like advanced imaging often fall short, with clinico-radiological diagnostic error rates of 15–27% for malignant tumors, necessitating to achieve a definitive and avoid misclassification. In palliative settings, ethical considerations emphasize balancing the procedure's diagnostic yield—potentially improving through informed decisions—against risks like hemorrhage or neurological deficits, ensuring interventions align with patient and beneficence principles.

Types of Brain Biopsies

Stereotactic Biopsy

Stereotactic biopsy is a minimally invasive neurosurgical technique that employs computer-assisted stereotactic navigation to obtain tissue samples from lesions using a needle probe guided by three-dimensional coordinates derived from preoperative imaging, such as MRI or scans. This method allows precise targeting of abnormalities, including deep-seated tumors or lesions inaccessible via open surgery, by calculating trajectories that minimize disruption to surrounding healthy tissue. The procedure typically involves creating a small burr hole in the through which the biopsy instrument is advanced along a predetermined path to extract cylindrical or core samples for histopathological analysis. Frame-based stereotactic relies on a rigid external head affixed to the patient's skull under , providing a fixed coordinate for accurate localization; the Leksell stereotactic frame, developed by Lars Leksell in the 1940s and refined over decades, exemplifies this approach with its arc-based that arcs the probe along calculated angles for submillimeter precision. In contrast, frameless stereotactic utilizes image-guided navigation integrated with optical or electromagnetic tracking, eliminating the need for a physical by registering patient anatomy to real-time imaging data via fiducial markers or surface scanning, which enhances patient comfort and setup flexibility without compromising accuracy. Comparative studies indicate that both techniques yield similar diagnostic success rates exceeding 90%, though frameless methods may reduce setup time and procedural discomfort. The primary advantages of stereotactic biopsy include its suitability for sampling deep or eloquent brain regions, such as the or , where open procedures pose higher risks, and its potential for outpatient performance in select patients, enabling same-day discharge with monitoring. Complication rates are low, typically ranging from 2% to 5% for symptomatic events like hemorrhage or neurological deficits, significantly lower than open biopsy due to the reduced tissue and smaller incision size. This minimizes morbidity and supports rapid histopathological , often within hours, facilitating timely planning. Key equipment includes stereotactic frames like the Leksell system, which features a metal ring secured by pins to the skull and adjustable arcs for trajectory alignment, often compatible with multimodal imaging for enhanced targeting. Biopsy needles vary by design: side-cutting needles, featuring an inner cannula that rotates or advances through a lateral window to shear tissue (typically 2-3 mm in diameter with a 10 mm cutting window), provide consistent core samples but may cause compression artifacts; alternatively, cup forceps (e.g., 2 mm diameter) grasp tissue via a biting mechanism for larger or irregular fragments, though they require more passes in some cases. These instruments are advanced through a introducer sheath to the lesion, with sampling performed under stereotactic guidance to ensure representativeness.

Open Craniotomy Biopsy

The open craniotomy biopsy is a traditional neurosurgical procedure that provides direct surgical access to tissue for diagnostic sampling. It begins with a incision over the targeted area, followed by the creation of burr holes using a high-speed or craniotome to outline and remove a flap, exposing the underlying . The dura is then incised and reflected to allow visualization of the surface, where abnormal —such as a suspected tumor—is identified and excised using precise instruments under microscopic or magnification. The sample is typically sent for immediate frozen section analysis to guide further intraoperative decisions, after which is achieved, the dura is closed, and the flap is securely replaced and fixed with plates or screws before skin closure. This approach is particularly indicated for superficial or peripherally located lesions, such as cortical tumors or meningiomas, where direct access is feasible without traversing deep eloquent brain structures. It is also preferred when a larger sample is required for comprehensive histopathological, molecular, or genetic analysis, or in cases necessitating intraoperative frozen section to assess margins during potential tumor resection. Unlike minimally invasive alternatives, open craniotomy biopsy is suitable for lesions in non-eloquent areas or when bleeding risk precludes needle-based methods, ensuring a higher volume of viable for . Key advantages include the ability to obtain substantial under direct visualization, facilitating real-time pathological evaluation and reducing , with diagnostic yields often exceeding 95% for accessible lesions. However, it carries disadvantages such as greater invasiveness compared to stereotactic techniques, leading to longer operative times (typically 2-4 hours) and extended recovery (3-7 days). Complications are more frequent, including a postoperative risk of approximately 2.2% for and up to 5% for surgical site infections overall, alongside hemorrhage (1-4%), seizures, and cerebrospinal fluid leaks. Essential surgical tools for the procedure include the craniotome or Hudson brace with perforator for bone flap creation, Gigli wire saw or high-speed drill for connecting burr holes, bipolar cautery for precise and of vessels, and devices to maintain a clear operative field. Additional instruments such as Penfield dissectors for retraction and scalp retractors ensure safe tissue handling and exposure. Neuronavigation systems may be integrated to enhance accuracy, though the method relies primarily on direct surgical exposure.

Preoperative Preparation

Patient Assessment and Evaluation

Patient assessment and evaluation prior to a brain biopsy involves a thorough review of the individual's to identify relevant comorbidities that could influence procedural risks, such as , , or a of seizures. This includes documenting current medications, including anticoagulants or antiepileptics, and obtaining collateral history from family members if the patient's consciousness is impaired. Neurological baseline is established through comprehensive examinations assessing level of consciousness using scales like the Glasgow Coma Scale, motor and sensory function, cranial nerve integrity, and overall cognitive status to guide postoperative comparisons. Comorbidities such as hypertension, diabetes, or respiratory issues like obstructive sleep apnea are optimized to minimize perioperative complications. Laboratory testing is essential to evaluate hemostatic function and overall health suitability for . Coagulation profiles, including (PT) and international normalized ratio (INR), are routinely obtained to detect risks, particularly in patients on therapy, with any abnormalities corrected preoperatively. A assesses for or that might necessitate transfusion, targeting a of 30-33% for optimal oxygen delivery during the procedure. screening, including counts and relevant serologies, helps identify potential sources of perioperative . Additional tests such as electrolytes, renal function, and glucose levels are performed to address metabolic imbalances. Informed consent is a critical component, where the neurosurgeon discusses the procedure's goals, such as obtaining tissue for histopathological diagnosis, alternative diagnostic options like advanced imaging, and patient-specific risks including neurological deficits or bleeding. This conversation ensures the patient or legal surrogate understands the potential benefits and limitations, with documentation of capacity assessment especially important in those with altered mental status. Consent forms are signed after addressing questions, typically during a preoperative clinic visit. Multidisciplinary input is integral for appropriate case selection and optimization, involving neurologists to evaluate seizure control and baseline deficits, oncologists for suspected neoplastic lesions, and hematologists for managing coagulopathies. This collaborative approach, often including anesthesiologists for risk stratification using tools like the classification, ensures comprehensive preoperative planning tailored to the patient's condition.

Imaging and Planning

Preoperative imaging plays a pivotal role in brain biopsy by providing the foundational data for precise trajectory planning and . (MRI) is the primary modality due to its exceptional contrast, which delineates lesions, , and adjacent neural structures with high resolution. Computed (CT) is routinely integrated to map bony landmarks, such as the and ventricular boundaries, which are critical for stereotactic frame alignment and determination. techniques, combining MRI and CT datasets, further augment accuracy by overlaying details with skeletal references, reducing navigation errors to submillimeter levels in stereotactic applications. Planning software, often integrated with neuronavigation systems, employs volumetric analysis to optimize biopsy trajectories. These tools process three-dimensional reconstructions of the to evaluate multiple candidate paths, selecting those that circumvent eloquent regions like the or to preserve function. By quantifying distances to critical structures and calculating risk scores based on tissue density and vascular proximity, the software prioritizes safer routes, such as avoiding sulcal crossings that elevate hemorrhage potential. Target selection benefits from advanced to refine precision and safety. Functional MRI (fMRI) maps cortical activation patterns during task-based paradigms, identifying sensorimotor or language areas to steer trajectories away from them. Diffusion tensor imaging (DTI) complements this by visualizing tracts, such as the corticospinal pathway, allowing planners to avoid disruption that could lead to deficits like . Virtual simulation within planning platforms enables preoperative rehearsal of the probe trajectory, simulating tissue penetration to forecast complications like hemorrhage. By modeling interactions with predicted vascular elements derived from , surgeons can iteratively adjust paths to lower risks, such as those from superficial veins or deep perforators. This step enhances procedural confidence, particularly in frameless stereotactic where adjustments are limited.

Performing the Procedure

Step-by-Step Execution

The step-by-step execution of a brain biopsy commences with incision and access to the . For stereotactic biopsy, the is incised linearly over the , followed by drilling a burr hole through the using a twist drill or high-speed drill to expose the . In open biopsy, a curvilinear incision is made, the underlying is dissected and retracted, and a circular or rectangular bone flap is created using a high-speed craniotome to provide direct visualization of the surface. Tissue sampling follows dural incision or opening. In stereotactic procedures, a rigid biopsy probe or needle is advanced along the preplanned trajectory to the lesion, where multiple cylindrical cores (typically 1-2 mm in diameter) are extracted using a side-cutting mechanism to obtain adequate samples for histopathological analysis. For open biopsy, microsurgical or ultrasonic is employed to resect a targeted segment of abnormal , also aiming for adequate for histopathological analysis while minimizing disruption. Variations in sampling technique depend on the biopsy type, as outlined in the Types of Brain Biopsies section. Hemostasis is then secured to control any bleeding from the biopsy tract or resection bed, commonly using topical hemostatic agents such as sponges soaked in or oxidized regenerated . Closure proceeds in layers: the dura is approximated watertight with sutures or dural substitute if needed, the bone flap is replaced and secured with plates or wires in open procedures, and the is closed with absorbable subcutaneous stitches and skin staples or nonabsorbable sutures, avoiding drains when feasible to reduce complication risks. The procedure typically requires 1-3 hours to complete, with stereotactic approaches often under 1 hour and open craniotomies extending to 2-3 hours based on lesion accessibility and surgical complexity.

Anesthesia and Intraoperative Monitoring

Brain biopsy procedures typically employ general as the standard approach, particularly for open biopsies, to ensure patient immobility and comfort during the invasive cranial exposure. In contrast, stereotactic biopsies, which are minimally invasive, are frequently performed under with or without intravenous , allowing for shorter procedure times and reduced pulmonary complications compared to general , without compromising diagnostic yield. For biopsies in eloquent brain areas, such as those near motor or language regions, combined with enables to assess neurological function in , minimizing the risk of postoperative deficits. Intraoperative monitoring is essential to maintain and detect potential neurological changes during the procedure. Standard physiological monitoring includes continuous , pulse oximetry, and noninvasive blood pressure assessment to track cardiovascular stability. (EEG) is utilized for detection, providing real-time assessment of cortical electrical activity. (ICP) monitoring may be employed in select high-risk patients, such as those with preexisting elevated ICP, using intraventricular or intraparenchymal probes to guide adjustments in or positioning and prevent herniation. Neuromonitoring techniques, including motor evoked potentials (MEPs) and somatosensory evoked potentials (SEPs), are applied in procedures involving eloquent areas to evaluate the integrity of motor and sensory pathways, with changes in signal or latency prompting immediate surgical pauses or trajectory adjustments. Intraoperative decisions often incorporate frozen section analysis to provide immediate histopathological feedback on tissue adequacy. During stereotactic biopsy, the initial sample is rapidly frozen and examined under by a neuropathologist, yielding a preliminary in approximately 67% of cases at the first target position, with additional samples increasing accuracy to 89% by the fourth section. This technique allows surgeons to confirm the presence of neoplastic or non-neoplastic tissue on-site, potentially avoiding nondiagnostic procedures and guiding real-time trajectory refinements if needed. Pharmacological support plays a key role in mitigating intraoperative risks. Prophylactic anticonvulsants, such as or , are commonly administered perioperatively in surgeries, including biopsies, to prevent seizures, despite from meta-analyses indicating limited overall efficacy in seizure-naive patients. Corticosteroids, typically dexamethasone at doses of 4-10 mg intravenously, are routinely given to reduce peritumoral and stabilize , with administration often starting intraoperatively and continued postoperatively in 25-50% of cases depending on characteristics.

Postoperative Management

Immediate Aftercare

Following a brain biopsy, patients are typically transferred to a post-anesthesia care unit () or (ICU) for close monitoring during the initial recovery phase. This observation period usually lasts 24 hours, during which such as , , and are continuously tracked, and neurological assessments—including checks for alertness, response, motor function, and speech—are performed every 15 to initially, then less frequently as stability improves. Symptom management in the immediate postoperative period focuses on alleviating common discomforts and preventing complications. is controlled with opioids or acetaminophen administered intravenously or orally, while antiemetics are given to address from . Prophylactic antibiotics, typically started preoperatively and continued briefly if indicated, help reduce , though routine extended use is not standard unless is suspected. Medications to reduce swelling, such as corticosteroids, may also be provided. Discharge from the hospital occurs once neurological status is stable, with no signs of confirmed via postoperative if clinically indicated, and normalized; most patients are able to go home within 1 to 2 days. In select low-risk cases, outpatient or same-day discharge may be feasible under enhanced recovery protocols. Wound care involves keeping the incision site clean and dry initially, with gentle washing using and water permitted starting the day after . Staples or sutures are typically removed 7 to 10 days postoperatively during a follow-up visit.

Recovery Monitoring and Follow-Up

Following discharge from the hospital, patients undergoing brain biopsy typically attend outpatient clinic visits to assess , neurological status, and overall progress. Initial follow-up appointments are commonly scheduled within one week to evaluate incision sites, remove staples or stitches if present, and discuss preliminary results. Subsequent visits occur at around one month, with ongoing surveillance every few months in the first year, tapering to every six to twelve months thereafter, depending on the underlying and plan. Serial plays a key role in monitoring for complications or residual issues. A postoperative MRI or is often performed within 24 hours to confirm the absence of hemorrhage or . Follow-up MRI is then conducted at approximately three months to assess stability and guide further management. Rehabilitation is tailored to address any procedure-related deficits, which occur in a minority of cases. Physical and may be recommended for motor impairments such as , reported in approximately 5-10% of stereotactic biopsy patients due to transient neurological effects. is incorporated if assessments reveal or challenges, with intensive programs promoting functional gains regardless of tumor type. Lifestyle modifications during recovery emphasize safety and gradual reintegration. Patients are advised to avoid heavy lifting or strenuous activities for 4 to 6 weeks to prevent increased intracranial pressure. Seizure precautions are essential, particularly if prophylactic anticonvulsants were administered perioperatively; this includes not driving until cleared by a physician, avoiding swimming unsupervised, and ensuring a safe home environment free of hazards like sharp edges. Long-term outcomes are generally favorable for most patients, with the majority returning to baseline function within several weeks, facilitated by the minimally invasive nature of stereotactic techniques. The majority resume normal activities and employment, though persistent monitoring is required to manage any delayed effects.

Risks and Complications

Potential Adverse Effects

Brain biopsy, whether performed via stereotactic or open techniques, carries inherent risks due to the brain's delicate vascular and neural structures. The most common adverse effect is hemorrhage, occurring in approximately 3-5% of cases overall, with symptomatic hemorrhage affecting about 2-4% of patients and potentially leading to increased or neurological deterioration. This risk arises from disruption of cerebral blood vessels during tissue sampling, particularly in hypervascular lesions such as glioblastomas or metastases. , another frequent complication, develops in 1-2% of procedures, often manifesting as , formation, or wound infection due to bacterial introduction at the surgical site. Postoperative can also occur, contributing to seizures in up to 5% of patients, as swelling in the confined cranial space exacerbates and irritates surrounding neural tissue. Rare but severe complications include mortality, with overall rates of 0.5-2% in experienced centers (as of 2025), potentially higher in challenging cases such as diffuse parenchymal diseases like where tissue sampling is more challenging and diagnostic yield is lower. Neurological deficits, such as , , or , may result from direct injury to eloquent areas or sampling errors that miss the target , affecting 1-3% of cases depending on lesion location. Type-specific risks vary; vascular lesions, including arteriovenous malformations, exhibit higher rates (up to 10%) owing to their fragile neovasculature. Stereotactic biopsies generally pose lower overall complication rates (around 12%) compared to open approaches (about 20%), primarily due to the minimally invasive trajectory that reduces tissue trauma. As of 2025, recent studies report symptomatic complications in approximately 3.9% of stereotactic cases, with 0.8% fatal. Patient-specific factors can significantly influence adverse outcomes. For instance, preoperative use of anticoagulants or antiplatelet agents increases the hemorrhage risk by 2-3 times, as these medications impair in the intraoperative setting. Other contributors include lesion size, location near critical structures, and underlying comorbidities like , which may exacerbate vascular fragility. Management of these effects, such as through imaging surveillance and supportive care, is addressed in subsequent sections.

Prevention and Management

Preventive measures during brain biopsy focus on meticulous preoperative and intraoperative strategies to minimize risks such as hemorrhage and . Trajectory planning is essential to avoid critical structures, including blood vessels, which can be achieved through advanced imaging techniques like or laser Doppler flowmetry to detect and circumvent vascular paths along the route. For patients with , may be considered to mitigate hemorrhagic risk, as low platelet levels are associated with increased complications. Intraoperative , including Doppler modes, provides real-time guidance to identify vessels and adjust the path, thereby reducing mechanical injury during stereotactic procedures. If complications arise, standardized management protocols guide prompt intervention. For postoperative hemorrhage, immediate reversal of anticoagulation is critical: prothrombin complex concentrates with intravenous for warfarin users, for , and for factor Xa inhibitors, aiming to normalize within hours to limit hematoma expansion. Surgical evacuation is indicated for significant exceeding 30 mL, particularly those causing or neurological deterioration, using minimally invasive techniques or to alleviate . In cases of , such as abscess formation, intravenous broad-spectrum antibiotics (e.g., and ) are initiated empirically, combined with surgical to remove purulent material and facilitate resolution. A multidisciplinary approach enhances outcomes by coordinating specialized . Neurosurgical is prioritized for neurological deficits due to hemorrhage or , often involving urgent , while consultation is sought for seizure management with anticonvulsants like to prevent . Intraoperative neuromonitoring, through techniques like evoked potentials, enables early detection of neural compromise, allowing immediate adjustments that significantly reduce the risk of permanent neurological damage.

Pathological Interpretation

Tissue Analysis Methods

Following a brain biopsy, the obtained undergoes standardized to preserve and enable diagnostic evaluation. Portions of the fresh are allocated for , frozen sections, and molecular studies, while the remainder is fixed in 10% neutral buffered formalin to prevent autolysis and maintain structural integrity for subsequent . Fixed is then dehydrated, cleared, embedded in , and sectioned into thin slices (typically 4-5 micrometers) for mounting on slides. Histopathological examination begins with hematoxylin and eosin (H&E) staining, the cornerstone method for assessing cellular architecture, nuclear atypia, and tissue organization in brain biopsies. This routine stain highlights basic tissue features, such as neoplastic cells in tumors or inflammatory infiltrates in infections, providing an initial diagnostic framework. Special stains are employed as needed; for instance, silver impregnation techniques, like the modified Bielschowsky method, visualize amyloid plaques or neurofibrillary tangles in neurodegenerative diseases such as Alzheimer's disease. Immunohistochemistry (IHC) enhances specificity by detecting protein markers in fixed, sectioned tissue using antigen-specific antibodies. Common applications include glial fibrillary acidic protein (GFAP) to identify astrocytic differentiation in gliomas, aiding in tumor classification and grading. Advanced methods address molecular and ultrastructural details. Molecular testing, such as polymerase chain reaction (PCR), detects genetic mutations (e.g., IDH1/IDH2 or BRAF V600E) critical for brain tumor subtyping, often performed on fresh or fixed tissue extracts. Electron microscopy examines ultrastructure in cases of suspected infections, revealing viral particles or inclusion bodies at nanometer resolution when light microscopy is inconclusive. Turnaround times vary by complexity: preliminary reports from initial H&E or frozen sections are typically available within 24-48 hours, while comprehensive analysis incorporating IHC, special stains, and molecular tests requires up to one week.

Clinical Implications of Results

The results of a brain biopsy play a pivotal role in guiding therapeutic decisions for patients with suspected central nervous system (CNS) lesions. When the biopsy confirms a positive tumor diagnosis, histopathological grading according to the integrated World Health Organization (WHO) 2021 classification—which combines histological and molecular features—is essential for determining the extent of surgical intervention. For instance, low-grade gliomas (WHO grades 1-2) may allow for maximal safe resection to achieve long-term control, whereas high-grade tumors like glioblastoma (WHO grade 4) often necessitate a combination of biopsy confirmation followed by adjuvant therapies due to their aggressive nature. In glioblastoma cases, the biopsy result typically prompts initiation of the Stupp protocol, involving concurrent radiotherapy and temozolomide chemotherapy, which has become the standard of care to improve survival outcomes. Non-malignant biopsy findings, such as those indicating inflammatory or infectious processes, similarly direct targeted management strategies to avoid unnecessary oncologic treatments. For inflammatory conditions like primary angiitis of the CNS, results often lead to immunosuppressive therapy with corticosteroids and to control vascular inflammation and prevent further neurological deterioration. In cases of infection, such as herpes simplex virus , the identification of viral pathogens via prompts immediate antiviral treatment with agents like acyclovir, which can be lifesaving by halting disease progression. These non-neoplastic diagnoses alter clinical management in a substantial proportion of cases, with studies showing an impact on clinical management in up to 87.5% of patients, including treatment changes in 57.8% following such results. Beyond immediate treatment guidance, brain biopsy results provide critical prognostic information through the identification of biomarkers that predict therapeutic response and overall survival. For example, promoter methylation status in , assessed from biopsy tissue, serves as a key predictor; methylated tumors exhibit greater sensitivity to , correlating with improved progression-free and overall survival rates. A negative or inconclusive biopsy, particularly in high-suspicion cases, may necessitate re-biopsy to obtain diagnostic tissue, as repeat procedures have demonstrated diagnostic yields of 86.7% in initially nondiagnostic cases, thereby refining and avoiding diagnostic delays. The integration of biopsy results into multidisciplinary tumor board discussions enhances by combining histopathological findings with and clinical data. These boards, involving neurosurgeons, oncologists, radiologists, and pathologists, facilitate personalized treatment plans, such as deciding between observation, additional resection, or experimental therapies based on the holistic assessment of biopsy-derived grading and imaging correlates. This collaborative approach has been shown to optimize patient outcomes in complex CNS cases by ensuring comprehensive evaluation of all available data.

Alternatives and Emerging Techniques

Non-Invasive Diagnostic Options

Non-invasive diagnostic options play a crucial role in the initial evaluation of suspected brain lesions, often providing preliminary insights that may delay or obviate the need for invasive procedures like brain biopsy. Advanced (MRI) techniques, such as and MR spectroscopy, enable detailed tumor characterization by assessing vascularity, blood volume, and metabolic profiles without surgical intervention. measures cerebral blood flow and volume to differentiate high-grade from low-grade tumors based on hypervascularity patterns, while MR spectroscopy identifies metabolite ratios like choline-to-N-acetylaspartate, which indicate cellular proliferation and neuronal integrity. These methods offer non-invasive grading and localization, particularly useful for gliomas and metastases. Positron emission tomography (PET) complements MRI by evaluating metabolic activity in brain tumors, using tracers like 18F-fluorodeoxyglucose (FDG) or analogs to highlight hypermetabolic regions indicative of . In , PET detects tumor viability and distinguishes recurrence from treatment effects, with combined providing enhanced anatomical and functional correlation for precise diagnosis. This approach is particularly valuable for lesions inaccessible to immediate or in patients with contraindications to . Liquid biopsy represents another non-invasive strategy, involving (CSF) analysis for (ctDNA) and biomarkers in . CSF ctDNA detection via targeted sequencing or allows molecular subtyping of gliomas and monitoring of tumor dynamics, with higher ctDNA yield in CSF compared to due to direct proximity to . This technique supports diagnosis in cases where surgical access is risky, such as brainstem tumors. Emerging blood-based liquid biopsies, including ctDNA and exosomal biomarkers, are also being explored for gliomas, offering potential systemic monitoring with improving sensitivity as of 2025. Additional non-invasive tests include serum markers like neuron-specific enolase (NSE), which aids in diagnosing and monitoring neuroblastoma with central nervous system involvement by detecting elevated levels associated with advanced disease. Despite these advances, non-invasive options have limitations, including lower specificity—typically 70-80% for imaging modalities like PET and advanced MRI compared to over 95% for histopathological biopsy confirmation—leading to potential false positives in distinguishing tumor types or grades. They are also not suitable for all lesions, particularly small, non-enhancing, or deep-seated tumors where definitive tissue sampling remains essential.

Advances in Biopsy Technology

Recent advancements in robotic assistance have significantly enhanced the precision and safety of brain biopsies by automating trajectory planning and execution, thereby minimizing human error. The ROSA (Robotized Stereotactic Arm) system, introduced in the 2010s, exemplifies this progress; it employs a frameless stereotactic approach that integrates preoperative imaging with real-time robotic guidance to achieve submillimeter accuracy in needle placement. Clinical studies have demonstrated that ROSA-assisted biopsies reduce procedure times and complication rates compared to traditional methods, with diagnostic yields exceeding 95% in prospective cohorts. For instance, a multicenter analysis of over 100 cases reported no permanent deficits attributable to the robotic system, underscoring its role in enabling minimally invasive access to deep-seated lesions. Intraoperative imaging technologies have further revolutionized brain biopsy by providing dynamic visualization to refine targeting and confirm sampling adequacy during . Real-time (MRI)-guided stereotactic allows for immediate adjustments to the based on live contrasts, improving diagnostic accuracy to nearly 100% while reducing the need for repeat procedures. This approach is particularly valuable for eloquent regions, where traditional frame-based methods may limit flexibility. Complementing MRI, fluorescence-guided using 5-aminolevulinic acid (5-ALA) induces accumulation in malignant cells, enabling surgeons to visualize tumor margins under for targeted sampling. Meta-analyses of 5-ALA applications in stereotactic biopsies report rates above 90% for high-grade gliomas, with lower nondiagnostic rates than conventional white-light techniques. Nanotechnology is emerging as a frontier for in vivo brain sampling, with nanoprobes designed to facilitate minimally invasive tissue acquisition and molecular analysis without full surgical exposure. Self-functionalized three-dimensional nanoprobes, for example, enable real-time detection of tumor biomarkers in cerebrospinal fluid or interstitial spaces, offering a bridge toward liquid biopsy equivalents for solid brain lesions. These probes leverage surface-enhanced Raman spectroscopy for ultrasensitive sampling, detecting glioma-specific markers at picomolar concentrations in preclinical models. Additionally, microfabricated nanoliter sampling probes allow on-demand collection of brain extracellular fluid, providing compositional insights that complement traditional tissue biopsies while reducing invasiveness. Integration of (AI) with these technologies optimizes biopsy planning by predicting optimal trajectories through algorithms trained on imaging datasets. AI-driven systems analyze patient-specific to select paths that avoid critical structures, achieving up to 20% shorter trajectories with equivalent diagnostic yields in simulation studies. For instance, models have been applied to stereotactic planning software, enhancing automation in robotic platforms like ROSA. Ongoing clinical trials as of 2025 are evaluating the synergy of laser interstitial thermal therapy (LITT) with biopsy, aiming to combine diagnostic sampling with therapeutic in a single minimally invasive session. Preliminary data from the REMASTer (NCT05124912), for example, suggest that LITT-integrated biopsies for recurrent brain metastases yield comparable overall survival to open surgery, with reduced recovery times. Similarly, prospective studies on primary , such as the EMITT , incorporate MRI-guided LITT-biopsy protocols, reporting feasibility in irresectable cases and exploring cost-effectiveness endpoints. These trials highlight LITT's potential to ablate lesions while obtaining viable for , with preliminary data showing low rates under 5%.

References

  1. [1]
    Brain tumor - Diagnosis and treatment - Mayo Clinic
    Oct 15, 2025 · A brain biopsy is a procedure to remove a sample of brain tumor tissue for testing in a lab. Often a surgeon gets the sample during surgery to remove the brain ...Missing: definition | Show results with:definition
  2. [2]
    Brain Surgery: Purpose, Recovery, Risks & Types - Cleveland Clinic
    Biopsy: A brain biopsy is the removal of a small piece of tissue or fluid sample from the brain. A pathologist examines it, usually to find out if a tumor is ...
  3. [3]
    Brain surgery: MedlinePlus Medical Encyclopedia
    Jan 13, 2025 · Remove a tumor or a piece of tumor for a biopsy; Remove abnormal brain tissue; Drain blood or an infection; Free a nerve; Take a sample of brain ...
  4. [4]
    Brain Biopsy > Clinical Keywords > Yale Medicine
    A brain biopsy is a diagnostic procedure in which a small sample of brain tissue is removed and examined under a microscope to determine the presence of ...
  5. [5]
    Brain Biopsy | Stanford Health Care
    A brain biopsy is performed to remove tissue or cells from the brain for examination under a microscope. Read more here.Missing: definition | Show results with:definition
  6. [6]
    Stereotactic Brain Biopsy - AANS
    Stereotactic Brain Biopsy is a common procedure that allows a neurosurgeon to diagnose a brain lesion. Performed in the operating room.Missing: definition | Show results with:definition
  7. [7]
    Evaluation of 311 contemporary cases of stereotactic biopsies in ...
    Sep 20, 2020 · The overall diagnostic yield was 86.2% and differed significantly between the various suspected diagnosis groups and was the highest when ...
  8. [8]
    Brain metastasis from an unknown primary, or primary brain tumour ...
    Solitary brain lesions have been found to be metastatic in only 15% of patients with an unknown primary site. A recent study that compared brain lesion images ...
  9. [9]
    Diagnostic yield of brain biopsies in children presenting to neurology
    The role of brain biopsy is well established in patients with neoplastic lesions, with a diagnostic yield approaching 95%. The diagnostic yield of brain biopsy ...
  10. [10]
    William Macewen and the first documented successful resection of a ...
    Jan 17, 2023 · William Macewen was a visionary fearless Scottish surgeon who performed the first documented successful resection of a brain tumor on July 27, 1879.Missing: biopsy | Show results with:biopsy
  11. [11]
    Sir William Macewen (1848–1924): Pioneering the Field of ...
    Macewen conducted the first documented successful resection of a brain tumor at the Glasgow Royal Infirmary on July 27, 1879. The patient, Barbara Watson, ...Missing: biopsy | Show results with:biopsy
  12. [12]
    Harvey W. Cushing | AJR - American Journal of Roentgenology
    Jun 22, 2017 · A career retrospective documented that he had operated on more than 2,000 brain tumors, more than any other surgeon in history [6]. Cushing is ...
  13. [13]
    Harvey Cushing and pediatric brain tumors at Johns Hopkins - NIH
    Cushing strove to maximize exposure while minimizing blood loss in an attempt to increase his ability to successfully treat pediatric brain tumors. His early ...
  14. [14]
    Spiegel and Wycis - the early years - PubMed
    The field of human stereotactic surgery was introduced by Ernest A. Spiegel and Henry T. Wycis by a historical paper in Science in 1947.
  15. [15]
    Early history of the stereotactic apparatus in neurosurgery in
    Stereotactic neurosurgery has a rich history, beginning with the first stereotactic frame described by Horsley and Clarke in 1908.
  16. [16]
    Image-Guided Brain Biopsy | Radiology Key
    Feb 20, 2016 · The advent of computed tomography (CT) in the 1970s marked the beginning of the modern era of brain biopsy.
  17. [17]
    How is stereotactic brain biopsy evolving? A multicentric analysis of ...
    The first clinical report of CT-guided stereotactic biopsy ... (MRI)-guided biopsy followed in the 1980s [7]. Since then, image-guided stereotactic brain biopsy ...
  18. [18]
    2 A Brief History of Brain Stereotactic Frames | Neupsy Key
    May 11, 2020 · The collaborative effort of Spiegel and Wycis from the 1930s to 1950s, led to significant advances in the development of stereotactic devises.
  19. [19]
    Comparative Effectiveness of Frame-based, Frameless and ...
    Frame-based, frameless stereotactic and ioMRI guided brain needle biopsy have comparable diagnostic yield for patients with no prior treatments (either ...
  20. [20]
    Role of Biopsies in the Management of Intracranial Gliomas
    Another frequent indication for brain tumor biopsy involves clinical trial enrollment. The prognosis of patients diagnosed with malignant gliomas remains poor ...
  21. [21]
    The Role of Stereotactic Biopsy in Brain Metastases - PMC
    Currently the predominant indication for BrM biopsy is diagnostic uncertainty, typically where concurrent patient features such as lack of other metastatic ...
  22. [22]
    Primary Brain Tumors in Adults: Diagnosis and Treatment - AAFP
    Feb 1, 2016 · The most common symptoms of these tumors are headache and seizures. Diagnosis of a suspected brain tumor is dependent on appropriate brain ...
  23. [23]
    Brain Biopsy in Patients With Acquired Immunodeficiency Syndrome
    Nov 22, 1999 · Conclusions These data show that in human immunodeficiency virus–positive patients with brain mass lesions, SBB has a high diagnostic yield. A ...Missing: immunocompromised | Show results with:immunocompromised
  24. [24]
    https://www.aafp.org/pubs/afp/issues/2016/0201/p211.html
  25. [25]
    Intracranial mass lesions in acquired immunodeficiency syndrome
    We studied the effectiveness of performing a stereotactic brain biopsy in the individual with acquired immunodeficiency syndrome (AIDS) and an intracranial ...Abstract · Methods · Discussion
  26. [26]
    Diagnostic Yield and Safety of Brain Biopsy for Suspected Primary ...
    Jun 28, 2016 · Biopsy identified alternative diagnoses in 24 patients (30%), with cerebral amyloid angiopathy (8 patients), encephalitis (5 patients), ...
  27. [27]
    Brain biopsy in dementia - PubMed
    Fifty-seven per cent of biopsies were diagnostic: the most frequent diagnoses were Alzheimer's disease (18%), Creutzfeldt-Jakob disease (12%) and inflammatory ...Missing: neoplastic conditions
  28. [28]
    Brain biopsy in dementia - Oxford Academic
    Fifty-seven per cent of biopsies were diagnostic: the most frequent diagnoses were Alzheimer's disease (18%), Creutzfeldt–Jakob disease (12%) and inflammatory ...
  29. [29]
    Reassessing the Role of Brain Tumor Biopsy in the Era of Advanced ...
    Sep 12, 2021 · Brain biopsy is the gold standard in order to establish the diagnosis of unresectable brain tumors. Few studies have investigated the long-term ...
  30. [30]
    Clinical impact and safety of brain biopsy in unexplained central ...
    In a selected population of patients with unexplained CNS disorders, clinical impact of brain biopsies is high, while being relatively safe.
  31. [31]
    [PDF] An Audit on the Use of Brain Biopsies for Non-neoplastic Brain ...
    Oct 1, 2021 · Conclusion: This study shows that brain biopsies are useful in the investigation of non-neoplastic neurological disease and can have a high ...
  32. [32]
    Brain biopsy in neurologic decline of unknown etiology - PMC
    Brain biopsies have an uncertain role in the diagnosis of patients with dementia or neurologic decline of unknown etiology.
  33. [33]
    Extended stereotactic brain biopsy in suspected primary central ...
    Aug 19, 2020 · Invasive brain biopsy was considered indicated when non-invasive testing provided inconclusive results but PACNS was still suspected or ...Missing: necessity | Show results with:necessity
  34. [34]
    The medical necessity of advanced molecular testing in the ...
    In most cases, the main purpose of molecular testing in brain tumors is to ensure that the tumor is properly classified, so as to best inform the patient and ...Missing: invasive insufficient
  35. [35]
    IDH mutation in glioma: molecular mechanisms and potential ...
    Apr 15, 2020 · Mechanistic studies revealed that neomorphic IDH1 mutant activity results in both global DNA hypermethylation and histone methylation.
  36. [36]
    IDH1 and IDH2 Mutations in Gliomas - PMC
    The mutations also drive increased methylation in gliomas. Gliomas with mutated IDH1 and IDH2 have improved prognosis compared to gliomas with wild-type IDH.
  37. [37]
    Impact of brain biopsy on management of nonneoplastic brain disease
    Jan 19, 2022 · Brain biopsy had clinical impact, including a change in treatment, in most patients studied, and may be considered a useful diagnostic option in nonneoplastic ...
  38. [38]
    Stereotactic biopsy of brainstem lesions: Techniques, efficacy, safety ...
    An inconclusive biopsy is reported in 2-30% of the cases in various studies.[2425] But most of the modern studies report a diagnostic yield of more than 90%.
  39. [39]
    Ethics consultations in neuro-oncology - PMC - PubMed Central
    The aim of this study was to characterize ethical conflicts encountered in neuro-oncologic patients.
  40. [40]
    Frame and Frameless Stereotactic Brain Biopsy - Clinical Gate
    Mar 26, 2015 · The first person to use a device for localizing brain structures was D. N. Zernov in 1889. A professor of anatomy in Moscow, Russia, he invented ...Missing: late | Show results with:late
  41. [41]
    The Invention and Early History of the N-Localizer for Stereotactic ...
    Brown invented the N-localizer and built the first CT-compatible stereotactic frame in 1978. The N-localizer has become an important tool for modern ...
  42. [42]
    Comparison of Frame-Based Versus Frameless Image-Guided ...
    Jul 29, 2021 · The frameless biopsy technique is as efficient as the frame-based brain biopsy technique with a low complication rate.Missing: advantages Leksell
  43. [43]
    (PDF) Frame-based versus frameless stereotactic brain biopsies
    Feb 10, 2021 · Conclusion Based on very low-quality evidence, both frame-based and frameless stereotaxy are safe and effective for biopsy of intracranial ...
  44. [44]
    Establishing stereotactic brain biopsies in outpatient care as the ...
    May 21, 2025 · Outpatient stereotactic brain biopsy is a safe and feasible approach for carefully selected patients, with high success rates and no increase in complication ...
  45. [45]
    Severity, timeline, and management of complications after ...
    Sep 10, 2021 · This study aimed to analyze 1) complications following brain biopsies, using a graded severity scale, and 2) a timeline of complication occurrence.
  46. [46]
    Leksell Frame-Based Stereotactic Biopsy for Infratentorial Tumor - NIH
    Stereotactic biopsy using the Leksell frame is a procedure performed under local anesthesia that enables rapid diagnosis with increased stability and proven ...
  47. [47]
    Stereotactic Brain Biopsies in AIDS Patients: Superior Diagnostic ...
    Of these, 11 were performed with a 2-mm-diameter cup forceps, and 14 with a 10-mm-long x 2-mm-diameter side-cutting needle. Abnormal tissue was obtained ...
  48. [48]
    Peripheral compressing artifacts in brain tissue from stereotactic ...
    The side-cutting type brain biopsy needle consists of inner and outer cannulae, both of which contain a side window. When the needle tip reached the target, the ...Missing: cup | Show results with:cup
  49. [49]
    Craniotomy - StatPearls - NCBI Bookshelf
    A craniotomy is a surgical procedure in which a part of the skull is temporarily removed to expose the brain and perform an intracranial procedure.Missing: advantages disadvantages
  50. [50]
    Stereotactic biopsy for brain lesions: Doing more with less - PMC
    Oct 14, 2023 · Stereotactic biopsy (STB) is a potential diagnostic tool considering its minimal invasiveness, high diagnostic yield, and minimal associated complications.Stereotactic Frame · Scalp Block · Discussion<|control11|><|separator|>
  51. [51]
    Biopsy for brain and spinal cord tumours | Cancer Research UK
    A biopsy means taking a small tissue sample from your brain and looking at it under a microscope. This helps your doctors decide the best treatment for you.Missing: definition | Show results with:definition
  52. [52]
    Risk Factors for Central Nervous System Infections After Craniotomy
    Jul 29, 2024 · Craniotomy may lead to postsurgical intracranial infection, which is mainly associated with surgery duration, infratentorial (posterior fossa) surgery, ...
  53. [53]
    Preoperative Assessment of Adult Patients for Intracranial Surgery
    The preoperative assessment of the patient for neurosurgical and endovascular procedures involves the understanding of the neurological disease and its systemic ...
  54. [54]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC2911602/
  55. [55]
    Preoperative Evaluation | Cohen Collection | Volumes
    The preoperative evaluation provides an important opportunity for the surgeon to establish rapport with the patient and family and provide information to them ...
  56. [56]
    Preparing for Brain Surgery - Johns Hopkins Medicine
    We will provide you with both written and verbal instructions. The following general information may be helpful in planning for some of our procedures.Missing: biopsy | Show results with:biopsy
  57. [57]
    Multiplanar MRI–CT fusion neuronavigation-guided serial ...
    This study shows for the first time a collection of patients with brain tumors with their associated multiplanar MRI–CT fusion imaging during stereotaxis.
  58. [58]
    Stereotactic Brain Biopsy - Brain and Spine Center of Texas
    Pre-Surgical Imaging – A CT scan or MRI is used to create a precise 3D map of the brain. Head Stabilization – A stereotactic frame or frameless navigation ...
  59. [59]
    Computer-Assisted Versus Manual Planning for Stereotactic Brain ...
    Aug 5, 2019 · The risk of hemorrhage is significantly greater when trajectories traverse sulci. As the risk score was the primary optimization criterion ...Missing: simulation | Show results with:simulation
  60. [60]
    Functional-guided frameless stereotactic biopsy of highly eloquent ...
    This study evaluated the usefulness and clinical impact of non-invasive cortical mapping and tractography of eloquent brain functions for trajectory planning ...
  61. [61]
    Intraoperative detection of blood vessels with an imaging needle ...
    Dec 19, 2018 · OCT speckle decorrelation detection of cerebral blood vessels holds great promise to reduce hemorrhagic risk from stereotactic brain biopsy.
  62. [62]
    Craniotomy - Mayo Clinic
    Oct 2, 2025 · The surgery is used to treat brain tumors, bleeding in the brain, blood clots or seizures. It also may be done to treat a bulging blood vessel ...Missing: advantages disadvantages
  63. [63]
    Stereotactic biopsy for lesions in brainstem and deep brain - PMC
    Jul 23, 2021 · After skin incision, drilling the skull, and cutting the dura mater, the biopsy needle was used to puncture according to the planned system ...
  64. [64]
    CT-assisted stereotactic brain biopsy: value of intraoperative frozen ...
    ... specimen volume was less than 2 mm3, the biopsy was generally successful. The disadvantages of the small sample size obtained through needle biopsy are best ...
  65. [65]
    Retained Surgical Sponges after Craniotomies - PMC - NIH
    Bioabsorbable agents may be left in the surgical bed to maintain hemostasis after wound closure. Three commonly used resorbable hemostatic agents are ...
  66. [66]
    Outpatient stereotactic brain biopsies - PMC - NIH
    Stereotactic brain biopsies can therefore be safely achieved on an outpatient setting in carefully selected patients.
  67. [67]
    Brain tumour biopsy
    A brain tumour biopsy is where a sample of abnormal tissue is removed to help diagnose the type and grade of tumour you have.Missing: definition | Show results with:definition
  68. [68]
    Efficacy and safety of local versus general anesthesia in stereotactic ...
    A major advantage is the ability to perform these procedures under local anesthesia (LA). However, there is no consensus on whether or when to use LA or ...
  69. [69]
    Anesthesia for Awake Craniotomy - StatPearls - NCBI Bookshelf
    Jul 6, 2023 · [10] First-line treatment should be irrigation of the brain with sterile iced saline. Propofol bolus (10 to 20 mg IV) or midazolam (1 to 2 mg IV) ...
  70. [70]
    EEG in Brain Tumors - Medscape Reference
    Jul 16, 2025 · EEG provides the only continuous measure of cerebral function over time and is the diagnostic test of choice regarding seizures and epilepsy, which is common ...
  71. [71]
    Intracranial Pressure Monitoring - StatPearls - NCBI Bookshelf - NIH
    Jan 23, 2024 · The normal intracranial pressure (ICP) ranges from 7 to 15 mm Hg, while it does not exceed 15 mm Hg in the vertical position.
  72. [72]
    Intraoperative Neurophysiological Monitoring - StatPearls - NCBI - NIH
    Intraoperative neurophysiological monitoring (IONM) helps assess the integrity of neural structures and consciousness during surgical procedures.Missing: biopsy | Show results with:biopsy
  73. [73]
    Frozen section evaluation of stereotactic brain biopsies - PubMed
    Objective: Use of the image-guided stereotactic brain biopsy has facilitated the diagnosis of previously inaccessible lesions with both safety and reliability.
  74. [74]
    The diagnostic properties of frozen sections in suspected ...
    Intraoperative FS diagnoses demonstrate high diagnostic accuracy. However, agreement varies among histopathological entities and is lower in low-grade tumors ...
  75. [75]
    Anticonvulsant prophylaxis for brain tumor surgery
    Aug 29, 2014 · The most commonly used AED for perioperative prophylaxis after brain tumor surgery is phenytoin. Other preferred AEDs include valproic acid, ...
  76. [76]
    After brain tumour surgery | Cancer Research UK
    The information on this page covers what happens immediately after and the first few days after surgery for a brain or spinal cord tumour.
  77. [77]
    Symptomatic intracranial hemorrhages and frame-based stereotactic ...
    Aug 1, 2020 · After the stereotactic biopsy, all the patients were under surveillance in the ICU or recovery room for 24 h. During Periods I and II, where ...Surgical Planning · Surgical Technique · Discussion<|control11|><|separator|>
  78. [78]
    Stereotactic Brain Biopsy | Expert Surgeon - Aaron Cohen-Gadol, MD
    Feb 25, 2024 · A stereotactic brain biopsy is minimally invasive and involves a small scalp incision, the creation of a dime-sized opening in the skull bone (burr hole), and ...
  79. [79]
    [PDF] post-operative instructions after a craniotomy
    When you feel that you no longer need your prescription pain medications, you may take 500 to 1000 mg of Tylenol every six hours as needed. • Incision care: You ...<|control11|><|separator|>
  80. [80]
    ASRA Pain Medicine consensus practice infection control guidelines ...
    Jan 20, 2025 · Preoperative antibiotics should be administered by the intravenous route prior to breaching the skin (30–60 min for cefazolin or clindamycin, ...
  81. [81]
    Safety and efficacy of brain biopsy: Results from a single institution ...
    This study demonstrates that brain biopsy is a procedure with an acceptably low rate of severe complications and mortality, in line with previously published ...
  82. [82]
    Brain Tumor Surgery | Johns Hopkins Medicine
    a surgical procedure to remove a small sample of a brain tumor for examination under a microscope — is usually performed during surgery to remove ...
  83. [83]
    Brain Tumor Follow-Up Care | Expert Surgeon
    Oct 3, 2024 · After surgery, you may require rehabilitation to improve your neurological recovery. You will see your surgical team within 2-4 weeks of surgery ...Missing: postoperative clinic
  84. [84]
    Timing of Early Postoperative MRI following Primary Glioblastoma ...
    Feb 20, 2023 · This study argues that early postoperative MRIs acquired before 48-h is preferable based on the occurrence of contrast enhancements. However, ...
  85. [85]
    [PDF] Guidelines for follow up imaging of adult patients with tumours of the ...
    Follow up imaging frequency​​ Then annually. At any time on symptom progression. Following biopsy/resection + radiotherapy. At 3 months after RT.
  86. [86]
    Independent predictors of morbidity after image-guided stereotactic ...
    Thirty-six patients (13%) experienced stereotactic biopsy—related morbidity. Morbidity consisted of arm or hand paresis in 18 patients (7%), hemiparesis in 16 ...
  87. [87]
    Intensive Rehabilitation Therapy Following Brain Tumor Surgery
    Intensive rehabilitation may help promote functional improvement following brain tumor surgery regardless of malignancy compared with stroke patients.
  88. [88]
    The ability to return to work: a patient-centered outcome parameter ...
    Sep 22, 2020 · We found that the majority of patients with gliomas were able to return to work following surgical and adjuvant treatment.
  89. [89]
    Current Trends for Improving Safety of Stereotactic Brain Biopsies
    Oct 1, 2019 · Herein, we review advanced optical techniques for improvement of safety and efficacy of stereotactic needle biopsy procedures.Missing: cup | Show results with:cup
  90. [90]
    Thrombocytopenia and Neurosurgery: A Literature Review - PubMed
    Introduction: The absence of evidence-based guidelines for platelet transfusion surrounding invasive neurosurgical procedures leads to uncertainty in management ...
  91. [91]
    Intraoperative use of Doppler ultrasound and endoscopic monitoring ...
    An intraoperative monitoring tool is described that prevents mechanical injury to intracerebral vessels during stereotactic surgery.
  92. [92]
    2022 Guideline for the Management of Patients With Spontaneous ...
    May 17, 2022 · This guideline provides updated recommendations for acute reversal of anticoagulation after ICH, highlighting use of protein complex ...
  93. [93]
    Brain Abscess - StatPearls - NCBI Bookshelf
    Sep 21, 2024 · For multiple abscesses, management usually involves a prolonged course of high-dose antibiotics (4-8 weeks) with or without aspirations, guided ...
  94. [94]
    Brain biopsy - RCPA
    Aug 30, 2024 · Method: Fresh tissue: for microbiology, frozen section, molecular studies. Fixed tissue: for light microscopy, immunohistochemistry and electron ...
  95. [95]
    Tissue Processing - Histotechniques
    Formalin is used for all routine surgical pathology and autopsy tissues when an H and E slide is to be produced. Formalin is the most forgiving of all fixatives ...Missing: brain GFAP silver prions turnaround
  96. [96]
    An Introduction to Specimen Processing - Leica Biosystems
    Overview of the steps in tissue processing for paraffin sections · 1. Obtaining a fresh specimen · 2. Fixation · 3. Dehydration · 4. Clearing · 5. Wax infiltration.Missing: GFAP silver prions electron
  97. [97]
    How We Diagnose Brain Tumors | Dana-Farber Cancer Institute
    Conventional histopathology analysis: The tissue is examined under a microscope to generate the initial diagnosis within a matter of days. · Immunohistochemistry ...
  98. [98]
    Silver diagnosis in neuropathology: principles, practice and revised ...
    In this review, four major silver-staining methods, modified Bielschowsky, Bodian, Gallyas (GAL) and Campbell–Switzer (CS) methods, are outlinedMissing: biopsy prions
  99. [99]
    Immunohistochemical expression of glial fibrillary acidic protein and ...
    Special IHC markers (GFAP and CAM5.2) were used to differentiate high-grade gliomas from metastatic tumors. Sections of the human brain were run with each batch ...
  100. [100]
    Molecular Testing of Brain Tumor - PMC - PubMed Central - NIH
    METHODS OF MOLECULAR TESTING. The molecular testing methods commonly used in pathology laboratories include immunohistochemical staining, direct sequencing ...
  101. [101]
    Electron Microscopy for Rapid Diagnosis of Emerging Infectious ...
    Electron microscopic diagnosis is uniquely suited for rapid identification of infectious agents. A specimen can be ready for examination.
  102. [102]
    [PDF] Even today, electron microscopy is useful for pathological diagnosis
    Viral infection was proven using electron microscopy, which revealed images of nuclei filled with viral particles. (Fig.1f, g). The frozen brain specimen had a ...<|separator|>
  103. [103]
    Turnaround times for samples - King's College Hospital
    Brain biopsies (surgical), 5 (2 if no special stains required), 95. Pituitary biopsies, 4, 95. Epilepsy surgery, 15, 95. Muscle biopsies, 10 (main report), 95.
  104. [104]
    The 2021 WHO Classification of Tumors of the Central Nervous ...
    Jun 29, 2021 · The 2021 fifth edition introduces major changes that advance the role of molecular diagnostics in CNS tumor classification.
  105. [105]
    Clinical implications of the 2021 edition of the WHO ... - PubMed - NIH
    Jun 21, 2022 · The new classification incorporates even more molecular alterations into the diagnosis of many tumours and reorganizes gliomas into adult-type diffuse gliomas.
  106. [106]
    Radiotherapy plus Concomitant and Adjuvant Temozolomide for ...
    Mar 10, 2005 · The current standard of care for newly diagnosed glioblastoma is surgical resection to the extent feasible, followed by adjuvant radiotherapy.
  107. [107]
    Encephalitis - Diagnosis and treatment - Mayo Clinic
    May 16, 2024 · A brain biopsy is usually done only if symptoms are worsening and treatments are having no effect.
  108. [108]
    MGMT promoter methylation is predictive of response to ...
    Dec 14, 2009 · Our data suggest that MGMT promoter methylation is a prognostic biomarker in GBM even in the absence of chemotherapy with alkylating agents.
  109. [109]
    [PDF] Efficacy of a Second Brain Biopsy for Intracranial Lesions after Initial ...
    Jul 21, 2020 · the first brain biopsy contributed to a diagnosis. We attempted to classify the reason why the first biopsy was nondiagnostic into three ...<|control11|><|separator|>
  110. [110]
    Neuro-Oncology Multidisciplinary Tumor Board: The Point of ... - NIH
    Jan 20, 2022 · Conclusions: Our study supported that the multidisciplinary approach to patient care can be particularly effective in managing brain tumors. A ...
  111. [111]
    Advanced MR Techniques for Preoperative Glioma Characterization
    The first part of this review includes perfusion imaging by dynamic contrast‐enhanced (DCE), dynamic susceptibility contrast (DSC), and arterial spin labeling ( ...
  112. [112]
    Diffusion-weighted and Perfusion MR Imaging for Brain Tumor ...
    In this review, the authors describe the fundamental principles of diffusion-weighted and perfusion MR imaging and provide an overview of the ways in which ...
  113. [113]
    Added Value of Spectroscopy to Perfusion MRI in the Differential ...
    Aug 1, 2018 · H-MR spectroscopy allows in vivo detection and characterization of brain metabolites, such as choline, a cellular membrane turnover marker ...
  114. [114]
    Clinical Applications of PET in Brain Tumors
    This article focuses on PET with 18 F-FDG and 18 F-labeled amino acid tracers in malignant gliomas and metastatic tumors, with a special focus on radiation ...
  115. [115]
    Comparison of PET/CT and PET/MRI in central nervous system ...
    This narrative review concluded that PET/MRI offers promising advantages over PET/CT for both new diagnoses and follow-up imaging in neuro-oncology.
  116. [116]
    Tumor-specific PET tracer imaging and contrast-enhanced Mri ...
    Aug 16, 2025 · The findings of this study highlight the potential of fusion imaging using PET and MRI as an effective diagnostic technique for glioblastoma ...
  117. [117]
    Tapping into the genome: the role of CSF ctDNA liquid biopsy in ...
    The use of liquid biopsy for noninvasive testing has revolutionized oncology with applications for diagnostics, disease monitoring, and treatment selection.
  118. [118]
    Targeted liquid biopsy for brain tumors - ScienceDirect
    The presence of ctDNA in CSF is notably higher than in plasma, making CSF an advantageous medium for liquid biopsy in brain tumor patients. Traditional liquid ...
  119. [119]
    Recent Advances in Liquid Biopsy of Brain Cancers - Frontiers
    Liquid biopsy is considered minimally invasive and can provide key genetic and epigenetic information of the tumor.Abstract · Introduction · Peripheral Blood and... · Advances and Challenges of...
  120. [120]
    Serum neuron-specific enolase in children with neuroblastoma ...
    Serum NSE is a useful marker for patients with advanced neuroblastoma in whom elevated levels were associated with a poor outcome.Missing: brain | Show results with:brain
  121. [121]
    The use of amino acid PET and conventional MRI for monitoring of ...
    A simple semiquantitative regions-of-interest analysis for the calculation of tumor/brain ratios demonstrated a sensitivity and specificity of 70–80% (Terakawa ...
  122. [122]
    Diagnostic Accuracy of MR Spectroscopic Imaging and 18F-FET ...
    Oct 26, 2023 · This study compared the contribution of MR spectroscopic imaging (MRSI) and amino acid PET to improve the detection of tumor tissue.
  123. [123]
    Advances, technological innovations, and future prospects in ... - NIH
    Dec 6, 2022 · Complications following a brain biopsy are rare, but like all neurosurgical procedures, they carry some risks, such as seizures, brain edema ...Missing: definition | Show results with:definition
  124. [124]
    Novel application of robot-guided stereotactic technique on biopsy ...
    Jul 26, 2023 · Stereotactic biopsy is used to obtain tissue from intracranial lesions for pathological diagnosis and establishment of treatment strategies (2, ...
  125. [125]
    The safety, accuracy, and feasibility of robotic assistance in neuro ...
    Our study demonstrates the positive impact of the. ROSA system in neurosurgical procedures, particularly stereotactic biopsies and LITT. The system's ...
  126. [126]
    Intraoperative Real-Time MRI Guided Stereotactic Biopsy Followed ...
    Intraoperative MRI-guided stereotactic biopsy followed by laser ablation is safe and accurate by providing real time update and feedback during the procedures.
  127. [127]
    Real-time magnetic resonance imaging-guided frameless ...
    Oct 23, 2015 · The object of this study was to assess the feasibility, accuracy, and safety of real-time MRI-compatible frameless stereotactic brain biopsy.
  128. [128]
    guided biopsy in brain lesions: a systematic review and meta-analysis
    Aug 10, 2024 · 5-ALA and NaFl provide high diagnostic yields with acceptable safety profiles in stereotactic biopsies. NaFl showed higher sensitivity and specificity.
  129. [129]
    What is the Surgical Benefit of Utilizing 5-ALA for Fluorescence ...
    5-ALA FGS has enabled surgeons to achieve a significantly higher rate of complete resections of malignant gliomas as compared to conventional white-light ...
  130. [130]
    DEEP Surveillance of Brain Cancer Using Self-Functionalized 3D ...
    Sep 16, 2022 · We attempted a liquid biopsy-based deep surveillance of brain cancer using a very minimal amount of blood serum (5 μL) in real time.
  131. [131]
    Optimising trajectory planning for stereotactic brain tumour biopsy ...
    May 13, 2023 · This systematic review reveals the need for IDEAL-D Stage 1 research into automated trajectory planning for brain tumour biopsy.Missing: machine optimization
  132. [132]
    AI-Guided Optimal Trajectory Selection in Stereotactic Brain Biopsy
    Aug 10, 2025 · The imaging stage involves acquiring MRI and MRA data, while the planning stage automatically calculates the trajectory with the lowest risk ...<|control11|><|separator|>
  133. [133]
    Artificial Intelligence in Brain Tumour Surgery—An Emerging ...
    Oct 7, 2021 · AI-based workflow analysis has several proposed benefits including intraoperative optimisation of the surgical plan and trajectory, accurate ...
  134. [134]
    Study Details | NCT05318612 | Effectiveness of MR-guided LITT ...
    The aim of this study is to investigate the (cost-)effectiveness of LITT (Laser Interstitial Thermal Therapy) in primary irresectable glioblastoma.
  135. [135]
    Guideline Update Supports Laser Therapy for Brain Tumors After SRS
    Apr 2, 2025 · The REMASTer trial found that laser interstitial thermal therapy was equivalent to open craniotomy regarding OS and PFS data in progressive metastatic brain ...
  136. [136]
    Expedited chemoradiation after laser interstitial thermal therapy ...
    Feb 14, 2025 · Expedited chemoradiation after laser interstitial thermal therapy (LITT) is feasible and safe in patients with newly diagnosed glioblastoma.