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Brachial plexus block

A brachial plexus block is a regional anesthesia technique that involves injecting local anesthetics near the brachial plexus—a network of nerves formed by the ventral rami of spinal nerves C5 through T1—to provide sensory and motor blockade of the upper extremity, from the shoulder to the fingertips. This method offers a targeted alternative to general anesthesia for upper limb surgeries, enabling effective postoperative pain management while minimizing systemic side effects associated with opioids or full-body anesthesia. The brachial plexus originates from the lower cervical and upper thoracic spinal cord, forming roots that combine into trunks (upper, middle, and lower), divisions (anterior and posterior), cords (lateral, posterior, and medial), and terminal branches such as the musculocutaneous, median, ulnar, radial, and axillary nerves, all positioned in proximity to the subclavian and axillary arteries for anatomical targeting. Indications for brachial plexus blocks include procedures on the (e.g., rotator cuff repair), , , , and hand, with specific approaches selected based on the surgical site: interscalene for proximal procedures, supraclavicular for mid-upper coverage, infraclavicular for distal and , and axillary for hand and surgeries. Techniques have evolved with the integration of guidance since the early 2000s, which enhances precision by visualizing the and needle in , reducing complications compared to landmark-based or nerve stimulation methods. Common local anesthetics include bupivacaine (0.25–0.5%) or (0.5%), administered in volumes of 10–40 mL depending on the approach. While benefits include faster recovery and lower incidence of postoperative nausea, potential risks encompass nerve injury, local anesthetic systemic toxicity, vascular puncture, and site-specific complications such as paralysis with interscalene blocks or with supraclavicular approaches. Recent studies as of 2025 have explored liposomal bupivacaine to extend analgesia duration. Contraindications involve patient refusal, infection at the injection site, severe , or preexisting neuropathy, emphasizing the need for multidisciplinary evaluation by anesthesiologists, surgeons, and nursing staff to optimize outcomes.

Overview and Indications

Definition and Purpose

A is a regional technique that targets the —a network of nerves originating from the —to produce sensory and motor blockade of the upper extremity, effectively anesthetizing the arm from the shoulder to the fingertips. This method involves injecting local anesthetics near the brachial plexus to interrupt nerve conduction, providing targeted numbness and muscle relaxation without affecting other body regions. The primary purposes of brachial plexus block include delivering surgical for upper limb procedures, ensuring postoperative analgesia to manage after , and facilitating acute control in or chronic upper extremity conditions. By blocking nociceptive signals from the surgical site, it reduces the need for systemic opioids, thereby minimizing associated side effects like respiratory depression. Compared to general , brachial plexus block offers advantages such as avoidance of airway instrumentation and related complications, including intubation risks and postoperative . This makes it particularly suitable for patients with respiratory comorbidities, as it preserves spontaneous ventilation and hemodynamic stability.

Clinical Indications

Brachial plexus blocks are primarily indicated for providing and analgesia during surgical procedures involving the upper extremity, encompassing surgeries on the , , , , and hand. Common examples include repair, arthroscopy, fixation, arthroscopy, fracture reduction, fracture repair, and hand procedures such as release or repairs. These blocks enable effective regional tailored to the surgical site, with the choice of approach depending on the dermatomal coverage required. Beyond surgical anesthesia, brachial plexus blocks serve as a key modality in acute following , such as fractures or injuries, where they provide targeted analgesia to facilitate early mobilization and reduce requirements. They are also employed for conditions, notably (CRPS) type I of the upper extremity, with continuous infusions demonstrating sustained symptom relief and functional improvement in refractory cases. These blocks offer distinct advantages in outpatient settings for procedures typically lasting 2-3 hours, supporting rapid , same-day , and enhanced patient satisfaction compared to general . In patients with respiratory comorbidities, such as or , blocks—particularly supraclavicular or infraclavicular approaches—are preferred to avoid the ventilatory risks associated with general , thereby improving profiles in high-risk populations.

Contraindications

Brachial plexus blocks, like other regional anesthesia techniques, have well-defined absolute contraindications that preclude their performance to avoid significant harm. These include patient refusal, as is essential for any invasive procedure. Local at the injection site is another absolute contraindication, as it risks disseminating into deeper tissues or the bloodstream. Confirmed to local anesthetics also prohibits the block, due to the potential for severe anaphylactic reactions. Severe represents an absolute barrier, given the heightened risk of uncontrollable bleeding from needle insertion into vascular structures. Relative contraindications warrant careful risk-benefit assessment and may allow the procedure with modifications or alternatives. Preexisting neuropathy in the affected limb is a relative contraindication, as it may exacerbate or complicate postoperative neurologic . Uncooperative patients pose challenges in maintaining positioning and , increasing procedural risks. Active bleeding disorders, while not always absolute, require to mitigate formation. Patients on anticoagulation therapy require special consideration per American Society of Regional Anesthesia and Pain Medicine (ASRA) guidelines, which differentiate peripheral nerve blocks like blocks from higher-risk neuraxial procedures. For deep plexus blocks (e.g., interscalene or supraclavicular approaches), ASRA recommends discontinuing certain direct oral anticoagulants, such as high-dose , at least 72 hours prior to the procedure in patients with normal renal function, to reduce bleeding risk. Superficial blocks (e.g., axillary) generally permit continuation of therapy with minimal interruption, emphasizing the need for individualized assessment based on agent, dose, and block depth. Bilateral brachial plexus blocks are relatively contraindicated due to the cumulative risks of local anesthetic systemic toxicity from higher total doses and potential phrenic nerve involvement leading to bilateral diaphragmatic paralysis, which can compromise respiratory function in vulnerable patients.

Anatomy of the Brachial Plexus

Structure and Components

The is a of nerves formed by the anterior rami (ventral ) of the spinal nerves through T1, originating from the ventral rami in the interscalene groove between the anterior and middle in the . These five emerge from the and combine to form three trunks: the superior trunk arises from the union of and , the middle trunk from the alone, and the inferior trunk from the C8 and T1 . This initial formation occurs within the , proximal to the . Distal to the trunks, each of the three trunks divides into anterior and posterior divisions, yielding six divisions in total (three anterior and three posterior), which occurs behind the middle third of the . These divisions then rearrange in the infraclavicular region to form three cords named relative to their position around the second part of the : the derives from the anterior divisions of the superior and middle trunks (C5-C7), the medial cord from the anterior division of the inferior trunk (C8-T1), and the from the posterior divisions of all three trunks (C5-T1). The cords travel through the , enveloped in . The cords give rise to five major terminal branches that provide the primary motor and sensory innervation to the : the (from the , C5-C7), which innervates anterior muscles and provides sensory supply to the lateral ; the (from lateral and medial cords, C6-T1), supplying flexors, thenar muscles, and sensation to the lateral palm and digits 1-3; the (from the medial cord, C8-T1), innervating hypothenar and interossei muscles with sensory coverage of the medial hand and digits 4-5; the (from the , C5-T1), providing motor supply to posterior and extensors and sensory innervation to the posterior , , and dorsal digits 1-3; and the (from the , C5-C6), innervating the deltoid and teres minor muscles with sensory supply to the lateral . Collectively, these branches ensure comprehensive motor control of muscles from the to the intrinsic hand muscles and sensory innervation of from the to the hand, excluding the and medial upper (supplied separately). Anatomical variations in brachial plexus formation occur in a significant portion of the , with prefixed plexuses (involving a contribution from and reduced T1 input) reported in approximately 11% of cases and postfixed plexuses (with increased C8 and a contribution) in about 1%. These variants can alter the relative positions of roots and trunks but typically do not affect overall function. The blood supply to the primarily derives from branches of the , including the ascending and deep arteries for the roots and trunks, and the subscapular and arteries for the cords and branches. Additionally, the plexus is invested by a fascial , an extension of the prevertebral that forms a multicompartmental fibrous envelope from the interscalene region through the , containing that surrounds the nerves and axillary vessels.

Relevant Anatomical Landmarks

The interscalene approach to the brachial plexus block relies on key surface landmarks including the upper border of the , the posterior border of the , and the to identify the interscalene groove between the anterior and middle . The needle insertion site is typically located at the level of the , just posterior to the , allowing access to the upper trunk of the plexus at approximately the vertebral level. This approach places the injection site in close proximity to the , which courses along the anterior scalene muscle and can result in a high incidence of ipsilateral diaphragmatic . For the supraclavicular approach, the midpoint of the serves as a primary landmark, with needle insertion directed superiorly into the , approximately 1-2 cm above the and lateral to the insertion. The palpable pulse of the , located in the deltopectoral groove just lateral to the sternocleidomastoid tendon, guides the needle trajectory toward the trunks and divisions of the as they cross over the first rib. Vital structures in proximity include the , which lies anterior to the lower trunk and risks vascular puncture, and the pleura, situated medial to the anterior scalene muscle, with potential for if the needle advances too medially. The infraclavicular approach utilizes the as a central bony , palpated just below the lateral third of the , with needle entry points typically 1-2 cm medial and inferior to this structure to target the cords surrounding the . The deltopectoral groove, formed by the medial border of the deltoid and the lateral border of the , helps orient the needle parallel to a line from the mid- to the in certain techniques. Proximity to vital structures involves the and vein within 2 cm of the cords, as well as the pleural dome, which can be as close as 10 mm to the needle path based on imaging studies. In the axillary approach, the pulse is the dominant landmark, palpated in the at the level of the muscle to encircle the where the terminal branches of the lie. The biceps tendon, located within the biceps brachii muscle, serves as a reference for targeting the separately, often by directing the needle superior to the artery. Additional pulse points along the guide circumferential injections around the vascular sheath, with close adjacency to the increasing the risk of vascular complications in this highly vascular region.

Techniques

Interscalene Block

The interscalene block is a regional technique that targets the roots at the level of the in the , providing effective analgesia for surgeries involving the and proximal upper . It is primarily indicated for procedures such as , repair, and reduction, where comprehensive coverage of the C5-C6 dermatomes is essential. This approach is particularly advantageous for outpatient surgeries due to its reliable blockade of the upper trunk, though it is less suitable for distal procedures owing to potential sparing of the lower trunk. Patient positioning for the interscalene block typically involves placing the individual or semi-recumbent, with the head turned 30-45 degrees toward the contralateral side to optimize access to the . The entails identifying the interscalene groove—located between the anterior and middle at the vertebral level, often aligned with the —using landmarks or guidance. A 22-gauge, 50-mm needle is then advanced in-plane from a posterior or lateral approach, depositing local around the roots once the appropriate plane is confirmed. Local anesthetic volumes of 20-30 mL, typically using long-acting agents like 0.5% or bupivacaine, are commonly administered to achieve surgical . Onset of sensory and motor occurs within 10-20 minutes, with durations extending 8-18 hours depending on the agent and adjuncts, providing prolonged postoperative analgesia. A notable characteristic is the near-100% incidence of ipsilateral with standard volumes, leading to temporary hemidiaphragmatic paralysis and a 20-25% reduction in pulmonary function, which is generally well-tolerated in healthy patients but requires caution in those with respiratory compromise. Additionally, the block often spares sensation in the distal and hand due to incomplete of the C8-T1 roots forming the inferior trunk. Recent studies have highlighted anatomical variations in root positioning that influence success and side effects. For instance, a 2025 investigation compared extrafascial (needle tip lateral to the sheath, equidistant from and roots) versus intrafascial (needle within the , between and ) approaches at the C5-C7 level, revealing 100% efficacy in both but a higher rate of hemidiaphragmatic (100% vs. 85.7%) and hemodynamic instability in the intrafascial group. These findings underscore the importance of visualization to account for individual variations in root alignment between the , potentially improving outcomes by minimizing unintended nerve involvement.

Supraclavicular Block

The supraclavicular block is a regional technique that targets the at the level of its trunks and divisions, just lateral to the in the . It provides reliable sensory and motor blockade for surgeries involving the , , , and hand, such as reductions, repairs, and releases. This approach is particularly suitable for mid-to-distal upper extremity procedures due to its high success rate and ability to achieve from the mid-humerus distally. The patient is positioned with the arm at the side and the head turned away from the block side to optimize access to the . A high-frequency linear probe is placed transversely in the , posterior to the clavicular head of the , to visualize the hyperechoic cluster adjacent to the and first rib. The needle entry point is typically 1-2 cm above the midpoint of the , with a 22-gauge, 50-mm block needle advanced in-plane from lateral to medial toward the center of the , ensuring the tip remains superficial to the pleura. Local anesthetic is injected incrementally after negative , hydrodissecting the around the until circumferential spread is observed. Typically, 20-40 mL of local anesthetic, such as 0.5% or lidocaine 1.5% with epinephrine, is administered to achieve a complete blockade, encompassing dermatomes from to T1. The block exhibits rapid onset, with sensory and motor effects beginning within 5-15 minutes, attributed to the compact arrangement of nerve trunks at this level. Historically, the supraclavicular approach carried a 1-3% risk of due to proximity to the pleural dome, but guidance has substantially reduced this to near zero in large cohorts, reduced to 0.06% (2 cases in 3403 supraclavicular blocks) with guidance, as reported in a 2014 multicenter study of 6366 periclavicular blocks. Other potential complications include vascular puncture and transient paresis, though these are minimized with real-time imaging. Recent analyses from 2025 indicate that supraclavicular blocks yield similar long-term pain relief and functional outcomes to axillary blocks for distal upper extremity surgeries, but with faster onset times enabling quicker surgical readiness.

Infraclavicular Block

The infraclavicular block is a regional technique that targets the at the level of its cords, providing effective analgesia and anesthesia for distal upper extremity procedures, including hand and surgeries. This approach is particularly advantageous for placements of continuous perineural , as the compact arrangement of the cords around the facilitates reliable local anesthetic spread, while the overlying help secure the against dislodgement. For the procedure, the patient is placed in the with the head turned away from the side being blocked, the abducted to 90 degrees, and the flexed to elevate the and enhance acoustic windows. guidance is standard, with the linear probe positioned in the to visualize the hyperechoic cords encircling the in a clock-face configuration (lateral at 9 o'clock, posterior at 7 o'clock, and medial at 5 o'clock). The needle is inserted in-plane from the cephalad edge of the probe, advanced 4-6 cm below the toward the , and directed posteriorly to the to deposit local in a U-shaped distribution around the vascular , confirming cord separation on . Typically, 20-40 mL of local anesthetic is administered in incremental doses, with sensory and motor onset achieved in 10-20 minutes. Block duration is similar to that of the supraclavicular approach, generally lasting 12-24 hours with long-acting agents like bupivacaine, supporting extended postoperative analgesia via . Phrenic nerve involvement, which can lead to hemidiaphragmatic , occurs in fewer than 10% of cases, substantially lower than in more proximal blocks. However, the proximity to the elevates the risk of vascular puncture compared to other approaches. Recent protocols, including dynamic imaging of cord separation, have further minimized these risks while improving success rates to over 95%. Relative to the supraclavicular block, the infraclavicular technique provides superior access for continuous maintenance and reduced risk but may require supplemental intercostobrachial blockade for complete medial arm coverage. Unlike the axillary block, which focuses on terminal branches, the infraclavicular approach engages the cords pre-axillary for more uniform initial distribution across the .

Axillary Block

The axillary block targets the at the level of its terminal branches in the , providing effective for surgeries of the hand and while sparing the and proximal . This approach is particularly suitable for isolated distal upper extremity procedures, such as repairs or finger amputations, as it reliably blocks the , ulnar, and radial nerves without proximal spread that could affect function. The patient is positioned with the arm abducted to 90 degrees and the flexed or supported to facilitate access to the . Under guidance or , a needle is advanced in the short-axis view around the to deposit local in a perivascular manner or via multiple injections targeting individual terminal branches. For a single-injection , volumes of 30-50 mL of local are typically used, while multiple-injection approaches require less overall volume, often 5-10 mL per . Onset of surgical occurs within 10-30 minutes, though complete sensory and motor blockade may take longer with single injections. Due to the musculocutaneous 's position outside the axillary sheath, supplemental blockade of this —often with 3-5 mL in the coracobrachialis muscle—is frequently necessary for full coverage of the lateral . Among brachial plexus block approaches, the axillary technique offers the lowest risk profile, with minimal potential for phrenic nerve involvement or pneumothorax, making it ideal for beginners learning regional anesthesia. Its distal location and compressible vessels further reduce complication risks compared to more proximal methods. Recent 2025 studies have examined optimized axillary block applications for elbow surgeries, including volume comparisons (20 mL vs. 30 mL) in below-elbow procedures and extensions to biceps tendon repairs, demonstrating reliable anesthesia with multiple or perivascular injections.

Methods of Nerve Localization

Ultrasound Guidance

Ultrasound guidance facilitates real-time visualization of the , adjacent vessels, and the needle trajectory during brachial plexus blocks, enhancing precision and safety. A high-frequency linear , typically operating at 10-15 MHz, is employed to image superficial structures such as the brachial plexus roots and trunks due to its superior resolution for depths up to 4-5 cm. This approach allows direct confirmation of local anesthetic spread around the target nerves, minimizing unintended injections. Procedural steps begin with patient positioning supine and the neck slightly extended for optimal access, followed by sterile preparation of the skin and ultrasound probe. For the interscalene approach, the probe is placed transversely at the level of the cricoid cartilage to identify the hypoechoic brachial plexus roots nestled between the anterior and middle scalene muscles, appearing as round or oval structures lateral to the carotid artery and internal jugular vein. Probe placement varies by technique—for instance, in the supraclavicular approach, it is positioned in the supraclavicular fossa parallel to the clavicle to visualize the plexus as a cluster of hypoechoic bundles superior to the subclavian artery. The needle is then advanced using either an in-plane technique, where the entire needle path is visualized within the ultrasound plane for continuous monitoring, or an out-of-plane technique, which inserts the needle perpendicular to the probe for shorter distances but requires dynamic tilting to track the tip. Local anesthetic is injected incrementally while observing circumferential spread around the nerves in real time. Key benefits of ultrasound guidance include a higher , shorter block performance time, and reduced need for needle redirections compared to traditional methods. It significantly lowers the risk of complications such as vascular puncture and , with studies reporting near-elimination of symptomatic in supraclavicular and infraclavicular blocks due to direct avoidance of the pleura. Additionally, ultrasound enables faster sensory block onset and use of lower local anesthetic volumes—often 20-30% less—while maintaining efficacy, thereby decreasing systemic toxicity risks. Unlike nerve stimulation, which depends on elicited motor responses, ultrasound offers visual precision across all approaches. Recent reviews from 2025 highlight the importance of standardized reporting in ultrasound-guided blocks to improve benchmarking, noting inconsistencies in terminology and underreporting of minor events like transient irritation despite overall low complication rates (approximately 4.5% in the aggregated data from the ). Effective implementation requires equipment setup including an machine with a sterile probe cover, conductive gel, a 50-100 mm 22-gauge block needle, and a for local , all arranged ergonomically to minimize . Training entails comprehensive education in anatomy, physics, and hands-on simulation, with proficiency typically achieved after 15-50 supervised procedures depending on prior regional anesthesia experience. Regular practice and certification in -guided regional anesthesia are recommended to ensure consistent outcomes.

Nerve Stimulation

Nerve stimulation involves the use of a peripheral nerve stimulator (PNS) to deliver low-intensity electrical impulses through an insulated needle, eliciting motor responses that indicate proximity to the target nerves of the brachial plexus. The device is typically set with an initial current of 0.5-1 mA, a pulse width of 0.1 ms, and a frequency of 2 Hz to produce visible muscle twitches without causing discomfort to the patient. The insulated needle, with its tip exposed for focused stimulation, is advanced toward the brachial plexus while connected to the negative pole of the stimulator, allowing the operator to adjust the needle trajectory based on the evoked responses. The endpoint of nerve stimulation is achieved when a minimal motor twitch is elicited at a current of 0.3-0.5 mA, confirming close needle-to-nerve proximity without direct intraneural placement. For example, in interscalene blocks, a deltoid muscle contraction serves as a reliable indicator of successful localization to the upper trunk, while in axillary blocks, flexion of the fingers signals engagement of the median or ulnar nerves. This electrophysiological feedback provides indirect confirmation of the needle tip's position relative to the nerve structure. Nerve stimulation offers advantages in low-resource settings due to its lower cost and portability compared to equipment, while also serving as a reliable to verify needle tip location and reduce the risk of intravascular injection. However, it has limitations, including the potential for false positives from direct muscle stimulation, which can mimic responses and lead to suboptimal block placement, and it is generally less precise than guidance for visualizing anatomy. Although has emerged as the primary modern method for localization, can be integrated with it in a hybrid approach to enhance accuracy by combining visual confirmation with motor response verification.

Local Anesthetics and

Types of Local Anesthetics

Local anesthetics used in blocks are classified into two main chemical groups: amides and esters, distinguished by their intermediate chain linking the aromatic and amine components. Amides, including lidocaine, bupivacaine, and , are more commonly employed due to their stability and lower risk of allergic reactions compared to esters. Esters, such as , are rapidly metabolized by esterases but are less frequently used in prolonged blocks owing to their short . Among amides, lidocaine provides short-acting anesthesia with an onset of 10-20 minutes and duration of 2-5 hours in peripheral blocks, making it suitable for shorter procedures. Bupivacaine offers long-acting effects, with an onset of 15-30 minutes and duration of 5-15 hours, attributed to its high lipid solubility and protein binding. serves as a less cardiotoxic alternative to bupivacaine, featuring similar onset (15-30 minutes) and duration profiles (4-12 hours) while producing reduced motor blockade due to its stereospecific S(-) structure. For esters, delivers ultra-short action with rapid onset (6-12 minutes) and duration of 0.5-1 hour, ideal for ambulatory settings where quick recovery is prioritized. Potency rankings among these agents follow lipid solubility: bupivacaine exhibits the highest potency, followed by , then lidocaine. Onset is inversely related to values, with lidocaine ( 7.8) achieving the fastest block initiation, while duration correlates with protein binding, longest for bupivacaine (95%). These properties guide agent selection based on procedural needs, balancing speed, longevity, and safety. Additives enhance the clinical profile of local anesthetics in blocks. Epinephrine, added at concentrations of 1:200,000 to 1:400,000, induces to prolong block duration by 30-50% through reduced vascular uptake. Dexamethasone, typically at 4-8 mg perineurally, extends analgesia duration by up to 50% via anti-inflammatory mechanisms, improving postoperative pain control without significant hemodynamic effects. As of 2025, emerging formulations include liposomal bupivacaine, which provides prolonged release for extended analgesia in blocks, with low-level evidence indicating reduced pain intensity after compared to standard bupivacaine.
AgentClassOnset (min)Duration (hours)Potency (Relative)
LidocaineAmide10-202-5Moderate
BupivacaineAmide15-305-15High
Amide15-304-12High
Ester6-120.5-1Low
As of 2025, research emphasizes low-volume high-concentration formulations, such as 10 mL of 0.5% , which maintain block efficacy while minimizing complications like hemidiaphragmatic paralysis in interscalene approaches. These strategies, supported by guidance, optimize safety without compromising sensory or motor blockade.

Dosing and Administration

Dosing for blocks must adhere to maximum recommended limits to minimize the risk of local anesthetic systemic toxicity (LAST), with lidocaine limited to 4.5 mg/kg without epinephrine and 7 mg/kg with epinephrine, bupivacaine to 2-3 mg/kg, and to 3 mg/kg. These thresholds are calculated based on weight and account for the total dose across all sites if multiple blocks are performed. For blocks, typical volumes range from 20-50 mL of local solution, depending on the specific approach and desired spread within the plexus sheath. Continuous techniques involve an initial bolus of 20-40 mL followed by infusion rates of 5-10 mL/h, often using dilute solutions to provide prolonged analgesia while limiting cumulative exposure. Common concentrations include 0.5% or bupivacaine for surgical in single-shot applications, providing dense blockade for 8-24 hours, while postoperative infusions typically use 0.2% solutions to balance analgesia and motor function. Additives such as epinephrine (5 mcg/mL) may be incorporated to prolong duration and reduce vascular uptake, but without exceeding overall dose limits. Dosing is influenced by patient weight, the targeted block site (e.g., higher volumes for axillary approaches), procedure duration, and adjuncts like dexamethasone, which can extend block effects without altering primary anesthetic volume. Obese patients may require adjustments based on ideal body weight to avoid overdose. Monitoring for LAST involves continuous assessment of vital signs, level of consciousness, and electrocardiogram during and after injection, with ultrasound guidance reducing intravascular injection risk and early toxicity onset. If symptoms such as perioral numbness or seizures occur, immediate cessation of infusion and supportive care per ASRA protocols are essential.

Special Situations

Pediatric Applications

Brachial plexus blocks are frequently indicated for surgeries in pediatric patients, particularly those involving such as requiring closed reduction or open repair, with common application in children aged 1 to 16 years. The supraclavicular approach is often preferred in this population for its comprehensive coverage of the and relative ease in achieving patient during . These indications align with the need for targeted in procedures like repair or fixation, where regional techniques minimize systemic exposure. Dosing regimens for pediatric brachial plexus blocks emphasize reduced volumes and concentrations to account for lower body weight and heightened sensitivity to local anesthetics. Typically, volumes of 0.15 to 0.2 mL/kg of 0.2% are administered, yielding doses of approximately 0.3 to 0.4 mg/kg, which balance efficacy with safety in children aged 1 to 6 years. Higher concentrations, such as 0.25%, may be used sparingly for older children, but lower options like 0.2% are prioritized to limit risks while ensuring adequate sensory and motor . Techniques for performing blocks in children rely heavily on guidance to navigate smaller anatomical structures and enhance precision. Landmarks are adjusted accordingly, such as using high-frequency probes (>13 MHz) for superficial visualization and in-plane needling to maintain continuous needle tracking, with the axillary approach favored for its straightforward access and lower risk profile in cooperative patients. The supraclavicular method involves positioning the patient with a roll to optimize probe placement parallel to the , while infraclavicular blocks serve as alternatives when the supraclavicular site is inaccessible. These blocks offer significant benefits in pediatric care by avoiding general anesthesia risks, such as respiratory depression and hemodynamic instability, while providing prolonged postoperative analgesia that reduces requirements and shortens hospital stays. Studies from 2016 to 2020, including large cohorts, report success rates exceeding 94% with guidance, demonstrating safety and efficacy across supraclavicular and infraclavicular approaches in upper extremity procedures. Challenges in pediatric applications include limited patient cooperation, especially in children under 6 years, often necessitating or general for block placement, and anatomical variations like the brachial plexus's proximity to the pleura, which heightens risk. Additionally, variations in nerve positioning, such as the appearing as dual structures, require vigilant monitoring to prevent incomplete blocks or complications. Despite these hurdles, the techniques' adaptability contributes to low complication rates when performed by experienced practitioners.

Use in Obese Patients

Performing blocks in obese patients presents several challenges, primarily due to anatomical alterations such as landmark distortion from excess , which complicates identification of key structures like the or . Difficult patient positioning, often exacerbated by limited mobility and respiratory constraints, further prolongs setup time and increases procedural complexity. Additionally, obese individuals face a heightened risk of local anesthetic systemic toxicity (LAST) stemming from dosing errors, as standard total body weight-based calculations can lead to excessive anesthetic administration; guidelines recommend dosing based on or lean body weight to mitigate this. Preferred approaches for obese patients include the infraclavicular and axillary blocks under guidance, as these sites offer more accessible landmarks—the and remain palpable despite subcutaneous fat accumulation—and minimize the need for neck extension. Recent studies from 2023 to 2024, including a secondary analysis of a , demonstrate that these ultrasound-guided techniques achieve comparable efficacy to non-obese cohorts, though procedure times are extended by approximately 2 minutes due to imaging and needling difficulties. Technical adjustments are essential for success in patients with BMI greater than 30, such as using lower-frequency transducers (e.g., 5-10 MHz) for better penetration through and improve visualization of deeper neural structures. identification should incorporate BMI-specific adaptations, like relying on the deltopectoral groove for infraclavicular access, while using reduced local anesthetic volumes (e.g., 20-30 mL total) to align with dosing limits that prevent LAST. guidance, as detailed in established methods, facilitates these modifications by providing real-time imaging to confirm needle trajectory. A key benefit of brachial plexus blocks in obese patients is the avoidance of general anesthesia-related issues, such as difficult and challenges, thereby reducing respiratory complications. With guidance, success rates of 94-100% have been reported, enabling effective analgesia without supplemental opioids in most cases. Secondary analyses indicate that does not significantly prolong block duration or impair overall analgesia quality, with equivalent postoperative control and satisfaction scores (around 9/10) compared to non-obese individuals, supporting the technique's reliability across body types.

Complications and Management

Common Complications

Brachial plexus blocks, while effective for regional , are associated with several common complications arising from anatomical proximity to critical structures and the pharmacologic effects of local anesthetics. represents one of the primary concerns, with an incidence of approximately 0.02–0.04% for persistent neurological deficits in ultrasound-guided blocks, typically presenting as or neuropraxia resulting from direct needle trauma, intraneural injection, or compression by formation. These injuries are often transient, resolving within weeks to months, but can occasionally lead to longer-term dysfunction, particularly in proximal approaches like interscalene blocks where the incidence of transient postoperative neurological symptoms may reach up to 5.5% of reported adverse events. Vascular puncture is another frequent , occurring in 1-5% of cases depending on the approach and operator experience, most notably in supraclavicular blocks due to the proximity of the . This complication can result in formation, potentially exacerbating nerve compression or requiring intervention if significant bleeding occurs. Ultrasound guidance has reduced the rate compared to techniques, with reported incidences dropping to as low as 3% after initial learning curves in axillary approaches. Phrenic nerve blockade is nearly universal in traditional interscalene approaches using 20–40 mL volumes, affecting up to 100% of patients and leading to ipsilateral hemidiaphragmatic paralysis with transient dyspnea, particularly in those with underlying pulmonary compromise; however, low-volume (5–10 mL) ultrasound-guided techniques reduce incidence to 0–50%. In contrast, the incidence is substantially lower (<20%) in supraclavicular or infraclavicular blocks, where the phrenic nerve is less involved, though hemidiaphragmatic paresis still accounts for nearly half of reported adverse events across all brachial plexus blocks. Pneumothorax, a serious respiratory complication, is primarily linked to supraclavicular blocks but occurs infrequently (<1%) with ultrasound guidance, with prospective data indicating rates as low as 0.06% in large cohorts. Horner syndrome, characterized by ptosis, miosis, and anhidrosis, arises from sympathetic chain involvement and affects 20-80% of interscalene block patients, though recent scoping reviews report around 21% incidence in adverse event cohorts, with higher rates (up to 29%) in supraclavicular approaches compared to distal sites like axillary (lower due to anatomical separation). Local anesthetic systemic toxicity (LAST) remains a critical risk across all approaches, manifesting as seizures or cardiac arrest from inadvertent intravascular injection or overdose, with an overall incidence of approximately 1-2 per 1,000 peripheral nerve blocks in orthopedic settings; 2025 registry data from over 26,000 blocks confirm persistently low rates (<1% of adverse events), though proximal blocks like supraclavicular show slightly higher odds than axillary due to larger anesthetic volumes.

Prevention and Treatment

Prevention of complications during brachial plexus block begins with the use of ultrasound guidance, which enhances visualization of anatomical structures, reduces the risk of inadvertent vascular or neural puncture, and allows for real-time needle adjustment to optimize safety. Incremental injection of local anesthetics, administered in small aliquots with pauses to assess for early signs of toxicity or incorrect placement, further minimizes the potential for systemic absorption or nerve trauma. Routine aspiration prior to each injection confirms the absence of intravascular placement, serving as a critical safeguard against unintended vascular injection. Additionally, preparing 20% lipid emulsion in advance ensures immediate availability for potential local anesthetic systemic toxicity (LAST), aligning with standard protocols that emphasize proactive resuscitation readiness. Treatment strategies for complications are tailored to the specific issue identified. For nerve injury, initial management involves close observation to allow spontaneous resolution, as most cases are transient neuropraxias; if inflammatory neuritis is suspected based on clinical presentation, corticosteroids may be administered to reduce edema and inflammation. Symptomatic pneumothorax requires prompt intervention with chest tube insertion to re-expand the lung and alleviate respiratory compromise, guided by clinical symptoms such as dyspnea or hypoxia. For LAST, the cornerstone of therapy is intravenous 20% lipid emulsion, starting with a bolus of 1.5 mL/kg over 2-3 minutes, followed by an infusion at 0.25 mL/kg/min until hemodynamic stability is achieved, alongside supportive measures like airway management and seizure control. Post-block monitoring is essential to detect early complications and ensure patient safety. Continuous assessment of vital signs, including blood pressure, heart rate, and respiratory rate, alongside pulse oximetry for oxygen saturation, allows for rapid identification of systemic effects or respiratory depression. Neurologic checks, such as sensory and motor function evaluation in the blocked extremity, should be performed at regular intervals to monitor for evolving deficits or incomplete resolution of the block. Adverse event reporting plays a key role in quality improvement for regional anesthesia practices. Follow-up protocols for persistent symptoms post-block typically include outpatient evaluation at 1-2 weeks, with electromyography if deficits endure beyond this period, and extended monitoring up to 4 weeks or longer to track resolution and guide rehabilitation if needed.

Alternatives

Other Regional Anesthesia Techniques

Peripheral nerve blocks targeting individual nerves of the upper extremity, such as median, ulnar, and radial nerve blocks at the wrist or forearm, serve as alternatives to for distal procedures like hand surgery. These distal blocks provide targeted anesthesia to specific dermatomes without affecting the proximal arm, reducing the volume of local anesthetic required and minimizing risks associated with proximal injections. For instance, a combination of median and ulnar nerve blocks at the wrist can effectively anesthetize the palm and fingers for carpal tunnel release or minor hand repairs. Cervical plexus blocks offer anesthesia for surgeries extending to the neck or proximal shoulder, complementing or substituting approaches when broader superficial coverage is needed. The superficial cervical plexus block targets sensory branches from C2-C4, providing analgesia to the lateral neck, clavicle, and upper shoulder without deep motor blockade. This technique is particularly useful for clavicle fracture repairs or lymph node biopsies, where interscalene blocks alone may insufficiently cover supraclavicular areas. Neuraxial techniques, such as cervical epidural anesthesia, provide extensive coverage for upper extremity surgeries requiring bilateral or multilevel analgesia, though they carry higher risks than peripheral blocks. Cervical epidurals allow for continuous infusion of local anesthetics, enabling prolonged postoperative pain control across multiple dermatomes from the cervical spine. However, they are associated with potential systemic effects like hypotension and require advanced monitoring due to the proximity to the brainstem. Intravenous regional anesthesia, commonly known as the Bier block, is a simpler alternative for short-duration hand and wrist procedures lasting less than 1 hour, involving exsanguination of the limb followed by intravenous injection of local anesthetic proximal to a tourniquet. Compared to brachial plexus blocks, the Bier block offers faster onset and setup time, making it suitable for ambulatory settings, but it is limited by tourniquet-induced pain after 30-45 minutes and lacks postoperative analgesia once the cuff is deflated. In comparisons, individual peripheral nerve blocks provide more selective anesthesia than brachial plexus blocks, avoiding phrenic nerve involvement but potentially requiring multiple injections for comprehensive coverage. Cervical epidurals excel in continuous delivery for extended surgeries but introduce risks of epidural hematoma or infection not seen in peripheral techniques. The Bier block's simplicity contrasts with brachial plexus blocks' superior duration and quality of analgesia, though the former avoids nerve stimulation or ultrasound guidance. Recent 2025 studies have evaluated nerve blocks against hematoma blocks—local anesthetic infiltration directly into the fracture site—for closed reduction of distal radius fractures. A randomized study found nerve blocks achieved higher success rates in fracture realignment (62% vs. 40%) and reduced the need for subsequent surgery (52% vs. 66%) compared to hematoma blocks, attributed to better muscle relaxation and pain control. Another randomized study confirmed ultrasound-guided peripheral nerve blocks (median and radial) provided more reliable anesthesia than hematoma blocks, with lower rates of procedural failure in emergency settings.

General Anesthesia Options

General anesthesia serves as an alternative to brachial plexus block for upper extremity procedures when regional techniques are unsuitable or impractical. Key indications include contraindications to the block, such as patient refusal, allergy to local anesthetics, active infection at the injection site, coagulopathy or therapeutic anticoagulation, and preexisting neurological deficits in the limb that could complicate assessment or increase injury risk. Additionally, GA is preferred for uncooperative patients, including young children or individuals with severe anxiety or cognitive impairment who cannot tolerate the block procedure, situations demanding rapid onset of unconsciousness such as trauma emergencies with multiple fractures, and bilateral upper extremity surgeries where bilateral blocks risk systemic local anesthetic toxicity from excessive dosing. Techniques for administering GA in upper extremity surgery align with standard practices for non-cardiac procedures, emphasizing rapid induction and secure airway management to accommodate varying surgical durations. Intravenous induction typically involves (1.5-2.5 mg/kg) combined with opioids like fentanyl for analgesia and a muscle relaxant such as rocuronium for intubation, while inhalational induction with sevoflurane is favored in pediatrics to avoid vascular access challenges. Airway securing options include endotracheal intubation for prolonged cases (>1 hour) or those with potential for , providing definitive protection, or a supraglottic device like the (LMA) for shorter surgeries, which supports spontaneous ventilation and expedites emergence. Maintenance employs volatile agents (e.g., for faster recovery) or total intravenous with infusions, tailored to patient comorbidities. GA carries distinct risks that must be weighed against regional alternatives, particularly in outpatient settings. Postoperative nausea and vomiting (PONV) affects about 30% of patients, driven by volatile anesthetics and opioids, leading to delayed discharge and patient discomfort. Airway complications, including , from residual effects, or difficult extubation, occur in 1-5% of cases and can prolong recovery. Postoperative or cognitive dysfunction is more common in older adults (up to 10-15% incidence), exacerbated by anesthetics and surgical stress. These risks are amplified in obese patients due to challenging and higher aspiration potential, and in pediatric populations from increased anesthetic sensitivity and airway reactivity. Combining with brachial plexus block offers a strategy for enhanced analgesia and reduced systemic exposure. The block provides targeted sensory blockade, allowing lighter depths, lower volatile agent concentrations, and minimized requirements—often cutting intraoperative by 50% or more—while ensuring hemodynamic stability and superior postoperative pain control. This approach is particularly beneficial for complex or longer procedures, where the block supplements without full reliance on either. Clinical evidence supports blocks as a means to reduce GA needs in surgery. Successful blocks enable standalone regional or sedation-only supplementation in 80-95% of cases, avoiding full GA and its associated recovery delays; overall, regional techniques improve throughput and patient satisfaction compared to GA.

History and Advances

Early Development

The early development of brachial plexus blockade began in the late 19th century with the pioneering use of for peripheral nerve blocks. In 1884, surgeons William Halsted and Richard Hall conducted clinical trials injecting 4% cocaine solutions directly into the to achieve sensory blockade in the upper extremity, marking one of the first documented applications of local anesthetics for regional in this area. This approach targeted branches of the such as the ulnar and musculocutaneous nerves, demonstrating effective but limited by cocaine's toxicity and addictive potential. By the early , percutaneous techniques emerged to access the more safely. In 1911, Georg Hirschel described the first axillary approach, injecting local anesthetic blindly into the to block the distally, which provided reliable anesthesia for hand and forearm procedures with reduced risk to proximal structures. Concurrently, Diedrich Kulenkampff introduced the supraclavicular method that same year, approaching the plexus at the level of the trunks between the , offering rapid onset for upper arm anesthesia. During the and , Gaston Labat advanced these techniques through standardization in his 1921 textbook Regional Anesthesia, refining supraclavicular and related approaches like the parascalene to improve reliability and safety for surgical applications. Initial methods relied on paresthesia elicitation for nerve localization, where needle advancement provoked a tingling sensation to confirm proximity to the plexus, but this carried significant risks. Early supraclavicular blocks, for instance, reported pneumothorax rates as high as 6.1% due to pleural proximity, alongside vascular punctures and incomplete blocks, limiting widespread until procedural refinements. The introduction of synthetic local anesthetics addressed some limitations of and esters like ; lidocaine, developed by Nils Löfgren, was first clinically used in 1948 for nerve blocks, providing faster onset, greater stability, and lower toxicity, which facilitated broader application of blockade into the mid-20th century.

Modern Innovations

In the 1960s and 1970s, peripheral stimulators were introduced for blocks, building on early electrical stimulation principles to improve localization accuracy during regional anesthesia. This innovation, exemplified by the Block-Aid monitor described in 1969, allowed clinicians to elicit muscle twitches at low current thresholds, enhancing block success rates compared to paresthesia-based techniques. By the , widespread adoption of these devices reduced procedural variability and complications, marking a shift toward more reliable identification. The late 1990s saw the initial adoption of guidance for blocks, revolutionizing nerve localization by providing real-time visualization of anatomical structures. This technology, first demonstrated in for upper extremity blocks, enabled precise needle placement and significantly reduced the required volumes of local anesthetics—often by up to 50%—while lowering risks such as vascular puncture and . For instance, studies on interscalene blocks showed effective with volumes as low as 20 ml versus 40 ml in traditional methods, contributing to faster onset and fewer systemic toxicities. From the 2000s to the 2020s, continuous perineural catheters emerged as a key advancement, allowing prolonged analgesia through infusion pumps for postoperative in upper extremity surgeries. These catheters, often placed under guidance, extended block duration beyond 24-48 hours, reducing requirements and enabling . Concurrently, adjuvants such as were integrated into local anesthetic solutions to enhance block efficacy; meta-analyses confirmed that perineural prolongs sensory and motor blockade by 2-4 hours without increasing adverse events. This combination improved analgesia quality, particularly for procedures. As of 2025, innovations include refined coracoid approaches to infraclavicular blocks, which, when combined with posterior blocks, provide superior analgesia for with minimal diaphragmatic impairment. Dual brachial plexus blocks have shown promise for surgeries, such as distal repair, offering targeted coverage while minimizing motor weakness in the proximal . AI-assisted ultrasound imaging is under evaluation in clinical trials to automate nerve detection and optimize needle trajectories, potentially standardizing block performance. Additionally, under brachial plexus block has demonstrated superior outcomes over conservative therapy for primary adhesive capsulitis, achieving greater range-of-motion improvements with lower pain scores. The American Society of Regional Anesthesia and Pain Medicine (ASRA) has iteratively updated guidelines on brachial plexus block safety since the 2000s, emphasizing neurologic complication prevention through checklists and . The 2015 advisory highlighted injection pressure to avoid intraneural placement, while 2025 updates addressed anticoagulation risks and 2025 guidelines focused on infection control protocols, including aseptic techniques and adverse event reporting to enhance overall procedural safety.