Brachial plexus block

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Brachial plexus block
Video of a brachial plexus block, using a portable ultrasound scanning device for localization of the nerves of the brachial plexus
ICD-9-CM 04.81
MeSH D009407

Brachial plexus block is a regional anesthesia technique that is sometimes employed as an alternative or as an adjunct to general anesthesia for surgery of the upper extremity. This technique involves the injection of local anesthetic agents in close proximity to the brachial plexus, temporarily blocking the sensation and ability to move the upper extremity. The subject can remain awake during the ensuing surgical procedure, or they can be sedated or even fully anesthetized if necessary.

Contents

There are several techniques for blocking the nerves of the brachial plexus. These techniques are classified by the level at which the needle or catheter is inserted for injecting the local anesthetic — interscalene block on the neck for example is considered the second most complete postoperative analgesia, [1] supraclavicular block immediately above the clavicle, infraclavicular block below the clavicle and axillary block in the axilla (armpit). [2]

Indications

General anesthesia may result in low blood pressure, undesirable decreases in cardiac output, central nervous system depression, respiratory depression, loss of protective airway reflexes (such as coughing), need for tracheal intubation and mechanical ventilation, and residual anesthetic effects. The most important advantage of brachial plexus block is that it allows for the avoidance of general anesthesia and therefore its attendant complications and side effects. Although brachial plexus block is not without risk, it usually affects fewer organ systems than general anesthesia. [3]

Brachial plexus blockade may be a reasonable option when all of the following criteria are met:[ citation needed ]

Anatomy

The brachial plexus is formed by the ventral rami of C5-C6-C7-C8-T1, occasionally with small contributions by C4 and T2. There are multiple approaches to blockade of the brachial plexus, beginning proximally with the interscalene block and continuing distally with the supraclavicular, infraclavicular, and axillary blocks. The concept behind all of these approaches to the brachial plexus is the existence of a sheath encompassing the neurovascular bundle extending from the deep cervical fascia to slightly beyond the borders of the axilla. [2]

Anatomical illustration of the brachial plexus with areas of roots, trunks, divisions and cords marked. Clicking on names of branches will link to their Wikipedia entry. Brachial plexus 2.svgDorsal scapular nerve (rhomboids, levator scapulae)Suprascapular nerve (supraspinatus, infraspinatus)Nerve to subclavius (subclavius)Lateral pectoral nerve (pectoralis major)Musculocutaneous nerve (coracobrachialis, brachialis, biceps brachii)Axillary nerve (deltoid, teres minor)Median nerve (forearm flexors except FCU and ulnar part of FDP, thenar muscles)Ulnar nerve (FCU and ulnar part of FDP, most intrinsic hand musclesRadial nerve (triceps brachii, supinator, anconeus, forearm extensors, brachioradialis)Lower subscapular nerve (lower part of subscapularis, teres major)Thoracodorsal nerve (latissimus dorsi)Medial pectoral nerve (pectoralis major, pectoralis minor)Upper subscapular nerve (upper part of subscapularis)Long thoracic nerve of Bell (serratus anterior)
Anatomical illustration of the brachial plexus with areas of roots, trunks, divisions and cords marked. Clicking on names of branches will link to their Wikipedia entry.

Techniques

Brachial plexus block is typically performed by an anesthesiologist. To achieve an optimal block, the tip of the needle should be close to the nerves of the plexus during the injection of local anesthetic solution. Commonly employed techniques for obtaining such a needle position include transarterial, elicitation of a paresthesia, and use of a peripheral nerve stimulator or a portable ultrasound scanning device. [4] If the needle is close to or contacts a nerve, the subject may experience a paresthesia (a sudden tingling sensation, often described as feeling like "pins and needles" or like an electric shock) in the arm, hand, or fingers. Injection close to the point of elicitation of such a paresthesia may result in a good block. [4] A peripheral nerve stimulator connected to an appropriate needle allows emission of electric current from the needle tip. When the needle tip is close to or contacts a motor nerve, characteristic contraction of the innervated muscle may be elicited. [4] Modern portable ultrasound devices allow the user to visualize internal anatomy, including the nerves to be blocked, neighboring anatomic structures and the needle as it approaches the nerves. Observation of local anesthetic surrounding the nerves during ultrasound-guided injection is predictive of a successful block. [5] Appropriate block per site-specific procedure are listed in the following table: [6]

Procedure SiteInterscaleneSupraclavicularInfraclavicularAxillary1
Shoulder2+++3
Arm2++++
Elbow2+++++
Forearm2+++++
Hand2++++

1. Include musculocutaneous nerve 2. Include T1-T2 if block is anesthetic 3. Include C3-C4 if block is anesthetic

Interscalene block

Left: the red line corresponds to the course of the subclavian artery, while the yellow line represents the brachial plexus and the "X" represents the site of entry of the needle when performing an interscalene block. Right: diagram of the course of the brachial plexus in relation to other important anatomic structures in the right side of the neck. Interscalene block.jpg
Left: the red line corresponds to the course of the subclavian artery, while the yellow line represents the brachial plexus and the "X" represents the site of entry of the needle when performing an interscalene block. Right: diagram of the course of the brachial plexus in relation to other important anatomic structures in the right side of the neck.

The interscalene block is performed by injecting local anesthetic to the nerves of the brachial plexus as it passes through the groove between the anterior and middle scalene muscles, at the level of the cricoid cartilage. This block is particularly useful in providing anesthesia and postoperative analgesia for surgery to the clavicle, shoulder, and arm. Advantages of this block include rapid blockade of the shoulder region, and relatively easily palpable anatomical landmarks. Disadvantages of this block include inadequate anesthesia in the distribution of the ulnar nerve, which makes this an unreliable block for operations involving the forearm and hand. [2]

Side effects

Temporary paresis (impairment of the function) of the thoracic diaphragm occurs in virtually all people who have undergone interscalene or supraclavicular brachial plexus block. Significant respiratory impairment can be demonstrated in these people by pulmonary function testing. [7] In certain people — such as those with severe chronic obstructive pulmonary disease — this can result in respiratory failure requiring tracheal intubation and mechanical ventilation until the block dissipates. [8] Horner's syndrome may be observed if the local anesthetic solution tracks cephalad and blocks the stellate ganglion. This may be accompanied by difficulty swallowing and vocal cord paresis. These signs and symptoms are transient however, and do not commonly result in any long-term problems, although they may be significantly distressing to patients until the effects subside.[ citation needed ]

Contraindications

Contraindications include severe chronic obstructive pulmonary disease, [8] and paresis of the phrenic nerve on the opposite side as the block. [9]

Supraclavicular block

Providing a rapid onset of dense anesthesia of the arm with a single injection, the supraclavicular block is ideal for operations involving the arm and forearm, from the lower humerus down to the hand. The brachial plexus is most compact at the level of the trunks formed by the C5–T1 nerve roots, so nerve block at this level has the greatest likelihood of blocking all of the branches of the brachial plexus. This results in rapid onset times and, ultimately, high success rates for surgery and analgesia of the upper extremity, excluding the shoulder. [10]

Surface landmarks can be used to identify the appropriate location for injection of local anesthetic, which is typically lateral to (outside) the lateral border of the sternocleidomastoid muscle and above the clavicle, with the first rib generally considered to represent the limit below which the needle must not be directed (the pleural cavity and uppermost part of the lung are located at this level). Palpation or ultrasound visualization of the subclavian artery just above the clavicle provides a useful anatomic landmark for locating the brachial plexus, which is lateral to the artery at this level. [10] Proximity to the brachial plexus can be determined using by elicitation of a paresthesia, use of a peripheral nerve stimulator, or ultrasound guidance. [11]

Compared to the interscalene block, the supraclavicular block — despite eliciting a more complete block of the median, radial ulnar and musculocutaneous nerves — does not improve postoperative analgesia. However, the supraclavicular block is often quicker to perform and may result in fewer side effects than the interscalene block. Compared to the infraclavicular block and axillary blocks, the successful achievement of adequate anesthesia for surgery of the upper extremity is about the same with supraclavicular block. [11]

Unlike the interscalene block — which results in diaphragmatic hemiparesis in all subjects — only half of those who undergo supraclavicular block experience this side effect. Disadvantages of the supraclavicular block include the risk of pneumothorax, which is estimated to be between 1%4% when using paresthesia or peripheral nerve stimulator guided techniques. Ultrasound guidance allows the operator to visualize the first rib and the pleura, thereby helping to ensure that the needle does not puncture the pleura; this presumably reduces the risk of pneumothorax. [11]

Infraclavicular block

Left: the red line corresponds to the course of the subclavian artery, while the yellow line represents the brachial plexus and the "X" represents the site of entry of the needle when performing an infraclavicular block. Right: diagram of the course of the brachial plexus in relation to other important anatomic structures in the right infraclavicular fossa. Infraclavicular block.jpg
Left: the red line corresponds to the course of the subclavian artery, while the yellow line represents the brachial plexus and the "X" represents the site of entry of the needle when performing an infraclavicular block. Right: diagram of the course of the brachial plexus in relation to other important anatomic structures in the right infraclavicular fossa.

For infraclavicular block, current evidence suggests that — when using a peripheral nerve stimulator for nerve localization — a double-stimulation technique is better than a single-stimulation technique. When compared to a multiple-stimulation axillary block, infraclavicular block provides similar efficacy. However it may be associated with a shorter performance time and less procedure-related pain for the patient. [11]

Axillary block

Left: the red line corresponds to the course of the axillary artery, while the "X" represents the site of entry of the needle when performing an axillary block. Right: diagram of the course of the axillary artery in relation to the brachial plexus in the right axilla. Axillary block.jpg
Left: the red line corresponds to the course of the axillary artery, while the "X" represents the site of entry of the needle when performing an axillary block. Right: diagram of the course of the axillary artery in relation to the brachial plexus in the right axilla.

The axillary block is particularly useful in providing anesthesia and postoperative analgesia for surgery to the elbow, forearm, wrist, and hand. The axillary block is also the safest of the four main approaches to the brachial plexus, as it does not risk paresis of the phrenic nerve, nor does it have the potential to cause pneumothorax. [12] In the axilla, the nerves of the brachial plexus and the axillary artery are enclosed together in a fibrous sheath which is a continuation of the deep cervical fascia. The easily palpated axillary artery thus serves as a reliable anatomical landmark for this block, and the injection of local anesthetic close to this artery frequently leads to a good block of the brachial plexus. The axillary block is commonly performed due to its ease of performance and relatively high success rate. [4]

Disadvantages of the axillary block include inadequate anesthesia in the distribution of the musculocutaneous nerve. This nerve supplies motor function to the biceps, brachialis, and coracobrachialis muscles and one of its branches supplies sensation to the skin of the forearm. If the musculocutaneous nerve is missed, it may be necessary to block this nerve separately. This can be accomplished by using a peripheral nerve stimulator to identify the location of the nerve as it passes through the coracobrachialis muscle. The intercostobrachial nerves (which are branches of the second and third intercostal nerves) are also frequently missed with the axillary block. Because these nerves supply sensation to the skin of the medial and posterior aspects of the arm and axilla, a tourniquet on the arm may be poorly tolerated in such cases. Subcutaneous injection of local anesthetic over the medial aspect of the arm in the axilla helps patients tolerate an arm tourniquet by blocking these nerves. [13]

Single-injection techniques provide unreliable blockade in the areas supplied by the musculocutaneous and radial nerves. Current evidence suggests that a triple-stimulation technique — with injections on the musculocutaneous, median and radial nerves — is the best technique for the axillary block. [11]

Methods of nerve localization

Despite the fact that people have been performing brachial plexus blocks for over a hundred years, [14] there is as yet no clear evidence to support the assertion that one method of nerve localization is better than another. There are however numerous case reports documenting cases in which use of a portable ultrasound scanning device has detected abnormal anatomy that would otherwise not have been evident using a "blind" approach. On the other hand, use of ultrasound may create a false sense of security in the operator, which may lead to errors, especially if the needle tip is not adequately visualized at all times. [10]

For interscalene block, it is not clear whether nerve stimulation provides a better interscalene block than elicitation of paresthesiae. [11] However, a recent study using ultrasound to follow the spread of local anesthetic demonstrated an improved success rate of the block (relative to blocks done with nerve stimulator alone) even at the inferior roots of the plexus. [2]

For supraclavicular block, nerve stimulation with a minimal threshold of 0.9 mA can offer a dependable block. [11] Although ultrasound-guided supraclavicular block has been shown to be a safe alternative to the peripheral nerve stimulator guided technique, there is little evidence to support that ultrasound guidance provides a better block, or is associated with fewer complications. [10] There is some evidence to suggest that the use of ultrasound guidance in combination with nerve stimulation can shorten the performance time of supraclavicular block. [11]

For axillary block, success rates are greatly improved with multiple injection techniques whether using nerve stimulation or ultrasound guidance. [12]

Special situations

The duration of a "single-shot" brachial plexus block is highly variable, commonly lasting anywhere from 45 minutes to 24 hours. The block can be extended by placing an indwelling catheter, which may be connected to a mechanical or electronic infusion pump for continuous administration of local anesthetic solution. A catheter may be inserted at the interscalene, supraclavicular, infraclavicular or axillary location, depending on the desired location of nerve block. Specific branches of the brachial plexus can also be blocked individually, for example the suprascapular nerve. [15] The infusion of local anesthetic can be programmed to be a continuous flow or patient-controlled analgesia. In some cases, people can maintain the catheters and infusions at home after release from the facility where the surgery was performed. [2]

Complications

As with any procedure involving disruption of the integrity of the skin, brachial plexus block can be associated with infection or bleeding. In people who are using anticoagulant agents, there is a greater risk of complications related to bleeding. [2]

Complications associated with brachial plexus block include intra-arterial or intravenous injection, which can lead to local anesthetic toxicity. This may be characterized by serious central nervous system problems such as epileptic seizure, central nervous system depression, and coma. [16] Cardiovascular effects of local anesthetic toxicity include slowing of the heart rate and impairment of its ability to pump blood through the circulatory system, which may lead to circulatory collapse. In severe cases, cardiac dysrhythmia, cardiac arrest and death may occur. [17] Other rare but serious complications from brachial plexus block include pneumothorax and persistent paresis of the phrenic nerve. [18]

Complications associated with interscalene and supraclavicular blocks include inadvertent subarachnoid or epidural injection of local anesthetic, which can result in respiratory failure. [18]

Because of the close proximity of the lung to the brachial plexus at the level of the clavicle, the complication most often associated with this block is pneumothorax — with a risk as high as 6.1%. [10] Further complications of supraclavicular block include subclavian artery puncture, and spread of local anesthetic to cause paresis of the stellate ganglion, the phrenic nerve and recurrent laryngeal nerve. [10]

Alternatives

Depending on the circumstances, alternatives to brachial plexus block may include general anesthesia, monitored anesthesia care, Bier block, or local anesthesia.[ citation needed ]

History

In 1855, Friedrich Gaedcke (18281890) became the first to chemically isolate cocaine, the most potent alkaloid of the coca plant. Gaedcke named the compound "erythroxyline". [19] [20] In 1884, Austrian ophthalmologist Karl Koller (18571944) instilled a 2% solution of cocaine into his own eye and tested its effectiveness as a local anesthetic by pricking the eye with needles. [21] His findings were presented a few weeks later at annual conference of the Heidelberg Ophthalmological Society. [22] The following year, William Halsted (18521922) performed the first brachial plexus block. [23] [24] Using a surgical approach in the neck, Halsted applied cocaine to the brachial plexus. [25] In January 1900, Harvey Cushing (18691939) — who was at that time one of Halsted's surgical residents — applied cocaine to the brachial plexus prior to dividing it, during a forequarter amputation for sarcoma. [26]

The first percutaneous supraclavicular block was performed in 1911 by German surgeon Diedrich Kulenkampff (18801967). [14] Just as his older colleague August Bier (18611949) had done with spinal anesthesia in 1898, [27] Kulenkampff subjected himself to the supraclavicular block. [14] Later that year, Georg Hirschel (18751963) described a percutaneous approach to the brachial plexus from the axilla. [28] In 1928, Kulenkampff and Persky published their experiences with a thousand blocks without apparent major complications. They described their technique with the patient in the sitting position or in the supine position with a pillow between the shoulders. The needle was inserted above the midpoint of the clavicle where the pulse of the subclavian artery could be felt and it was directed medially toward the second or third thoracic spinous process. [29]

By the late 1940s, clinical experience with brachial plexus block in both peacetime and wartime surgery was extensive, [30] and new approaches to this technique began to be described. For example, In 1946, F. Paul Ansbro was the first to describe a continuous brachial plexus block technique. He secured a needle in the supraclavicular fossa and attached tubing connected to a syringe through which he could inject incremental doses of local anesthetic. [31] The subclavian perivascular block was first described by Winnie and Collins in 1964. [32] This approach became popular due to its lower risk of pneumothorax compared to the traditional Kulenkampff approach. The infraclavicular approach was first developed by Raj.[ citation needed ] In 1977, Selander described a technique for continuous brachial plexus block using an intravenous catheter secured in the axilla. [33]

See also

Notes

  1. Panchamia, Jason, Olsen, David, Sanchez-Sotelo, Joaquin, MD, PhD, Amundson, Adam. Combined Selective Nerve Blockade and Local Infiltration Analgesia in a Total Shoulder Arthroplasty Patient With Chronic Pain and Severe Restrictive Lung Disease: A Case Report. A&A Case Reports. 2017;9(12):360-363. doi:10.1213/XAA.0000000000000617.
  2. 1 2 3 4 5 6 Fisher, L; Gordon, M (2011). "Anesthesia for hand surgery" (PDF). In Wolfe, SW; Hotchkiss, RN; Pederson, WC; Kozin, SH (eds.). Green's Operative Hand Surgery. Vol. 1 (6th ed.). Philadelphia: Elsevier/Churchill Livingstone. pp. 25–40. ISBN   978-1-4160-5279-1. Archived from the original (PDF) on 2019-12-16. Retrieved 2012-06-09.
  3. Boedeker, BH; Rung, GW (1995). "Regional anesthesia" (PDF). In Zajtchuk, R; Bellamy, RF; Grande, CM (eds.). Textbook of Military Medicine, Part IV: Surgical Combat Casualty Care. Vol. 1: Anesthesia and Perioperative Care of the Combat Casualty. Washington, DC: Borden Institute. pp. 251–86. Archived from the original (PDF) on 2012-05-17. Retrieved 2012-06-09.
  4. 1 2 3 4 Winnie, AP (1990). "Perivascular techniques of brachial plexus block". Plexus anesthesia: perivascular techniques of brachial plexus block. Vol. I (2nd ed.). Philadelphia: W.B. Saunders Company. pp. 126–7. ISBN   9780721611723.
  5. Kapral S, Krafft P, Eibenberger K, Fitzgerald R, Gosch M, Weinstabl C (1994). "Ultrasound-guided supraclavicular approach for regional anesthesia of the brachial plexus" (PDF). Anesthesia & Analgesia. 78 (3): 507–13. doi:10.1213/00000539-199403000-00016. PMID   8109769. S2CID   24839528.
  6. Morgan, GE; Mikhail, MS; Murray, MJ (2006). "Peripheral nerve blocks". In Morgan, GE; Mikhail, MS; Murray, MJ (eds.). Clinical Anesthesiology (4th ed.). New York: McGraw-Hill Medical. pp. 283–308. ISBN   978-0071423588.
  7. Finucane, BT; Tsui, BCH (2007). Finucane, BT (ed.). Complications of regional anesthesia (2nd ed.). Philadelphia: Springer Science+Business Media, LLC. pp. 121–48. ISBN   978-0387375595.
  8. 1 2 Urmey, W (2006). "Pulmonary complications". In Neal, JM; Rathmell, J (eds.). Complications in regional anesthesia and pain medicine. Philadelphia: Saunders Elsevier. pp. 147–56. ISBN   9781416023920.
  9. Amutike, D (1998). "Interscalene brachial plexus block". Practical Procedures. 1998 (9). Archived from the original on 2011-09-26.
  10. 1 2 3 4 5 6 Macfarlane, A; Brull, R (2009). "Ultrasound guided supraclavicular block" (PDF). The Journal of New York School of Regional Anesthesia. 12: 6–10.[ permanent dead link ]
  11. 1 2 3 4 5 6 7 8 De Tran QH, Clemente A, Doan J, Finlayson RJ (2007). "Brachial plexus blocks: a review of approaches and techniques". Canadian Journal of Anesthesia. 54 (8): 662–74. doi:10.1007/BF03022962. PMID   17666721. S2CID   4711427.
  12. 1 2 Satapathy, AR; Coventry, DM (2011). "Axillary Brachial Plexus Block". Anesthesiology Research and Practice. 2011: 1–5. doi: 10.1155/2011/173796 . PMC   3119420 . PMID   21716725.
  13. Tschaikowsky, K. and Hemmerling, T. (1998), Comparison of the effect of EMLA and semicircular subcutaneous anaesthesia in the prevention of tourniquet pain during plexus block anaesthesia of the arm. Anaesthesia, 53: 390-393. https://doi.org/10.1046/j.1365-2044.1998.00301.x
  14. 1 2 3 Kulenkampff, D (1911). "Zur anästhesierung des plexus brachialis" [On anesthesia of the brachial plexus]. Zentralblatt für Chirurgie (in German). 38: 1337–40.
  15. White, Leigh; Reardon, Damon; Davis, Keiran; Velli, Gina; Bright, Matthew (2021-09-17). "Anterior suprascapular nerve block versus interscalene brachial plexus block for arthroscopic shoulder surgery: a systematic review and meta-analysis of randomized controlled trials". Journal of Anesthesia. 36 (1): 17–25. doi:10.1007/s00540-021-03000-z. ISSN   1438-8359. PMID   34533639. S2CID   237539656.
  16. Mulroy, M (2002). "Systemic toxicity and cardiotoxicity from local anesthetics: incidence and preventive measures" (PDF). Regional Anesthesia and Pain Medicine. 27 (6): 556–61. doi:10.1053/rapm.2002.37127. PMID   12430104. S2CID   36915462. Archived from the original (PDF) on 2012-11-19.
  17. Mather, LE; Copeland, SE; Ladd, LA (2005). "Acute toxicity of local anesthetics: underlying pharmacokinetic and pharmacodynamic concepts" (PDF). Regional Anesthesia and Pain Medicine. 30 (6): 553–66. doi:10.1016/j.rapm.2005.07.186. PMID   16326341. S2CID   34745265.[ permanent dead link ]
  18. 1 2 Urmey, WF (2009). "Pulmonary complications of interscalene brachial plexus blocks" (PDF). Lecture notes: 2009 symposium. New York: The New York School of Regional Anesthesia. Retrieved 2012-06-02.[ permanent dead link ]
  19. Gaedcke, F (1855). "Ueber das Erythroxylin, dargestellt aus den Blättern des in Südamerika cultivirten Strauches Erythroxylon Coca Lam". Archiv der Pharmazie. 132 (2): 141–50. doi:10.1002/ardp.18551320208. S2CID   86030231.
  20. Zaunick, R (1956). "Early history of cocaine isolation: Domitzer pharmacist Friedrich Gaedcke (1828–1890); contribution to Mecklenburg pharmaceutical history". Beitr Gesch Pharm Ihrer Nachbargeb. 7 (2): 5–15. PMID   13395966.
  21. Koller, K (1884). "Über die verwendung des kokains zur anästhesierung am auge" [On the use of cocaine for anesthesia on the eye]. Wiener Medizinische Wochenschrift (in German). 34: 1276–1309.
  22. Karch, SB (2006). "Genies and furies". A brief history of cocaine from Inca monarchs to Cali cartels : 500 years of cocaine dealing (2nd ed.). Boca Raton, Florida: Taylor & Francis Group. pp. 51–68. ISBN   978-0849397752.
  23. Halsted, WS (1885-09-12). "Practical comments on the use and abuse of cocaine; suggested by its invariably successful employment in more than a thousand minor surgical operations". New York Medical Journal. 42: 294–5.
  24. Crile, GW (1897). "Anesthesia of nerve roots with cocaine". Cleveland Medical Journal. 2: 355.
  25. Borgeat, A (2006). "All roads do not lead to Rome". Anesthesiology. 105 (1): 1–2. doi:10.1097/00000542-200607000-00002. PMID   16809983. S2CID   19403814.
  26. Cushing, HW (1902). "I. On the Avoidance of Shock in Major Amputations by Cocainization of Large Nerve-Trunks Preliminary to their Division. With Observations on Blood-Pressure Changes in Surgical Cases". Annals of Surgery. 36 (3): 321–45. doi:10.1097/00000658-190209000-00001. PMC   1430733 . PMID   17861171.
  27. Bier, A (1899). "Versuche über cocainisirung des rückenmarkes" [Experiments on the cocainization of the spinal cord]. Deutsche Zeitschrift für Chirurgie (in German). 51 (3–4): 361–9. doi:10.1007/BF02792160. S2CID   41966814.
  28. Hirschel, G (1911-07-18). "Die anästhesierung des plexus brachialis fuer die operationen an der oberen extremitat" [Anesthesia of the brachial plexus for operations on the upper extremity]. Munchener Medizinische Wochenschrift (in German). 58: 1555–6.
  29. Kulenkampff, D; Persky, MA (1928). "Brachial plexus anaesthesia: its indications, technique, and dangers". Annals of Surgery. 87 (6): 883–91. doi:10.1097/00000658-192806000-00015. PMC   1398572 . PMID   17865904.
  30. de Pablo, JS; Diez-Mallo, J (1948). "Experience with Three Thousand Cases of Brachial Plexus Block: Its Dangers: Report of a Fatal Case". Annals of Surgery. 128 (5): 956–64. doi:10.1097/00000658-194811000-00008. PMC   1513923 . PMID   17859253.
  31. Ansbro, FP (1946). "A Method of Continuous Brachial Plexus Block". American Journal of Surgery. 71 (6): 716–22. doi:10.1016/0002-9610(46)90219-x. PMID   20983091.
  32. Winnie AP, Collins VJ (1964). "The subclavian perivascular technique of brachial plexus anesthesia". Anesthesiology. 25 (3): 35–63. doi: 10.1097/00000542-196405000-00014 . PMID   14156576. S2CID   36275626.
  33. Selander, D (1977). "Catheter technique in axillary plexus block: presentation of a new method". Acta Anaesthesiologica Scandinavica. 21 (4): 324–9. doi:10.1111/j.1399-6576.1977.tb01226.x. PMID   906787. S2CID   8164535.

Further reading

Related Research Articles

<span class="mw-page-title-main">Anesthesia</span> State of medically-controlled temporary loss of sensation or awareness

Anesthesia or anaesthesia is a state of controlled, temporary loss of sensation or awareness that is induced for medical or veterinary purposes. It may include some or all of analgesia, paralysis, amnesia, and unconsciousness. An individual under the effects of anesthetic drugs is referred to as being anesthetized.

Local anesthesia is any technique to induce the absence of sensation in a specific part of the body, generally for the aim of inducing local analgesia, i.e. local insensitivity to pain, although other local senses may be affected as well. It allows patients to undergo surgical and dental procedures with reduced pain and distress. In many situations, such as cesarean section, it is safer and therefore superior to general anesthesia.

<span class="mw-page-title-main">Local anesthetic</span> Medications to reversibly block pain

A local anesthetic (LA) is a medication that causes absence of all sensation in a specific body part without loss of consciousness, as opposed to a general anesthetic, which eliminates all sensation in the entire body and causes unconsciousness. Local anesthetics are most commonly used to eliminate pain during or after surgery. When it is used on specific nerve pathways, paralysis also can be induced.

<span class="mw-page-title-main">Brachial plexus</span> Network of nerves

The brachial plexus is a network of nerves formed by the anterior rami of the lower four cervical nerves and first thoracic nerve. This plexus extends from the spinal cord, through the cervicoaxillary canal in the neck, over the first rib, and into the armpit, it supplies afferent and efferent nerve fibers to the chest, shoulder, arm, forearm, and hand.

<span class="mw-page-title-main">Spinal anaesthesia</span> Form of neuraxial regional anaesthesia

Spinal anaesthesia, also called spinal block, subarachnoid block, intradural block and intrathecal block, is a form of neuraxial regional anaesthesia involving the injection of a local anaesthetic or opioid into the subarachnoid space, generally through a fine needle, usually 9 cm (3.5 in) long. It is a safe and effective form of anesthesia usually performed by anesthesiologists that can be used as an alternative to general anesthesia commonly in surgeries involving the lower extremities and surgeries below the umbilicus. The local anesthetic with or without an opioid injected into the cerebrospinal fluid provides locoregional anaesthesia: true analgesia, motor, sensory and autonomic (sympathetic) blockade. Administering analgesics in the cerebrospinal fluid without a local anaesthetic produces locoregional analgesia: markedly reduced pain sensation, some autonomic blockade, but no sensory or motor block. Locoregional analgesia, due to mainly the absence of motor and sympathetic block may be preferred over locoregional anaesthesia in some postoperative care settings. The tip of the spinal needle has a point or small bevel. Recently, pencil point needles have been made available.

<span class="mw-page-title-main">Axilla</span> Area of the human body beneath the joint between arm and torso

The axilla is the area on the human body directly under the shoulder joint. It includes the axillary space, an anatomical space within the shoulder girdle between the arm and the thoracic cage, bounded superiorly by the imaginary plane between the superior borders of the first rib, clavicle and scapula, medially by the serratus anterior muscle and thoracolumbar fascia, anteriorly by the pectoral muscles and posteriorly by the subscapularis, teres major and latissimus dorsi muscle.

<span class="mw-page-title-main">Epidural administration</span> Medication injected into the epidural space of the spine

Epidural administration is a method of medication administration in which a medicine is injected into the epidural space around the spinal cord. The epidural route is used by physicians and nurse anesthetists to administer local anesthetic agents, analgesics, diagnostic medicines such as radiocontrast agents, and other medicines such as glucocorticoids. Epidural administration involves the placement of a catheter into the epidural space, which may remain in place for the duration of the treatment. The technique of intentional epidural administration of medication was first described in 1921 by Spanish military surgeon Fidel Pagés.

<span class="mw-page-title-main">Musculocutaneous nerve</span> Nerve in the arm

The musculocutaneous nerve is a mixed branch of the lateral cord of the brachial plexus derived from cervical spinal nerves C5-C7. It arises opposite the lower border of the pectoralis major. It provides motor innervation to the muscles of the anterior compartment of the arm: the coracobrachialis, biceps brachii, and brachialis. It provides sensory innervation to the lateral forearm. It courses through the anterior part of the arm, terminating 2 cm above elbow; after passing the lateral edge of the tendon of biceps brachii it is becomes known as the lateral cutaneous nerve of the forearm.

Infiltration analgesia is deposition of an analgesic drug close to the apex of a tooth so that it can diffuse to reach the nerve entering the apical foramina. It is the most routinely used in dental local treatment.

<span class="mw-page-title-main">Nerve block</span> Deliberate inhibition of nerve impulses

Nerve block or regional nerve blockade is any deliberate interruption of signals traveling along a nerve, often for the purpose of pain relief. Local anesthetic nerve block is a short-term block, usually lasting hours or days, involving the injection of an anesthetic, a corticosteroid, and other agents onto or near a nerve. Neurolytic block, the deliberate temporary degeneration of nerve fibers through the application of chemicals, heat, or freezing, produces a block that may persist for weeks, months, or indefinitely. Neurectomy, the cutting through or removal of a nerve or a section of a nerve, usually produces a permanent block. Because neurectomy of a sensory nerve is often followed, months later, by the emergence of new, more intense pain, sensory nerve neurectomy is rarely performed.

<span class="mw-page-title-main">Lateral pectoral nerve</span>

The lateral pectoral nerve arises from the lateral cord of the brachial plexus, and through it from the C5-7.

<span class="mw-page-title-main">Chloroprocaine</span> Local anaesthetic drug

Chloroprocaine is a local anesthetic given by injection during surgical procedures and labor and delivery. Chloroprocaine vasodilates; this is in contrast to cocaine which vasoconstricts. Chloroprocaine is an ester anesthetic.

A retrobulbar block is a regional anesthetic nerve block in the retrobulbar space, the area located behind the globe of the eye. Injection of local anesthetic into this space constitutes the retrobulbar block. This injection provides akinesia of the extraocular muscles by blocking cranial nerves II, III, and VI, thereby preventing movement of the globe. Cranial nerve IV lies outside the muscle cone, and therefore is not affected by the local anesthesia. As a result, intorsion of the eye is still possible. It also provides sensory anesthesia of the conjunctiva, cornea and uvea by blocking the ciliary nerves. This block is most commonly employed for cataract surgery, but also provides anesthesia for other intraocular surgeries.

<span class="mw-page-title-main">Shoulder replacement</span>

Shoulder replacement is a surgical procedure in which all or part of the glenohumeral joint is replaced by a prosthetic implant. Such joint replacement surgery generally is conducted to relieve arthritis pain or fix severe physical joint damage.

Dental anesthesia is the application of anesthesia to dentistry. It includes local anesthetics, sedation, and general anesthesia.

<span class="mw-page-title-main">History of neuraxial anesthesia</span>

The history of neuraxial anaesthesia dates back to the late 1800s and is closely intertwined with the development of anaesthesia in general. Neuraxial anaesthesia, in particular, is a form of regional analgesia placed in or around the Central Nervous System, used for pain management and anaesthesia for certain surgeries and procedures.

Ocular surgery may be performed under topical, local or general anesthesia. Local anaesthesia is more preferred because it is economical, easy to perform and the risk involved is less. Local anaesthesia has a rapid onset of action and provides a dilated pupil with low intraocular pressure.

<span class="mw-page-title-main">Intercostal nerve block</span> Procedure for pain relief

Intercostal nerve block is a nerve block which temporarily or permanently interrupts the flow of signals along an intercostal nerve, usually performed to relieve pain.

Fascia iliaca blocks is a local anesthetic nerve block, a type of regional anesthesia technique, used to provide analgesia or anaesthesia to the hip and thigh. FICB can performed by using ultrasound or with a loss of resistance technique, the latter sometimes referred to as the "two-pop-method". FICB works by affecting the femoral, obturator and the lateral cutaneous nerves with a local anesthetic.

<span class="mw-page-title-main">Caudal anaesthesia</span> Form of neuraxial regional anaesthesia

Caudal anaesthesia is a form of neuraxial regional anaesthesia conducted by accessing the epidural space via the sacral hiatus. It is typically used in paediatrics to provide peri- and post-operative analgesia for surgeries below the umbilicus. In adults it is used for chronic low back pain management.

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