Basic Surgical Technique and Postoperative Care

The hand is the most complex and versatile structure in the human body. Formed of 27 bones, the hand and wrist require more than 30 muscles and a vast web of ligaments and tendons to move them into the myriad postures required for the countless tasks the hand performs every day. The complexity of hand function is reflected by the large amount of brain space dedicated to it. Injury to or dysfunction of any element of hand function can cause significant disability. Because of the importance of the hand to every aspect of life, it is essential for the surgeon to make the correct diagnosis and perform the appropriate and needed procedures, avoiding both undertreatment and overtreatment.

Preoperative Planning and Preparation

A carefully taken history and detailed physical examination of the involved part are frequently sufficient to determine the appropriate diagnosis. Routine anteroposterior, lateral, and oblique radiographic hand and wrist views may be supplemented with additional special views of the wrist, thumb base, and fifth carpometacarpal joint. MRI and CT can provide sufficient additional information to clarify some bone and soft-tissue problems in the hand and wrist. Radionuclide bone scanning may show areas of bone involvement before they can be seen on plain radiographs. Electrodiagnostic studies (electromyography and nerve conduction velocities) may localize areas of nerve compression and reveal other conditions (e.g., peripheral neuropathy). In patients with suspected but undiagnosed systemic illnesses, such as the inflammatory arthritides, assessment by appropriate medical specialists is helpful in determining appropriate nonoperative management. Patients who are taking warfarin, corticosteroids or other antiinflammatory medications, immunosuppressive drugs, aspirin, herbal and complementary preparations, and medications for diabetes may require modification of dosage or discontinuation of the medications during the immediate preoperative and intraoperative periods.

Most important is that the patient and surgeon have realistic expectations regarding the operative outcome before the procedure is performed. The patient should understand the options; the alternatives to surgery; the expected outcome with and without surgical treatment; the potential risks, hazards, and benefits of the surgery; the nature and location of the incisions; the potential need for incisions to be made on other parts of the body for the harvesting of grafts; and the possible use of internal fixation, drains, and other types of implants. The patient should understand the nature of immobilization after surgery, including the use of splints and casts, and he or she should understand that recovery and rehabilitation might be prolonged, especially after major reconstructive procedures.

As part of the preoperative preparation, patients are instructed to keep their hands clean for several days before surgery and to avoid skin injury to minimize the potential for infection. From currently available information, an infection rate of 0.5% to 3.0% might be expected. If the patient has evidence of cuts or skin or remote infections, the operation may best be delayed. If the fingernails are long or dirty, they should be trimmed and cleaned to remove potential sources of bacterial contamination, and excessive hair in the incision area should be removed before scrubbing the operative extremity.

Perioperative antibiotics

Although surgical site infections are uncommon after hand surgery, postoperative infection can occur, causing impairment of hand function, delaying rehabilitation and return to work. Severe infection may require multiple surgical procedures and result in permanent damage to the hand. The routine use of perioperative antibiotics for many orthopaedic procedures in the hand remains questionable. In three large series (one retrospective study involving 8850 patients, one prospective, randomized study involving 1340 patients, and one retrospective analysis of 516,986 patients gathered from a multistate commercial insurance claims database) there was no significant difference in the frequency of infection in patients who received perioperative antibiotics and those who did not. The prospective study also found no difference between elective and emergency surgery, between operations lasting 2 hours and those lasting longer, or between “clean” and “crush/dirty” wounds. Even in “high-risk” patients (smokers, those with diabetes mellitus, and those with longer operative procedure times) in the retrospective study, prophylactic antibiotics did not reduce the frequency of surgical site infection. Another study that evaluated the use of antibiotics for carpal tunnel release in patients with a prosthetic joint also found that antibiotics were not indicated. Although numerous studies have concluded that antibiotic prophylaxis should not be routinely administered for surgery of the hand, the rate of antibiotic use has steadily increased, with antibiotics being used in one of five clean soft-tissue hand surgeries.

Arrangement and routine in the operating room

Because surgical results depend considerably on the skill, judgment, and precise work of the surgeon, intraoperative distractions should be kept to a minimum. It is important for the surgeon to establish a standard routine that is followed regularly. Each assistant can then depend on this routine. The activities of the assistants in following this routine should not be disrupted by the surgeon with irregular, unexpected, or inconsistent demands. A standard routine makes it possible for assistants to know what is expected of them at each step in the operation and allows them to perform without hesitation, delay, or wasted motion.

The operating room should always be pleasant. If a local anesthetic is being used and the patient is awake, loud or inappropriate noises or bursts of conversation may alarm the patient and should be avoided. Sometimes music of the patient’s choosing is comforting.

If the surgical procedure is being arranged with the operating room staff, it is helpful to make requests regarding special needs for the case under consideration. Making advance arrangements for instruments, sutures, operating microscope, special implants, additional assistants, and other items enhances the efficiency of the operating team on the day of the procedure. Radiology support, including the use of C-arm fluoroscopy, should be arranged beforehand as well.

Five “be” attitudes on the part of the surgeon can increase efficiency in the operating room: (1) be punctual—if possible, be early; (2) be available—being present signifies to the surgical team that you are a member of the team; (3) be predictable—the less variation in the operating room routine, the more efficient it becomes; (4) be progressive—go from simple to complex; and (5) be gracious—it costs nothing, but buys a lot of goodwill.

The operating surgeon usually sits on a firm, comfortable, and stable stool and occasionally stands for some procedures. When sitting, the surgeon’s knees are almost level with the hips and the feet rest flat on the floor without strain. The working surface of the operating hand table should be at elbow height to provide a comfortable support for the forearms. When the light is directed perpendicular to the surgeon’s view, it shines directly on the operative field, and shadows are avoided.

Seated opposite the surgeon, the assistant should view the operative field from 8 to 10 cm higher than the surgeon to allow a clear line of vision without having to bend forward and obstruct the surgeon’s view. Although mechanical hand holders are available, they are not as good as a motivated and well-trained assistant ( Fig. 64.1 ). It is especially helpful for the assistant to be familiar with each procedure. Usually, the primary duty of the assistant is to hold the patient’s hand stable, secure, and motionless, retracting the fingers to provide the surgeon with the best access to the operative field ( Fig. 64.2A and B ). Using a mechanical holder such as a lead hand is better with untrained assistants.

FIGURE 64.1, Mechanical hand positioner/holder.

FIGURE 64.2, A, Assistant holds patient’s hand firm and motionless and exposes operative field for midlateral digital incision. B, Ideal position for assistant to stabilize patient’s hand as surgeon makes zigzag incision.

The hand operating table should be stable and immobile. Space should be sufficient for the patient’s hand and for resting the elbows and forearms of the surgeon and assistant, minimizing muscle fatigue. For most procedures, the surgeon should sit on the axillary side of the involved extremity, allowing the anatomy of either hand to be seen in the same relative position. Some procedures on the dorsum of the hand and wrist may be performed more easily from the cephalic side. If the surgeon changes sides, keep in mind the change in routine to avoid anatomic disorientation.

The tray holding the basic instruments is often placed on a shelf extending from the operating table, level with the working surface. The instruments always should be arranged in the same order ( Fig. 64.3 ). This arrangement allows the surgeon to save time by routinely reaching for instruments from the basic tray. With practice, this can be done without the surgeon looking at the instruments.

FIGURE 64.3, Basic instruments for any surgical procedure on hand. Octagonal knife handle is preferable to flat handle because knife is more commonly held by precision pinch in hand surgery. Instruments shown are knife handle, small rat-tooth forceps, dissecting scissors, small hemostats, ruler, marking pencil, double-hook Lovejoy retractors, and probe.

Using an instrument pan or designated “hands-free” zone, the surgeon discards an instrument after using it, and the surgery technician returns it to its place on the tray. The discarded knife, tissue forceps, and dissecting scissors that are used constantly are not retrieved by the surgery technician unless requested by the surgeon. Special instruments should be readily available on another large table so that they can be handed quickly to the surgeon on request. Additional knife blades and special sutures and needles also should be immediately available.

Numerous hand conditions, such as infection, foreign bodies, and fractures, may now be effectively treated in procedure rooms with local anesthesia as opposed to formal operating rooms when appropriate. Studies have shown a significant reduction in the cost of these procedures without a significant difference in risk of complications.

Choice of Anesthesia

Drugs used for local and regional anesthesia should become effective within a few minutes after injection, should cause minimal local irritation, and should have low systemic toxicity. Lidocaine seems to fulfill these requirements. Mepivacaine (Carbocaine) is longer acting but may be slower in onset. Many surgeons prefer bupivacaine (Marcaine) because it is effective for 8 hours or longer. It can be used for axillary brachial block to avoid the use of a general anesthetic. Each of these agents has a toxicity level based on milligrams per kilogram of body weight, and this should be calculated before administration ( Table 64.1 ).

TABLE 64.1

Maximal Doses of Local Anesthetics for Brachial Plexus Blocks

Modified from Bruce BG, Green A, Blaine TA, Wesner LV: Brachial plexus blocks for upper extremity orthopaedic surgery, J AAOS 20:38, 2012.

Anesthetic	Maximal Recommended Dose
Bupivacaine	2.5 mg/kg
Bupivacaine with epinephrine	3.0 mg/kg
Levobupivacaine	2.0 mg/kg
Levobupivacaine with epinephrine	3.0 mg/kg
Ropivacaine	2.0 mg/kg
Ropivacaine with epinephrine	3.0 mg/kg

These amounts should be used as a guideline only; practitioners should use their clinical judgment when administering local anesthetics.

Unsatisfactory anesthesia for hand and upper extremity operations prevents the surgeon from accomplishing his or her goals and is likely to compromise the surgical result. For accurate and precise work, the part must be motionless, the procedure should be completely painless, and the patient should be comfortable. All anesthetic techniques carry some risks, and the selection of the technique depends on the needs of the patient and the preferences of the surgeon and anesthesiologist. The selection should be part of the preoperative planning.

At times, general anesthesia is preferred. Factors that favor the use of this type of anesthesia include extensive and prolonged hand and upper extremity operations, performance of procedures on other parts of the body (chest or abdomen or harvesting of various tissue grafts), extensive operations in young children, the presence of infection in a region that would preclude injecting a local anesthetic agent, and the preference of a particularly uneasy or anxious patient.

Regional anesthesia has many advantages in hand and upper extremity surgery. Satisfactory regional anesthesia can be achieved for emergency procedures performed on patients with a full stomach; in these situations and in elective operations, a regional anesthetic blocks vasoconstrictive afferent impulses from the surgical wound and avoids some of the unpleasant postoperative complications of general anesthesia. Outpatient surgery can be performed safely using regional anesthetic blocks, which reduce the need for postoperative nursing care. A regional anesthetic may allow operations to be done on the hand and upper extremity in patients with unstable cardiac or severe pulmonary or renal problems that would create an increased risk with general anesthesia. In a recent study of 27,041 patients who had hand surgery, local and regional anesthesia, with and without sedation, resulted in fewer postoperative complications than general anesthesia. In addition, avoiding sedation entirely was shown to decrease the risk of complications after surgery in patients over the age of 65 years.

Regional anesthesia is less satisfactory in children or extremely nervous, anxious, or uncooperative adults. It should be avoided in patients with documented, true allergies to local anesthetic agents and in patients taking anticoagulants. A regional anesthetic agent may be difficult to administer in patients with contractures or involvement of joints that limit positioning of the limb for satisfactory blocks and in patients whose veins or blood pressure elevation do not allow the use of the intravenous technique. Care should be taken when administering regional anesthetic agents to avoid complications such as overdosage, intravascular injection (when doing nerve blocks), pneumothorax (when doing supraclavicular brachial plexus blocks), and the dissemination of infection.

For operations on the hand and upper extremity, four methods of regional anesthesia are in widespread use: (1) brachial plexus blocks using the interscalene, axillary, or supraclavicular approach; (2) intravenous regional blocks; (3) peripheral nerve blocks distal to the axilla, including blocks of the median, radial, ulnar, and digital nerves; and (4) local infiltration of anesthetic agents, including the wide-awake, local anesthesia, no tourniquet (WALANT) technique. It is helpful to have the patient satisfactorily sedated before surgery. In many situations, especially in elective surgery, simple nerve blocks at the wrist or fingers require little premedication. The use of regional anesthesia requires that sufficient time be allowed in the immediate period before surgery for preparation of the patient, for the administration of the regional anesthetic agents, and for the anesthetic to become effective before the skin incision is made.

Brachial plexus blocks

The traditional approaches for administering anesthesia to the major components of the brachial plexus include the axillary, interscalene, and supraclavicular and infraclavicular routes ( Fig. 64.4 ). The axillary and interscalene approaches we use most commonly probably are safer than the supraclavicular route, which carries the risk of a low incidence (1% to 5%) of pneumothorax. Infraclavicular and supraclavicular blocks are more commonly done now with ultrasound guidance. The interscalene block covers the supraclavicular nerves emanating from the third and fourth cervical roots and is ideal for shoulder surgery. Interscalene blocks can also be used for elbow surgery. Supraclavicular blocks are useful for surgery in the upper arm distal to the shoulder, whereas infraclavicular blocks can provide regional anesthesia for surgery of the elbow, forearm, wrist, and hand. An axillary block provides anesthesia similar to that of an infraclavicular block. Access to the axillary space requires the patient to abduct the arm 90 degrees, which may be difficult for those with trauma or contractures. Needle placement for brachial plexus blocks was traditionally based on anatomic landmarks and nerve localization with a nerve stimulator, but more recent approaches use an ultrasound approach. A meta-analysis of 13 studies comparing neurostimulation with ultrasound-guided blocks found that ultrasound-guided blocks were more likely to be successful, took less time, had a faster onset, and decreased the risk of vascular puncture. A study of the multiple-injection technique for axillary block showed that ultrasound guidance resulted in fewer needle passes, a shorter time to onset of anesthesia, and less procedure-related pain than nerve stimulation techniques. Limitations of ultrasound include availability, a limited plane of view, and highly operator-dependent image quality.

$FIGURE 64.4, Distribution of brachial plexus blocks. A, Interscalene. B, Supraclavicular. C, Infraclavicular axillary, single injection. D, Axillary, multiple injections and high humeral block.$

Short- and long-acting local anesthetic agents can be used for brachial plexus blocks. The dose depends on the agent used, the technique used, and the preference of the administering physician. Although the amount of anesthetic used is not standardized, maximal amounts have been recommended ( Table 64.1 ). Evidence exists that multiple-injection block is more effective than single or double-injection block in obtaining and maintaining anesthesia; no statistically significant differences have been noted regarding secondary analgesia failure, complications, or patient discomfort.

Complications of brachial plexus blocks are few (<1%). Reported systemic complications include cardiac arrest, respiratory failure, and seizures. Peripheral nerve injury can be caused by mechanical trauma from needles or catheters, drug neurotoxicity, ischemia, compression, or stretch, but permanent neurologic sequelae occur in less than 1% of patients. Pneumothorax is most common with supraclavicular blocks (as high as 6%) but has been reported with interscalene and infraclavicular blocks. Ultrasound-guided technique has been suggested to reduce the risk of pneumothorax: a prospective study found no clinically apparent pneumothoraces in 510 patients who had ultrasound-guided supraclavicular blocks.

Contraindications to axillary brachial plexus block include infection in the axilla, axillary lymphadenopathy, and malignancy.

Dysesthesias and “brachialgia” may persist after brachial plexus blocks, and the patient should understand this before the block. It also might create difficulty in patients who require fine manipulation of the hands in their occupation.

Intravenous regional anesthesia

The intravenous regional anesthesia technique using a double tourniquet (Bier) is useful, especially for procedures of relatively short duration (60 to 90 minutes). A specially designed double tourniquet is used. The patient should be satisfactorily premedicated, and intravenous infusion should be in place in the contralateral arm. The usual anesthetic agent is lidocaine. In most situations, 30 to 60 mL of 0.5% lidocaine provides sufficient and safe anesthesia. Adjuncts to lidocaine also have shown some benefit in analgesia and tourniquet pain. The dosage used should take the patient’s age and body weight into consideration. Satisfactory anesthesia can be obtained in a short time. The tourniquet is left inflated for a minimum of 30 minutes after injection of the anesthetic agent into the extremity. In the usual situation, the limb is exsanguinated; the proximal tourniquet is inflated to a level 100 mm Hg greater than the systolic pressure (usually 250 to 300 mm Hg); and, using sterile technique, the anesthesiologist intravenously introduces the previously determined volume of anesthetic agent ( Fig. 64.5 ). As the more proximal tourniquet becomes uncomfortable, the distal tourniquet is inflated and the proximal tourniquet is deflated. Reported reactions during intravenous regional anesthesia include anesthetic toxicity, cardiac arrhythmias (bradycardia and cardiac arrest), unconsciousness, seizures, vertigo, nystagmus, and compartment syndrome.

The use of a forearm tourniquet for intravenous regional anesthesia has been suggested, with reported advantages of safety, preservation of hand motor function, lower anesthetic dose, and reduced risk of complications. One study of 430 patients demonstrated no major complications when tourniquet time was less than 20 minutes.

Peripheral nerve blocks

The median, radial, and ulnar nerves can be blocked at the wrist. In terms of surgical time, tourniquet time, and postoperative pain, no difference has been noted between forearm blocks and brachial plexus blocks; however, forearm blocks are extremely helpful for brief procedures ( Fig. 64.6 ), and a tourniquet may not be required or may be used only for a short period (usually ≤30 minutes). Blocks at the wrist can be especially useful for procedures such as tenolysis and capsulotomy because motion of the fingers can be observed during surgery. The patient can be kept comfortable, and a tourniquet can be used longer than 30 minutes if the patient is adequately sedated. Kocheta and Agrawal described adding posterior interosseous and anterior interosseous nerve blocks to a wrist block for more effective carpal surgery. Regardless of the surgical location, it is essential to know the location of the respective nerves before attempting regional blocks. Ultrasound may be useful in this regard. One study found that nonultrasound-guided median nerve blocks at the wrist were unreliable in effectiveness and took up to 40 minutes for maximal numbness to occur and up to 100 minutes for maximal anesthesia. Contraindications to peripheral nerve blocks include infection in the proposed area of injection, history of allergy to the anesthetic, or a patient who is unable to communicate pain.

Digital nerve blocks

Digital nerve blocks provide excellent anesthesia for procedures on the fingers ( Fig. 64.7 ). Usually, perineural injection around the digital nerves proximal to the finger web spaces is a safer technique than injection of the nerves at the base of the fingers. Because ischemia may develop after injection of an anesthetic agent in a circle around the base of the finger, this technique should be avoided. Digital blocks using a transthecal (flexor sheath) approach have shown no advantage compared with the traditional digital block technique ( Fig. 64.8 ), but may be tolerated better because it is a single injection rather than two separate injections. We rarely use epinephrine in the local anesthetic agent in the digits, although it can be used safely.

FIGURE 64.8, For procedures that require anesthesia from midmiddle phalanx distally (e.g., nail bed regions and distal interphalangeal joint distributions and fusions) digital anesthesia can be easily achieved by single volar injection technique. A, Just proximal to palmar digital crease, through pinched skin 3 to 5 mL of local anesthetic is injected superficial to flexor sheath. B, Anesthesia achieved (colored area) from block of proper and dorsal sensory digital nerve branches. Note, if more proximal anesthesia is needed, additional block can be given at metacarpophalangeal joint dorsally as shown.

If hemostasis is required, traditionally a Penrose drain or a French rubber catheter applied around the finger has provided satisfactory and safe ischemia. Commercially available finger tourniquets and the finger of a rubber glove cut to allow it to be rolled onto the finger as a tourniquet also are effective tools ( Fig. 64.9 ). Pressures achieved beneath these tourniquets cannot be determined accurately; caution is advised. At times, especially in the elderly and patients with vascular disorders in the fingers (e.g., Raynaud disease, atherosclerosis, diabetes), vascular insufficiency may develop in the digit, and care should be taken when using digital tourniquets in these patients ( Fig. 64.10 ). If a rubber glove is used, special attention is essential to ensure it is removed at the end of the procedure: there are reports of catastrophic consequences after such a tourniquet was left on a digit.

FIGURE 64.9, Rubber glove tourniquet (see text).

FIGURE 64.10, Broad-based finger tourniquet can be cut from Esmarch wrap, which usually accompanies upper extremity packages. A, Long and short strips 2.5 cm wide are cut from opposite sides of Esmarch bandage. B, Short strip is loosely applied across finger base and is held in place with curved hemostat. Longer strip is used to exsanguinate finger. C, Tension is applied to short section, and hemostat is applied close to dorsal skin with the two limbs of short Esmarch section fully opposed.

Local infiltration

Local infiltration of an anesthetic agent may be used for more proximal conditions that do not require deep, extensive dissection. This method is satisfactory for trigger digit release, small scar revision, and excision of benign masses from the skin and subcutaneous tissues of the forearm, hand, and fingers.

Walant approach

There has been a move away from the traditional tourniquet and sedation protocol to the WALANT approach for outpatient hand and wrist surgery. Suggested benefits of the WALANT approach include (1) increased patient comfort and convenience, (2) decreased operative time for minor procedures such as carpal tunnel and trigger finger releases, (3) significant cost reductions, and (4) ability to see sutured tendons, and bones and joints with fracture fixation, during a full range of active movement, which can improve functional outcomes. The WALANT approach can be used for a variety of outpatient hand and wrist procedures, with the location of injection and the volume of anesthetic agent differing between them ( Table 64.2 ). Although the technique is not appropriate for all patients, it can be used in most patients who can, for instance, have dental procedures without sedation. Specific procedures for which WALANT is effective include flexor tendon repair, tendon transfer, and soft-tissue releases. It has also been used for phalangeal and metacarpal fracture treatment. The primary advantage of this procedure is that it avoids the use of a tourniquet, reducing patient pain and the risk of injury to the nerves or skin. Patient satisfaction is high with this method because there are no sedation side effects, and faster recovery has been noted. Also postoperative narcotic use has been reported to be less than with other forms of anesthesia.

TABLE 64.2

Typical Volumes Used for Common Operations

Modified from Lalonde DH, Wong A: Dosage of local anesthesia in wide awake hand surgery, J Hand Surg 38:2025, 2013.

Operation	Typical Volume of 1% Lidocaine with 1:100,000 Epinephrine and 8.4% Bicarbonate (Mixed 10 mL:1 mL)	Location of Injection
Carpal tunnel	20 mL	10 mL between ulnar and median nerves (5 mm proximal to wrist crease and 5 mm ulnar to median nerve); another 10 mL under incision
Trigger finger	4 mL	Subcutaneously beneath the center of the incision
Finger sensory block (SIMPLE)	2 mL	Volar middle of proximal phalanx just past palmar-finger crease
Finger soft-tissue lesions or other surgery when finger base tourniquet is not desirable and finger epinephrine is used for hemostasis	5 mL volar distributed among 5 phalanges, 4 mL dorsal split between 2 phalanges	2 mL volar and 2 mL dorsal subcutaneous midline fat, in both proximal and middle phalanges. Distal phalanx gets only 1 mL midline volar, just past the DIP crease
PIP arthrodesis	8 mL total, 4 mL volar (2 in each phalanx) and 4 mL dorsal (2 in each phalanx)	2 mL midvolar and another 2 mL middorsal of both proximal and middle phalanges
Thumb MCP arthrodesis and collateral ligament tears of the MCP joint	15 mL	2 mL on each of volar and dorsal aspects of proximal phalanx and the rest all around the metacarpal head
Dupuytren contracture or zone II flexor tendon repair	15 mL/ray	10 mL (or more) in the palm; 2 mL in the proximal and middle phalanges and 1 mL in the distal phalanx (if required)
Trapeziectomy or Bennett fracture	40 mL	Radial side of the hand under the skin and all around the joint, including the median nerve. If LRTI is performed, decrease concentration to 0.5% lidocaine with 1:200,000 epinephrine, and also inject all around where FCR or APL will be dissected
Metacarpal fractures	40 mL	All around the metacarpal where dissection or K-wires will occur

APL , Abductor pollicis longus; DIP , distal interphalangeal joint; FCR , flexor carpi radialis; LRTI , ligament reconstruction and tendon interposition; MCP , metacarpophalangeal joint; PIP , proximal interphalangeal joint; SIMPLE , single subcutaneous injection in the middle of the proximal phalanx with lidocaine and epinephrine.

WALANT uses a combination of lidocaine or bupivacaine and epinephrine to obtain hemostasis and anesthetize the area of the surgical procedure. As with any local anesthetic use, adverse reactions are possible but rare. Nevertheless, patients require monitoring for hypotension, seizures, cardiac dysrhythmias, and other complications. In the past the use of epinephrine in the hand or foot was believed to cause necrosis and gangrene, but this has been refuted by several studies. In a multicenter, prospective study of 3110 patients who had hand or finger epinephrine injections, none developed skin necrosis or digital tissue loss. If a local adverse reaction occurs from the use of epinephrine in the finger, phentolamine, a vasodilator, can be used for reversal of epinephrine-induced vasoconstriction.

Walant Administration ( Box 64.1 )

Two mL of 1% lidocaine with epinephrine (1:100,000) is injected into the palmar and dorsal subcutaneous tissues ( Fig. 64.11 ). If only a sensory block is required, a single subcutaneous dose of lidocaine and epinephrine is injected in the midline of the proximal phalanx (SIMPLE technique) ( Fig. 64.11A ). Lalonde and Wong recommend no more than 1 mL for distal phalangeal procedures. Although some studies support the safe use of up to 35 mg/kg of lidocaine with epinephrine, the accepted maximal dose is 7 mg/kg (50 mL for 150 lb patient).

FIGURE 64.11, Sites of injection of local anesthesia in finger and hand surgery. A, Volar injections. When only a sensory block of finger is required (SIMPLE technique), 2 mL are injected into the areas designated by the blue dots. To obtain hemostasis and local anesthesia for palmar finger surgery, 1% lidocaine with epinephrine 1:100,000 is injected into midline subcutaneous fat between digital nerve in each area designated by dot. B, Dorsal injections. For hemostasis and local anesthesia, injection is into midline subcutaneous fat in each area designated by dot. In both volar and dorsal injections, 2 mL are injected at site of blue and red dots, 1 mL at site of green dots, and 5 mL at site of the orange dots.

BOX 64.1

Tips for Administering WALANT (Lalonde & Wong 2013)

From: Steiner MM, Calandruccio JH: Use of wide-awake local anesthesia no tourniquet in hand and wrist surgery, Orthop Clin North Am 49(1):63, 2018.

▪
Pain during administration can be reduced by several methods:
- ▪
  Buffering the solution: a solution of lidocaine 1% with 1:100,000 epinephrine has a pH of 4.2, which likely contributes to the pain with injection. A 1:20 ratio of 8.4% sodium bicarbonate to lidocaine 1% with 1:100,000 epinephrine has a more physiologic pH of 7.4. A Cochrane review concluded that patients much preferred buffered lidocaine to unbuffered lidocaine; the difference was even more pronounced when the solution contained epinephrine.
- ▪
  Warming the solution.
- ▪
  Using a smaller needle (27- or 30-gauge or smaller).
- ▪
  Choosing the correct angle for needle insertion: A randomized, controlled crossover trial of 65 patients showed that injections with needles oriented at 90 degrees were significantly less painful than those with needles oriented at 45 degrees.
- ▪
  Injecting the solution under the dermis: In their double-blind, prospective trial, Arndt et al. found that subdermal injections produced less pain than intradermal injections. Strazar et al. suggested that this occurred because the space-occupying effect of the solution stretches the tissue, producing more pain in the densely innervated dermal tissue.

Some surgeons prefer bupivacaine to lidocaine because of its longer action, but intravascular bupivacaine has been associated with cardiotoxicity, and the pain block provided by bupivacaine lasts only half the time as the return to normal sensation. Pain while the area is still numb is a common complaint in patients. Adding epinephrine will prolong the pain relief but only for about 1.5 hours; patients should be informed that pain sensation will return before the numbness resolves. Using lidocaine, pain and sensation return at the same time, and most surgeries in the hand can be done within the anesthesia time provided by lidocaine with epinephrine (5 hours in the wrist, 10 hours in the finger). Bupivacaine can be used for procedures expected to last 3 hours, although pain may be severe thereafter.

Maximal vasoconstriction after injection of lidocaine with epinephrine can be expected at 25 minutes, after which time optimal visibility of the operative field is obtained. McKee et al. recommend waiting 30 minutes after injection before incision.

Preparation and Draping for Elective Surgery

Regardless of the procedure, the method of preparing and draping the upper extremity and hand should be the same. This helps to standardize the routine and allows movement about the operative field while minimizing the risk of bacterial contamination. The preparation of other areas for graft donor sites varies depending on the requirements of the procedure. If skin, tendon, bone, nerve, or other grafts are required, the patient should be positioned to allow easy access to the specific areas. Care should be taken to pad and protect neurovascular structures. The electrocautery grounding pads should be attached in a safe and secure manner. Usually, the hand and forearm are scrubbed before the time of the surgery. The hair is removed with electric clippers from the areas where skin incisions will be made on the hand, forearm, and elsewhere as needed; this often is done before the patient is transported to the operating room. A well-padded tourniquet is applied to the arm or the forearm, depending on the surgeon’s preference; however, it is not inflated until all preparations have been completed (unless a Bier block is being used). After the patient has been satisfactorily anesthetized, the hand and forearm are scrubbed by an assistant with an antiseptic solution of choice. Iodophor soaps and skin preparation solutions and combinations of chlorhexidine and alcohol have been found to be effective ( Table 64.3 ). A waterproof sheet is placed on the well-padded hand surgery table, followed by a sterile drape-sheet. Combinations of sterile towels and sheets are applied, leaving exposed the upper extremity and hand and other areas that may require access during the operation. The gloves used in preparation of the surgical field are removed, and the surgeon dons a gown and gloves and sits down, usually on the axillary side of the forearm. The operating lights are adjusted, and the skin incisions are outlined.

TABLE 64.3

Antiseptic Solutions

Adapted from Green DP: General principles. In Wolfe SW, Hotchkiss RN, Pederson WC, Kozin SH, editors: Green’s operative hand surgery , ed 6, Philadelphia, 2011, Elsevier.

Alcohol	Good immediate skin disinfectant, but dries quickly and has less long-term effect
Alcohol	95% alcohol better than 75% because of dilution by moist skin
Hexachlorophene (pHisoHex)	Forms a film that retains bacteriostatic properties
	Easily washed off
	Requires multiple applications to be effective
	May be toxic in infants
	Effective against gram-positive organisms; less effective against gram-negative organisms
Iodine	Side effects
Alcoholic (tincture)	Frequent skin irritation (can be lessened by adding iodine)
Aqueous (Lugol’s solution)	True allergic reactions
Iodophors (povidone-iodine [Betadine])	Advantages over iodine
Iodine and polyvinyl pyrrolidine or povidone	Slower release of iodine
	Fewer skin reactions
	Effective against gram-negative and gram-positive organisms
Chlorhexidine (Hibiclens) 70% alcoholic solution	Some studies have shown it superior to Betadine and pHisoHex
Chlorhexidine (Hibiclens) 70% alcoholic solution	Repeated washings may have a cumulative effect

Tourniquet

A bloodless field is essential for accurate dissection to avoid damaging small vital structures. The inherent dangers of tourniquet use are ischemia and its complications, including muscle contracture and nerve paralysis. Because the pressure can be monitored and controlled more reliably with a pneumatic tourniquet, complications are believed to be less likely with this type than with an elastic or rubber bandage tourniquet. Regardless of the tourniquet used, temporary or permanent disproportionate or prolonged edema, stiffness, diminished sensibility, and weakness or paralysis may result. Based on animal studies, Pedowitz et al. emphasized that biochemical, biomechanical, microvascular, and cellular mechanisms combine to produce significant neuromuscular injury from the use of tourniquets even at clinically allowable pressures and durations.

When operations are performed with the patient under local anesthesia and last less than 30 minutes, an elastic (Martin) bandage provides sufficient hemostasis and may be used safely. Wrapping of the bandage is begun at the fingertips and proceeds proximally on the forearm. It is applied in layers that overlap less than 5 to 6 mm. When the midforearm is reached, four or five layers of the elastic are overlapped. Wrinkles are avoided. The pressure is increased with each layer so that only moderate stretching is needed. The bandage is unwrapped, beginning distally, from the hand up to the midforearm. The overlapped layers in the midforearm are left in place until the operation is finished. For some procedures done with local infiltration or wrist block anesthesia, a pneumatic tourniquet can be used rather than an elastic wrap tourniquet. The tourniquet can be applied above or just below the elbow and left inflated 30 minutes without extreme discomfort.

Although the tourniquet is generally applied to the upper arm, several reports have indicated that forearm tourniquets are safe and reliable. The use of a forearm tourniquet with regional blocks has been reported to allow the dosage of local anesthetic to be decreased to almost half of that required with an upper arm tourniquet, and the frequency and severity of tourniquet pain have been reported to be less with a forearm tourniquet (procedures of 25 minutes or less or distal to the wrist with regional block). Both a longer duration of sensory block and prolonged postoperative analgesia have been described with the use of a forearm tourniquet.

The usual procedure for tourniquet application involves first the application of several layers of Webril wrapped smoothly around the middle of the upper arm near the axilla. The tourniquet is usually applied by the surgeon, an experienced assistant, or the anesthesiologist. Wrinkles are avoided because their presence may cause blisters, pinching of the skin, and necrosis. The limb is exsanguinated by elevation for 2 to 5 minutes or by wrapping with an elastic bandage about 10 cm wide beginning at the fingertips and proceeding to just distal to the tourniquet. With automatic tourniquets, inflation is usually rapid enough to avoid trapping excessive blood in the arm during inflation. Wrapping of the limb should be avoided in patients with infections in the limb or in whom malignant tumors are suspected. Instead, to allow venous drainage, the limb is elevated for 5 to 10 minutes. The tourniquet inflation pressure generally should not exceed 100 mm Hg systolic blood pressure for adults and children. The wider cuffs minimize focal compression of nerves beneath the cuff; however, smaller cuffs are required for children. When the tourniquet has been released, it and the underlying cotton wrapping should be removed to avoid venous congestion.

Improvements in design have resulted in the development of “automatic” pneumatic tourniquets that allow the setting of pressures within a safe range and for specific periods of time. Alarms notify the surgeon and anesthesiologist when the preset time has passed. Pneumatic tourniquets are available in several widths with Velcro strap fasteners. There is no absolute rule as to how long a tourniquet can remain safely inflated on the arm. The reports of most authors suggest that the “recovery time” or revascularization time between periods of tourniquet inflation is related to the length of time the tourniquet has been inflated ( Table 64.4 ). In practice, the usual limit is considered to be 2 hours. If this limit is exceeded, the risk of paralysis may be increased. Usually, if the operation lasts longer than 2 hours, the tourniquet is released for at least 15 minutes and the limb is elevated with minimal compression applied to the incisions with sterile dressings. The limb is again exsanguinated with an elastic wrap, and the tourniquet is reinflated.

TABLE 64.4

Tourniquet Time and Revascularization

From Wilgis EFS: Observations on the effect of tourniquet ischemia, J Bone Joint Surg 53A:1343, 1971.

Tourniquet Time	No. Patients	PH		P O ₂ (mm Hg)		P CO ₂ (mm Hg)
Tourniquet Time	No. Patients	Range	Mean	Range	Mean	Range	Mean
Preinflation		7.38–7.42	7.4	40–50	45	35–40	38
0.5 h	50	7.29–7.35	7.31	22–27	24	45–53	50
1 h	40	7.15–7.22	7.19	19–22	20	60–66	62
1.5 h	26	7.02–7.10	7.04	6–16	10	80–88	85
2 h	12	6.88–6.96	6.9	0–6	4	92–110	104

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