Volar Splinting

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Continuing Education Activity

Volar splinting of the upper extremity can be employed to immobilize hard and soft tissue injuries and painful atraumatic conditions. In general, splinting is useful for various conditions, including fractures, sprains, strains, reduced fracture-dislocations, and after extensive laceration repair. Splints allow for soft tissue swelling in the acute phase of healing. Volar splinting can immobilize and protect the affected upper extremity, facilitate healing, and decrease pain. Volar splinting is generally limited to short-term use to maximize benefits while minimizing complications. However, volar splinting for chronic conditions may assist the healing process, provide long-term pain control, and slow the progression of the underlying pathophysiological process. This activity reviews the indications, contraindications, complications, and technique of volar splinting and highlights the role of the interprofessional team in caring for patients with upper extremity injuries that may benefit from volar splinting.

Objectives:

  • Identify patients with upper extremity injuries or conditions who may benefit from volar splinting.
  • Differentiate clinical conditions that may prohibit volar splint placement.
  • Apply best practices when fabricating and placing a volar splint.
  • Develop and implement interprofessional team strategies to improve outcomes for patients with upper extremity injuries who undergo volar splinting.

Introduction

Volar splinting of the upper extremity can be employed to immobilize hard and soft tissue injuries in addition to painful atraumatic conditions. Hard tissue skeletal injuries that may benefit from volar splinting include distal radius fractures, Colles fractures, and metacarpal or carpal fractures, excluding fractures of the first metacarpal and trapezium. Basic splinting guidelines of skeletal pathology require immobilization of the joint above and below the lesion. Exceptions to this rule include metaphyseal fractures, such as Colles or Smith fractures; metaphyseal fractures behave like injuries within the joint. For more proximal shaft fractures, the principle of volar splinting expands into sugar-tong or Muenster-type splinting, extending above the elbow.[1][2] Other conditions amenable to volar splinting include acute gouty arthritis, carpal tunnel syndrome, and radial nerve palsy.

Splinting is an adjunct to elevation and ice. Splinting improves patient comfort, facilitates recovery, and protects from further injury. Splints may be used for comfort as a temporizing measure for wrist and hand dislocations or fracture subluxations while awaiting definitive care.[3] Splints differ from casts in that the noncircumferential bandage allows for some degree of soft tissue swelling without undue constriction. Splints can be easily removed for wound care. Splinting may be the definitive treatment or temporary treatment before casting. Although plaster is considered the traditional splinting material, padded fiberglass or preformed plastic splints are commonly encountered in clinical practice.[4]

Anatomy and Physiology

A fundamental principle of fracture immobilization with splinting is that a splint must extend from at least one joint above to one below the fracture. For example, when splinting a metacarpal fracture, the splint must extend from the mid-forearm above the wrist to beyond the metacarpophalangeal joints. The careful examination and dressing of wounds should precede splint application. The neurovascular status of the affected extremity must be assessed and documented before splint application.

Indications

Volar splinting may be indicated to immobilize hard tissue injuries such as distal radial or ulnar fractures and certain metacarpal or carpal fractures, excluding fractures of the first metacarpal or trapezium.[5] Soft tissue injuries that may benefit from volar splinting include extensive skin lacerations and structural injuries to tendons or ligaments.[6] A volar splint may provide symptomatic relief from inflamed, painful, but uninjured joints in patients with acute gout, active rheumatoid arthritis, or other painful inflammatory conditions.[7][8]

Contraindications

There are no specific contraindications to volar splinting. However, some clinical situations may warrant special consideration before placing a volar splint. Burns, open or contaminated wounds, or unstable fracture patterns must be carefully evaluated to determine if the benefits of a volar splint will outweigh the risks. If the affected limb is tense and edematous, monitoring for compartment syndrome and rapidly extending soft tissue inflammation or infection will be required, potentially making splinting less desirable.

Equipment

The following equipment is required when fashioning and placing a volar splint:

  • Plaster or padded fiberglass
  • Stockinette
  • Undercast or cotton padding
  • Cool water
  • Elastic bandage
  • Sling

Personnel

Volar splinting can be performed by appropriately trained personnel, including physicians, advanced practice providers, nurses, athletic trainers, or technicians. A single operator can perform the procedure.

Preparation

The clinical situation dictates the length of a volar splint. For a Colles or wrist fracture, the splint must extend from the distal palmar crease to 4 to 5 cm distal to the antecubital fossa. For metacarpal fractures, including Boxer fractures, the splint should extend beyond the metacarpophalangeal joint. For phalangeal fractures, the splint should extend beyond the tips of the digits.

In preparing equipment to place a volar splint, the operator must keep in mind that while plaster is more pliable than fiberglass, it does take longer to set. The hardening of the splint material occurs via an exothermic reaction. The amount of heat released during this reaction is proportional to the number of layers of casting material and the water temperature. When utilizing plaster for volar splinting, the layers of plaster should be limited to 12; 8 to 10 layers will usually suffice. Cool water allows time to mold the splint and reduces the risk of burn.

Technique or Treatment

Pain Management

The manipulation of acute fractures is painful. Using analgesics and anesthesia ensures comfort and muscle relaxation to reduce a fracture and apply a splint effectively.[9] Children are more likely to require general anesthesia than adults, most of whom will tolerate the procedure with regional anesthesia and adjunctive analgesia.[10] A viable substitute for regional anesthesia is the hematoma block.

To perform a hematoma block, insert a needle into the fracture site after palpating the fracture ends. Aspiration of blood and fat droplets confirms the correct position of the needle. Aspirate as much of the hematoma as possible. Inject 5 to 10 mL of local anesthesia into the fracture.[11] The hematoma will function as a fluid medium, allowing the anesthetic to diffuse within the fracture site. [12] However, most patients do not seek care until hours after the fracture, when the hematoma has already formed and cannot be aspirated. Hematoma blocks are not appropriate for patients with open fractures.[13]

Parenteral analgesics should be administered before and after fracture manipulation and splint application to relieve pain without significant sedation. Pain that persists after rest, splinting, elevation, and adequate analgesia may indicate compartment syndrome, which requires surgical consultation.

Fracture Reduction

The closed reduction of a displaced fracture requires initial distraction, deformity alignment by connecting the bone ends, and length stabilization. Sustained gentle traction that can stretch the soft tissue surrounding the fracture to realign the bony ends is required. The amount of traction applied should be greater than the magnitude of the muscle spasm. Translation of the bone ends during distraction allows fracture reduction.[14] By applying traction, intact tendons, muscles, and periosteum may immediately reduce regions of fracture comminution. Alternative fracture manipulation techniques are needed for displaced fractures with periosteal hinges and fractures that do not align with traction.[15][16] Alternative methods of fracture reduction involve simulating the injurious impact by worsening the deformity, disengaging fracture ends, and angulation correction using the distraction force.[17]

Positioning of the Affected Limb

Of the two forms of radioulnar joint instability, dorsal dislocations from a fall onto an outstretched hand are the most common. Volar dislocations are less common and occur with forceful supination.[18]

Distal extra-articular radius fractures with <5 mm of shortening and dorsal angulation of <5° require closed reduction and casting.[19] A Colles fracture demonstrates supination, dorsal tilt, and volar angulation of the distal radius.[20][21] The splinting posture of the affected extremity is pronation with slight palmar flexion and ulnar deviation to preserve fracture reduction and maintain a neutral wrist position. Excessive palmar flexion and ulnar deviation must be avoided. This position may induce increased stiffness in patients with degenerative joint disease. The position may raise carpal tunnel pressure. [22]  

Smith fractures commonly occur secondary to falling on a flexed wrist or a direct blow to the dorsal aspect of the wrist. The distal fragment exhibits volar displacement, dorsal angulation, and pronation in a Smith fracture. The splinting posture requires extension and supination of the wrist.[23] 

Unicortical fractures of the forearm and forearm fractures that are undisplaced or mildly displaced, characterized by less than 50% displacement and 10 degrees of angulation, are candidates for conservative management. Forearm fractures with volar angulation should be treated with immobilization in pronation, and those with dorsal angulation should be immobilized in supination.[24] The appropriate forearm rotation for immobilization will depend on the fracture location and any accompanying deforming forces. Fractures of the proximal third are splinted in supination, fractures of the middle third are immobilized in a neutral position, and fractures of the distal third are immobilized in pronation.[24]

Restoration of digital function after flexor and extensor tendon reconstruction remains one of the most challenging clinical and operative dilemmas in hand surgery. The posture of safe immobilization (POSI) is the appropriate position to immobilize the hand safely after a surgical procedure or injury. In the POSI, the wrist is dorsiflexed between 0 and 30°, the metacarpophalangeal joints are flexed between 70 to 90°, and the interphalangeal joints are fully extended.[25]

Splinting Technique

The neurovascular status of the affected limb should be assessed before splint application. Apply adequate stockinette and cotton undercast padding to prevent heat penetration. Extra padding over bony prominences, such as the ulnar styloid, and at the ends of the splint will help prevent pressure sores. The stockinette must cover the entire splint area and extend approximately 10 cm beyond either end of the planned splint location. A 2- to 3-in stockinette width is typically used for the upper limbs.[26] Wrap cotton padding concentrically around the extremity rolling from one end to the other, with each layer covering the preceding layer by 50%. This method automatically provides 2 layers of padding. The padding should reach 2 to 3 cm beyond the intended boundaries of the splint without being constrictive. To prevent regions of excessive wrinkling and subsequent pressure, joints should be put in their functional position before, during, and after applying padding. A 2- to 4-inch padding is typically used for the upper extremity.[27]

Plaster and synthetic casting materials are commonly used to splint fractures. Prepare a container of water at room temperature before starting the splinting procedure. Water that is too warm will hasten the setting process and shorten the time available for molding. The risk of severe skin burns increases with shortened set times. Cool water is encouraged if additional time is required for splint application. 

The side of the extremity contralateral to the fracture should be measured to calculate the necessary length of the casting material. When creating a plaster splint, fold the plaster into layers and dip it into the container of water at an angle of 45 degrees. Completely immerse the plaster. Once the bubbling ceases, the plaster may be removed from the water. Squeeze out the excess water using longitudinal compression massage. If the splinting material is too long, the edges may be folded over to achieve the desired length. For an average-sized adult, an upper extremity splint will require approximately 10 layers of casting material.[28] The splint will generate more heat and weigh more if excess sheets are used.[29]

The sugar-tong splint is an appropriate treatment option for forearm and distal radius fractures. The sugar-tong splint originates at the distal palmar crease and extends along the volar forearm, around the elbow to the dorsum of the metacarpophalangeal joints.[30] An alternative upper extremity splint is the long arm posterior splint that extends from the axilla over the posterior surface of the 90-degree flexed elbow and along the ulna to the proximal palmar crease.[31] 

The elastic wrap holds the splint in place and should be applied to accommodate soft tissue swelling but limit movement. Neurovascular status should be reassessed after splint application. A sling is used for elevation and protection. (see Images. Volar Splint and Volar Splint Side View)

Splinting Aftercare

The length of immobilization and time to reevaluation varies greatly depending on the location, nature, and stability of the fracture. Each injury must be evaluated, handled, and monitored individually. Instruct the patient to keep the splint clean and dry. The extremity should be elevated, and an ice pack applied to the splint for 20 minutes every few hours. If the fingers become cold, blue, numb, or painful, the patient should seek medical attention. Removal of the splint allows for wound care in some cases.[32][1] 

Complications

Complications of volar splinting include joint stiffness, thermal burns, pressure ulcers, wound infections, and compartment syndrome.   

Clinical Significance

Volar splinting is a valuable technique for managing traumatic and atraumatic conditions of the hand and wrist. The splint immobilizes and supports the metacarpals and carpals while allowing room for swelling. The splint can be removed to examine wounds that may accompany the injury.[1]

Enhancing Healthcare Team Outcomes

Healthcare professionals can work as an interprofessional team to improve outcomes for patients who require volar splinting by utilizing collaborative communication and a patient-centered approach. Not all patients with injuries to the upper extremity are candidates for volar splinting. Each healthcare team member should actively ensure that the patient understands and is willing to participate in the care and monitoring of their volar splint before it is placed. While volar splinting may be the definitive therapy for some clinical conditions, most patients require a follow-up appointment within 1 week. Patient education is imperative as the patient will be responsible for caring for their splint in the interim.



(Click Image to Enlarge)
<p>Volar Splint Side View</p>

Volar Splint Side View


Contributed by Tammy J Toney-Butler, RN, CEN, TCRN, CPEN


(Click Image to Enlarge)
<p>Volar Splint</p>

Volar Splint


Contributed by Tammy J Toney-Butler, RN, CEN, TCRN, CPEN

Details

Updated:

7/19/2023 1:48:00 AM

References


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