A cervical collar, also known as a neck brace, is a medical device designed to support and immobilize the neck by encircling it, thereby stabilizing the cervical spine to prevent further injury or promote healing.[1][2] These devices have historically been a standard component of prehospital trauma care for immobilizing the neck in suspected spinal injuries during emergency transport, though current guidelines recommend selective use based on clinical assessment to minimize risks.[3]Cervical collars are primarily used to limit neck movement and protect the spinal cord in cases of acute trauma with suspected bony injury, such as fractures or dislocations; for whiplash-associated disorders, use is limited or discouraged to avoid delaying recovery. They also aid recovery after cervical spine surgery, for conditions like cervical spondylosis, nerve compression, or chronic neck pain.[2][4] In non-traumatic scenarios, they provide support for muscle strains or spasms and can offer psychological reassurance by restricting motion that might exacerbate pain.[1] However, prolonged use beyond 10 days is generally discouraged for conditions like whiplash due to limited evidence of promoting recovery and potential risks.[2]There are several types of cervical collars, varying in rigidity and material to suit different levels of immobilization needs:While effective for short-term protection, cervical collars carry risks including muscle atrophy, stiffness, or dependency with extended wear; they may also complicate breathing or increase intracranial pressure in certain patients.[4] Proper fitting is crucial to avoid complications like airway obstruction, and users are advised to maintain neutral posture, avoid heavy activities, and follow medical guidance for weaning off the device.[1] Current guidelines stress early removal of collars once injury is ruled out to mitigate these risks.[5]
Fundamentals
Definition and Purpose
A cervical collar is a medical device designed to support and immobilize the neck by encircling it and restricting head and neck movement, thereby stabilizing the cervical spine.[1] It serves as a non-invasive orthosis that maintains the head in a neutral position to protect the spinal cord from potential damage.[6]The primary purpose of a cervical collar is to prevent further injury to the cervical spine and spinal cord, particularly in cases of trauma, by limiting motions such as flexion, extension, rotation, and lateral bending of the neck.[2] This immobilization helps reduce the risk of secondary neurological damage by minimizing unintended movements that could exacerbate instability in the upper vertebrae.[4]Cervical collars are commonly used in emergency trauma responses, such as those following motor vehicle accidents, to safeguard the spine during initial assessment and transport.[2] They also provide post-surgical support after procedures involving the neck to promote healing while restricting motion.[6] Additionally, they aid in managing chronic conditions, including whiplash-associated disorders and degenerative disc disease, by offering temporary relief and stability.[4]In terms of basic mechanics, the cervical collar achieves immobilization by supporting the chin and occiput, which distributes gravitational loads and limits shear forces and axial compression on the vertebrae from C1 to C7.[1] This restriction decreases the transmission of forces through the cervical spine, thereby reducing strain on ligaments, discs, and neural structures during the healing process.[6]
Relevant Anatomy
The cervical spine, the uppermost segment of the vertebral column, comprises seven vertebrae designated C1 through C7. The first vertebra, C1, is known as the atlas, a ring-like structure that articulates with the skull and lacks a vertebral body, while the second, C2 or axis, features a prominent odontoid process (dens) that allows rotational movement of the head. Vertebrae C3 to C7 are more typical in form, each consisting of a vertebral body, pedicles, laminae, and spinous processes that form the vertebral arch. Between the vertebral bodies lie fibrocartilaginous intervertebral discs, which provide cushioning and permit flexibility, and the spinal cord traverses the central vertebral canal formed by the stacked vertebrae, protected by the surrounding bony and ligamentous structures.[7][8]Key stabilizing ligaments include the anterior longitudinal ligament, a strong fibrous band that spans the anterior surfaces of the vertebral bodies and intervertebral discs from the base of the skull to the sacrum, limiting hyperextension and reinforcing disc integrity. Other ligaments, such as the posterior longitudinal ligament within the vertebral canal and the ligamentum flavum between laminae, further maintain alignment and protect the spinal cord. Spinal nerves emerge from the spinal cord at each cervical level—C1 to C7 roots exit above their corresponding vertebrae, while C8 exits below C7—forming eight pairs that innervate the upper body; for instance, C3-C7 nerves supply motor and sensory functions to the shoulders, arms, and diaphragm, making injuries at these levels potentially disruptive to upper extremity and respiratory control.[9][10][11]The cervical spine's high degree of mobility, essential for head and neck movements, renders it vulnerable to trauma, with risks including fractures, dislocations, and spinal cord compression that can lead to neurological deficits. This segment's relatively small vertebral size compared to the loads it bears, combined with its transitional role between the stable skull and mobile thorax, heightens susceptibility during high-impact events. Normal biomechanics allow approximately 50-60° of flexion (forward bending) and 70-80° of extension (backward bending), alongside lateral flexion and rotation, but excessive motion beyond these ranges—such as in hyperflexion from sudden deceleration or hyperextension from rear impacts—can destabilize the structure, stretch ligaments, or impinge the cord, resulting in instability or permanent damage.[12][13][14]
Types and Design
Soft Collars
Soft collars, also known as flexible or foam collars, are constructed from foam rubber, typically polyurethane foam encased in a soft fabric cover such as cotton stockinette for enhanced comfort and breathability.[15][16] These collars feature a contoured design that molds around the neck, supporting under the chin and jaw while permitting limited head movement; they are lightweight, often secured with Velcro fasteners at the rear for adjustability.[15]Soft collars are indicated for minor cervical strains, whiplash-associated disorders during early recovery, and short-term relief of chronic neck pain, providing a gentle reminder to avoid excessive motion without restricting daily activities.[16][17] They are suitable for use up to 10 days for symptom management in non-traumatic neck pain but are not recommended for severe injuries requiring immobilization.[18]The primary advantages of soft collars include providing warmth to the neck area, offering psychological reassurance to patients, and serving as a kinesthetic cue to limit neck motion, with studies showing they reduce flexion and extension by 8-26%, lateral bending by approximately 8%, and rotation by 10-17%.[15][16] However, they offer no true structural support to the cervical spine and are insufficient for full immobilization, potentially leading to muscle weakening or dependency with prolonged wear; evidence also suggests they may prolong symptom persistence in whiplash cases.[15][17] Unlike rigid collars, soft collars permit greater neckmobility, making them preferable for mild, non-emergency support.[15]
Rigid and Specialized Collars
Rigid cervical collars are constructed from inflexible materials to provide maximum stabilization of the cervical spine, typically featuring a hard plastic shell that encases the neck and supports the head. Prominent models include the Aspen collar, made of polyethylene with adjustable chin and occiput supports, a tracheostomy opening, and ventilation features to minimize skin pressure and promote airflow.[15] Similarly, the Miami J collar utilizes polyethylene construction with customizable height adjustments via interlocking components, occipital padding, and a mandibular shelf to restrict flexion, extension, lateral bending, and rotation effectively.[15] The Philadelphia collar, formed from two-piece plastizote foam—a rigid closed-cell polyethylene—forces motion restriction up to 75% in flexion/extension, though it may limit ventilation and increase risks of skin irritation.[15] These designs distribute pressure evenly across contact areas, often incorporating removable foam liners for hygiene and compatibility with imaging like MRI or CT scans.[19]Specialized variants extend immobilization beyond the neck for more severe instabilities. The halo vest consists of a metal ring fixed to the skull via four pins, connected by uprights to a rigid thoracic vest, achieving near-total motion restriction (up to 99% in rotation) down to the T3 level.[15][20] The Philadelphia collar is adapted for pediatric use, with scaled sizing for children under 12 to support neck muscles post-injury while allowing growth accommodation.[19] The sternal-occipital-mandibular immobilizer (SOMI) brace features a three-poster frame with sternal and posterior plates extending to the xiphoid process, limiting motion primarily in the upper cervical segments (C1-C5).[15][20] The Minerva brace, often constructed from rigid plastic or, in pediatric cases, plaster casts, envelops the head, neck, and upper thorax with a forehead strap and posterior shell for control below C1, offering a lighter alternative to the halo for mid-to-lower cervical injuries.[15][21] Thermoplastics like polyethylene provide the primary rigidity.[15]Emerging designs as of 2025 include smart collars integrating motion sensors for real-time monitoring of neck movement and 3D-printed collars for personalized fit and improved comfort.[22][23]These collars are indicated for severe trauma, such as odontoid or hangman's fractures, occipital condyle injuries, and Jefferson fractures, where they immobilize the spine to prevent displacement. Post-operatively, they stabilize the cervical region following procedures like anterior cervical discectomy or fusion, promoting fusion and reducing deformity risk.[19] In contrast to soft collars, which prioritize comfort for milder strains, rigid and specialized collars deliver near-total motion restriction essential for critical cases.[19]
Clinical Application
Indications and Contraindications
Cervical collars are primarily indicated for suspected cervical spine injury in trauma scenarios, including unconscious patients, those with significant neck pain, tenderness, or neurologic deficits such as paresthesia or weakness, to restrict motion and prevent secondary spinal cord injury.[5] In prehospital care, they provide initial spinal motion restriction for all trauma patients with a mechanism suggestive of cervicalinjury until formal evaluation and clearance can occur.[3] Additionally, short-term use (up to 2 weeks) may support conservative management of non-traumatic conditions like cervical herniated discs, often combined with rest, anti-inflammatory medications, and physical therapy to reduce pain and promote healing.[18]Patient selection emphasizes application in high-risk cases, such as those with altered mental status, intoxication, or distracting injuries, while prioritizing prompt clearance to minimize complications from prolonged immobilization.[25] Collars should be maintained until clinical assessment or advanced imaging, such as high-resolution CT scans interpreted by a radiologist or spine specialist, confirms no injury, particularly in obtunded or unreliable patients.[25] Modern protocols advocate removal as soon as feasible, ideally within 24-48 hours, transitioning to padded long-term collars if extended use is required.[26]Evidence-based decision tools guide appropriate use and clearance. The NEXUS criteria identify low-risk patients (no midline cervical tenderness, no intoxication, normal alertness, no focal neurologic deficits, no painful distracting injuries) who can safely forgo imaging and collar application if alert and stable.[27] Similarly, the Canadian C-spine rule applies to alert, stable trauma patients, recommending imaging and collar use only if high-risk factors (e.g., age ≥65 years, dangerous mechanism, extremity paresthesia) are present or low-risk criteria (e.g., ability to rotate neck ≥45 degrees, no midline tenderness) are not met.[28] These rules reduce unnecessary collar application in low-risk cases, with the Canadian rule showing higher sensitivity (99.6%) compared to NEXUS (90.7%) for clinically important injuries.[29]Contraindications include penetrating necktrauma, active airway compromise, or surgical airways, as the collar can interfere with hemorrhage control, ventilation, or surgical access.[30] Per current guidelines, collars are inadvisable for alert, asymptomatic patients without neck pain, tenderness, or limited range of motion, as immobilization offers no benefit and increases risks like pressure sores or muscle atrophy.[5] Relative contraindications encompass severe claustrophobia, which may induce anxiety and agitation, potentially necessitating alternative motion restriction techniques.[31]
Fitting and Application Procedure
Before applying a cervical collar, healthcare providers must first assess the patient's airway and circulation to ensure stability, followed by establishing manual in-line stabilization of the cervical spine to minimize movement.[32] This preparation is critical in trauma settings where spinal motion restriction is indicated for suspected cervical injury.[33]The application procedure typically involves a two-person technique for safety and precision. First, measure the neck circumference or length from the shoulder to the chin to select the appropriate collar size, ensuring it supports the occiput and mandible without gaps.[32] With manual stabilization maintained, slide the posterior portion of the collar under the patient's head while keeping the neck in neutral alignment.[34] Next, position the anterior portion to support the chin, fold any chin section if required, and secure the Velcro straps or locks, adjusting for a snug fit that maintains neutral alignment without excessive pressure.[34] Finally, verify the collar's fit by checking for limited cervical motion and no skin impingement before releasing stabilization.[32]Special considerations apply for pediatric patients, where collars must be sized appropriately for smaller necks, often requiring additional padding under the shoulders or occiput to account for the proportionally larger head-to-body ratio and prevent flexion.[35] Avoid over-tightening in all cases to prevent compression of the jugular veins or airway compromise, ensuring one finger can fit between the collar and skin.[35]Removal of the cervical collar should only occur after clinical clearance, such as via the Canadian C-Spine Rule for alert patients meeting low-risk criteria, or confirmation of spinal stability through high-quality CT imaging without evidence of injury.[36] In cases of obtunded patients or imaging discrepancies, consultation with a spinal specialist is required prior to removal.[36]
Care and Complications
Maintenance and Hygiene
Proper maintenance and hygiene of cervical collars are essential to prevent skin infections, ensure device integrity, and promote patient safety during use. For foam or padded collars, such as those with soft liners, cleaning involves hand washing the pads with mild soap and warm water, followed by thorough rinsing to remove all soap residue.[37] Avoid machine washing, dryers, bleach, or harsh detergents, as these can degrade the materials; instead, gently squeeze excess water using a towel and allow the pads to air dry completely on a clean surface to inhibit mold growth.[37][38] Rigid plastic components should be wiped with mild soap and water if soiled, without submerging to prevent damage to structural elements, and dried thoroughly with a towel.[37]Regular inspection routines help identify potential issues early. Users should check the collar weekly for signs of wear, such as cracks in the plastic frame, fraying straps, or loosening Velcro fasteners, and replace the device immediately if any damage is found to maintain immobilization efficacy.[39] Prior to each application, inspect for soiling, faults, or deformation, and document findings as part of routine care protocols.[39] Additionally, collars should be designated for single-patient use to minimize cross-contamination risks in clinical settings.For storage, keep cervical collars in a cool, dryenvironment away from direct sunlight and extreme temperatures to preserve material integrity and prevent degradation.[38] After cleaning, ensure the device is fully dry before storing to avoid moisture-related issues like bacterial growth.Cervical collars are intended for short-term use, typically ranging from days to a few weeks depending on the injury, with guidelines recommending removal as soon as clinically feasible—ideally within 24 hours for trauma clearance if no instability is present—to reduce risks like pressure ulcers.[25] During wear, monitor skin integrity under the collar at least every 8-12 hours by removing it briefly under supervision, cleansing the area with mild soap and water, and inspecting for redness or breakdown. Poor hygiene practices, such as inadequate cleaning, can exacerbate risks of skin complications addressed elsewhere.
Potential Risks and Side Effects
Prolonged use of cervical collars can lead to common risks such as pressure ulcers, particularly on the occipital protuberance and chin due to sustained pressure from immobilization.[40] Up to 33% of hospital-acquired pressure ulcers may result from medical devices like cervical collars.[41] These devices have also been associated with increased intracranial pressure, potentially caused by venous outflow obstruction in the neck.[42] Additionally, cervical collars can reduce pulmonary function, with studies showing significant decreases in lung capacity and spirometry parameters like forced vital capacity in trauma patients.[43]Dysphagia is another frequent issue, as collars may restrict laryngeal movement and alter swallowing mechanics, elevating the risk especially in geriatric populations.[44]More serious complications include aspiration pneumonia, which arises from dysphagia-induced aspiration and is a leading cause of morbidity in patients with cervical injuries wearing collars.[44]Venous thrombosis, such as deep veinthrombosis, can occur due to immobility and prolonged collar use restricting venous return.[26]Muscle atrophy may develop from extended immobilization, leading to secondary damage in neck muscles and reduced strength.[18]To mitigate these risks, regular skin checks and repositioning of the collar are essential to alleviate pressure points and prevent ulcers.[45] Use should be limited to necessary periods to minimize complications like atrophy and thrombosis, with collars contraindicated or challenging in conditions like obesity due to poor fit and inadequate spinal control through excess soft tissue.[19] Proper hygiene practices can further reduce infection risks from skin breakdown.[45]Monitoring for signs of distress, such as skin redness, breakdown, or respiratory changes, is critical; immediate adjustment or removal of the collar may be required to prevent progression to severe complications.[41]
Historical Development
Invention and Early Adoption
The modern cervical collar was invented in 1966 by George W. Cottrell, who patented a device designed to immobilize the neck following trauma, featuring adjustable members with inflatable pneumatic casings along the edges for customizable support to the chin and neck.[46] This innovation emerged during the Vietnam War era, initially aimed at providing neck support for soldiers with suspected cervical trauma during evacuation.[47]In the post-Vietnam period, the device's adoption gained momentum through the advocacy of orthopedic surgeon Dr. J.D. Farrington, who in 1967 published "Death in a Ditch" in the Bulletin of the American College of Surgeons, emphasizing the need for immediate spinal immobilization in trauma cases to prevent secondary injuries during extrication and transport. Drawing from battlefield experiences and civilian accident reports, Farrington promoted the collar's use in emergency medicine, particularly for battlefield and roadside injuries where improper handling exacerbated spinal damage.[48] Early integration focused on prehospital settings, marking a shift toward standardized trauma protocols. Military medical reports from Vietnam highlighted spinal injuries in evacuations, influencing civilian protocols.By the late 1960s, initial rigid collar designs began appearing, building on Cottrell's framework with stiffer materials for enhanced immobilization, though soft foam variants predominated initially.[49] Widespread prehospital adoption accelerated in the 1970s, with cervical collars becoming standard equipment in ambulances following endorsements from organizations like the American Academy of Orthopaedic Surgeons in 1971, which recommended their pairing with long spine boards for suspected spinal injuries.[50]This development was driven by rising data on spinal injuries from motor vehicle accidents, which accounted for a significant portion of trauma cases in the 1960s, highlighting the risks of neck movement during rescue and underscoring the need for reliable immobilization tools.[51] Studies from the era, including analyses of crash fatalities, revealed that cervical fractures contributed to approximately 20% of in-car deaths, prompting urgent innovations in emergency response.[52]
Evolution and Modern Advancements
The evolution of cervical collars in the late 20th century marked a significant shift toward more effective immobilization through the adoption of rigid plastic materials. In the 1970s, the introduction of semi-rigid, two-piece designs like the Philadelphia collar, invented in 1971 by Anthony Calabrese and Frank Gramaglia, revolutionized emergency response by providing superior stability compared to earlier foam-based options, allowing for quicker application while maintaining spinal alignment.[53] By the 1980s, widespread use of high-density polyethylene and other thermoplastics further enhanced durability and rigidity, reducing the risk of secondary injury in trauma patients and becoming a standard in prehospital care protocols.[54]Entering the 2000s, advancements focused on improving patient comfort and compliance through ventilated and lightweight composite materials. Designs incorporating open-cell foam and breathable liners, such as those in the Aspen and Miami J collars, were developed to minimize skin irritation and heat buildup during prolonged wear, addressing limitations of earlier rigid models.[55] These composites, often combining rigid polymers with porous fabrics, reduced overall weight compared to 1980s predecessors, facilitating better airflow and extended use in clinical settings.[56]Contemporary innovations have integrated advanced materials and technology to enhance customization and monitoring. Antimicrobial fabrics, such as those laminated onto breathable foam in collars like the Breg Pinnacle, inhibit bacterial growth and reduce infection risks associated with extended immobilization.[57] Post-2020 developments include 3D-printed collars using biocompatible polylactic acid for patient-specific fits, weighing as little as 60 grams and tailored via CT scans for precise support.[58] Emerging smart collars embed motion sensors, like accelerometers and gyroscopes, to track neck movements in real-time, aiding rehabilitation by alerting users to improper postures.[59]Changes in clinical usage reflect growing evidence on immobilization risks, leading to more selective application. By the 2010s, guidelines from organizations like the National Association of EMS Physicians recommended against routine cervical collar use in low-risk trauma cases, emphasizing selective immobilization based on tools like the NEXUS criteria to avoid complications such as pressure ulcers.[60] Integration with backboards was largely phased out in favor of spinal motion restriction techniques, as studies highlighted respiratory compromise and discomfort from combined devices.[51]As of 2025, adjustable modular designs represent the latest innovations, featuring interchangeable components and dynamic adjustment mechanisms for optimized fit and reduced complications. These collars, with features like sizing tracks and removable pads, improve comfort and compliance while maintaining immobilization efficacy, particularly in outpatient and rehabilitation contexts.[61]
A randomized controlled trial conducted by Kuijper et al. in 2009 involving 205 patients with recent-onset cervical radiculopathy demonstrated that the use of a semi-hard cervical collar for three to six weeks led to a clinically relevant reduction in neck and arm pain compared to a wait-and-see policy, with significant improvements observed at the six-week follow-up.[62] Similarly, Sundstrøm et al.'s 2014 critical review of prehospital cervical collar application in trauma patients highlighted its role in standard trauma care protocols, noting potential benefits in stabilizing the cervical spine during transport to prevent exacerbation of injuries, though it emphasized the need for evidence-based refinement in application.Clinical effectiveness studies indicate that cervical collars reduce the risk of secondary spinal cord injury in patients with unstable cervical spines by limiting inadvertent motion, particularly in cases of fracture or dislocation.[22] However, in alert and cooperative patients without neurological deficits, the benefit is limited, as collars primarily serve as a kinesthetic reminder rather than achieving full immobilization.[63] Comparative studies show rigid collars provide greater flexion-extension restriction (approximately 50-60%) compared to soft collars (around 10-30%), with variations across types and studies, influencing their suitability for different injury severities.[64]Outcomes from key trials reveal improved neurological preservation in patients with cervical fractures when collars are used for initial stabilization, as evidenced by improved neurological outcomes in immobilized patients.[22] Nonetheless, retrospective analyses of trauma cohorts have found no significant mortality benefit associated with cervical collar use, particularly among alert patients with Glasgow Coma Scale scores greater than 8.[65]Research gaps persist, particularly in the need for randomized controlled trials post-2022 evaluating long-term collar use beyond six weeks and comparisons with alternatives such as vacuum splints, which may offer superior motion restriction without the same risks of skin pressure in prolonged applications.[66]
Controversies and Current Guidelines
The use of cervical collars in emergency medicine has sparked significant debate, particularly regarding their routine application in low-risk trauma cases where potential complications may outweigh benefits. Critics argue that collars provide minimal protection against secondary injury while increasing risks such as pressure ulcers, airway compromise, and elevated intracranial pressure, leading to calls for more selective implementation.[67][68] The 2019 International Trauma Life Support (ITLS) position paper explicitly advises against routine prehospital use of cervical collars for awake, alert patients without neurological deficits or focal injuries, emphasizing a patient-centered approach to avoid unnecessary interventions.[67]Current standards from major organizations prioritize selective application over blanket immobilization. The National Highway Traffic Safety Administration (NHTSA) and American College of Surgeons (ACS) protocols, aligned with joint position statements from the ACS Committee on Trauma (COT), American College of Emergency Physicians (ACEP), and National Association of EMS Physicians (NAEMSP), recommend using clearance tools such as the NEXUS criteria or Canadian C-Spine Rule to identify low-risk patients who can forgo collars.[33][26] These guidelines, updated through 2022 with ongoing endorsements into 2023, stress application only in cases of altered mental status, midline tenderness, focal neurology, or distracting injuries, and advocate for prompt removal based on negative helical CT imaging.[26] In penetrating trauma, proposals in various regions, including ITLS and NAEMSP recommendations, effectively ban routine collar use, citing no evidence of benefit and potential harm from delayed hemorrhage control.[67][33]Alternatives to traditional collars are increasingly promoted to achieve spinal motion restriction (SMR) with fewer risks. Guidelines favor manual stabilization during extrication, followed by devices like scoop stretchers, vacuum splints, or padded long backboards, reserving collars for short-term use only when necessary.[33][68]As of 2025, emergency medicine protocols emphasize enhanced training for EMS providers to minimize collar-related harms through evidence-based decision-making, while debates continue in journals over the pathophysiology of delayed neurological injury and the true efficacy of immobilization devices.[68][66]
Non-Medical Uses
Sports and Recreation
In motorsports, particularly motocross and off-road racing, specialized cervical collars known as neck braces are widely adopted to absorb impact forces and prevent basilar skull fractures during crashes. These devices, such as the EVS RC Evolution and Leatt Brace series, transfer kinetic energy from the helmet to the rider's shoulders and torso, reducing axial loading on the cervical spine. Their primary function is to limit excessive head and neck motion, thereby mitigating risks of severe trauma in high-velocity falls common to these sports.Neck brace designs in motorsports often feature hybrid constructions combining rigid composite materials like polyamide or carbon fiber with foam padding for energy absorption, including shoulder attachments that integrate with chest protectors for stability. Some models incorporate helmet risers or direct contact points to enhance whiplash reduction by bridging the gap between the helmet and brace during impacts. These adaptations prioritize lightweight construction—typically under 1 kg—to avoid hindering rider mobility while providing targeted protection.[69]Evidence from a 10-year retrospective study by Great Lakes EMS on motocross incidents indicates that neck brace adoption since the early 2000s has significantly lowered cervical spine injury rates, with 26 injuries among brace wearers compared to 239 without, and only one fatality with a brace versus four without. Biomechanical research demonstrates that effective brace-helmet interaction can dissipate up to 50% of impact forces to the neck, establishing their role in reducing off-road racing fatalities. In other sports, cervical collars see limited application, primarily for precautionary support during recovery in American football and equestrian events, where they aid in stabilizing minor strains without routine preventive use.[70][71][72]
Other Applications
Cervical collars have been explored for therapeutic purposes beyond primary injury stabilization, such as providing symptom relief in conditions like cervical radiculopathy. In cases of acute cervical radiculopathy, short-term use of a soft cervical collar can offer temporary pain reduction by limiting neck motion and supporting the cervical spine, with studies indicating reduced pain with their use.[18] A 2009 randomized trial further demonstrated that a semi-hard cervical collar led to statistically significant and clinically meaningful reductions in arm and neck pain compared to a wait-and-see approach, though long-term benefits remain unproven.[73] Similarly, for obstructive sleep apnea, cervical collars have been investigated to optimize head positioning during continuous positive airway pressure (CPAP) therapy or to promote head extension, potentially reducing apnea-hypopnea events; however, evidence is limited, with pilot studies showing mixed tolerability and efficacy in moderate cases.[74][75]In everyday settings, cervical collars are adapted for non-clinical comfort and support. During travel, such as long flights or drives, cervical collars provide necksupport to prevent strain and head nodding, functioning similarly to specialized pillows by stabilizing the cervical region for improved comfort.[76]Veterinary applications extend cervical collar use to animals, particularly dogs, for stabilizing neck injuries or post-surgical recovery. Devices like the Balto Neck brace offer rigid support for conditions such as cervical hernias or intervertebral disc disease, limiting head and neck movement to promote healing while allowing mobility.[77] Similarly, the BiteNot collar serves as a protective alternative to Elizabethan cones, preventing pets from accessing surgical sites on the neck or body without restricting vision or breathing.[78]Despite these applications, cervical collars are not intended as substitutes for medically prescribed devices, and non-medical misuse can lead to adverse effects. Prolonged or improper use may weaken neck muscles, increase stiffness, and raise risks of aspiration or elevated intracranial pressure, potentially exacerbating rather than alleviating discomfort.[4][79] In non-therapeutic contexts, such as casual wear, they should be avoided to prevent dependency and secondary injuries.[80]