Back brace
A back brace is a device designed to limit the motion of the spine in cases of fracture or in post-operative fusions, as well as a preventative measure against some progressive conditions.
Common back braces include:
- Rigid (Hard) braces : These braces are form-fitting plastic molds that restrict motion by as much as 50%; and
- Soft braces : Elastic braces that limit forward motion of the spine and assist in setting spinal fusions or supporting the spine during occasions of stress (for example, employment requiring the lifting of heavy loads).
Bracing for scoliosis
Back braces are also commonly prescribed to treat adolescent idiopathic scoliosis, as they may stop the progression of spinal curvature in a growing child/adolescent. As of 2016, the Scientific Society on Scoliosis Orthopaedic and Rehabilitation Treatment (SOSORT) recommends bracing "is important, but does not have to be applied to all patients with this specific need"[1] for idiopathic scoliosis during growth. Multiple studies have provided strong evidence of bracing as an effective conservative treatment for children and adolescents and may also help decrease the amount of curvature in the spine;[2] with results lasting several decades following the end of treatment and brace weaning.[3] A variety of brace styles are available; the Boston brace is the most commonly used brace for adolescent idiopathic scoliosis (AIS). It is important to note that in-brace correction has been found to be directly related with treatment success,[4] suggesting in-brace correction should be maximized; thus individualized custom braces which maximize in-brace correction show better results. Other designs include the Milwaukee brace, the Charleston bending brace, the Peak Scoliosis Bracing System, and the SpineCor (a soft brace) in the United States, Canada and Europe. In Europe, however, the SPoRT and Cheneau and Crass Cheneau braces are also used. There has been considerable research and information published in reputable journals on back braces for scoliosis. Issues like patient compliance with treatment, psycho-social impact of brace use, and exercise with bracing have been looked at. Quality of Life research has been attempted, but is difficult due to a current lack of instruments. Bracing is the primary treatment for AIS in curves that are considered to be moderate in their severity and are likely due to progress (determined by curve pattern/type and the patient's structural maturity).
One large issue in bracing for scoliosis is patient compliance, as mentioned above. Compliance is often impacted by the other above-mentioned factors (psycho-social comfort, exercise), but there are others also, including ability to eat and move, pain, and physical deformation. Back braces, especially the Boston brace, puts a great deal of pressure on the abdomen and can make digestion uncomfortable. Scoliosis braces, like those used for correcting post-operatively and for fractures, inhibit motion to a large extent, though percentages are difficult to find. Patients frequently complain about the inability to tie their own shoes, sit on the floor, etc. Bracing is also painful, though the body can adapt to tolerate the pain. Braces can also deform the patient's existing bone structures, most notably the hips, though there have been complaints about rib cage deformities as well.
Boston brace
A Boston brace is a form of thoracolumbosacral orthosis (TLSO). It is the most commonly used brace in the United States. It is a symmetrical brace. It corrects curvature by pushing with small pads placed against the ribs, which are also used for rotational correction (here it tends to be slightly less successful, however). These pads are usually placed in the back corners of the brace so that the body is thrust forward against the brace's front, which acts to hold the body upright. The brace opens to the back, and usually runs from just above a chair's seat (when a person is seated) to around shoulder-blade height. Because of this, it is not particularly useful in correcting very high curves. It also does not correct hip misalignment, as it uses the hips as a base point. This brace is typically worn 20–23 hours a day.
Charleston bending brace
This brace was designed with the idea that compliance would increase if the brace were worn only at night. It is asymmetrical. The brace fights against the body's curve by over-correcting. It grips the hips much like the Boston, and rises to approximately the same height, but pushes the patient's body to the side. It is used in single, thoracolumbar curves in patients 12–14 years of age (before structural maturity) who have flexible curves in the range of 25–35 Cobb degrees.
Chêneau-Gensingen Brace (CGB)
This brace is designed for use with the Schroth physical therapy method. It utilizes large, sweeping pads to push the body against its curve and into blown out spaces. The Schroth theory holds that the deformity can be corrected through retraining muscles and nerves to learn what a straight spine feels like, and breathing deeply into areas crushed by the curvature to help gain flexibility and to expand. The brace helps patients to keep doing their exercises throughout the day. This brace is asymmetrical, and is used for patients of all degrees of severity and maturity. It is often worn 20–23 hours a day. The brace principally contracts to allow for lateral and longditutal rotation and movement.
Crass Cheneau Brace
The new dynamic asymmetric brace Crass Cheneau is made of special hypoallergenic polypropylene, 2 to 3 mm. of thickness, semi-transparent when applied on the patient's body. Laser scanner technique or the use of plaster tape at lordosis position are required to estimate the size of the patient's body. Regarding the mechanic principles of the brace, special attention was paid to the functional importance of some vertebras that play predominant role for the maintenance of standing position (according to Delmas).
Its use ranges between 12 and 16 hours/day. Its effectiveness lies to the arrays surrounding pressures to the digital preform and the cuneiform adhesions on the structure of one and only typical vertebra at the time, with their application during the construction of the brace. The arrays surrounding pressures on a deformed spine minimize the resistance of the spine at the deformed area (hump of dynamic type) as well as axial compression forces (Delmas index), disarm the mechanism of turn - side bend at the thoracic part (which accompanies the deformation of Cobb's angle in idiopathic scoliosis), as well as the mechanical resistance, limiting the amplitude of movements of the thoracic spine, as well as of the side bend (Krassa, 2006).
Flexpine brace
Flexpine brace is a hybrid type of brace for use by non-surgical scoliosis patients. It is of 0.04 inches thickness and uses foldable urethane/plastic as its frame so that the wearer can still move his/her body. It is a customized product made of 3D printing material, with an elastic band to push the curved part of the spine. It is easy to bend their body when wearing. Patients can do spine realigning exercise while wearing Flexpine brace, so they can reduce their overall treatment time by exercising and conveying the brace treatment simultaneously.
Milwaukee brace
The Milwaukee brace was a very common brace towards the earlier part of the twentieth century in the United States. It is a largely symmetrical brace. The brace is made with a harness-like hip area and metal strips rising to the chin, where a collar is. Between the hips and chin, there are corrective thrusts given with large pads. There is little rotational correction. Today this brace is generally used for very high thoracic curves that are severe and out of range of the Boston. This brace is typically worn 20–23 hours a day.
Silicon Valley Brace
This brace is similar to that of the Rigo-Cheneau or other Cheneau type braces in that it incorporates an individualized correction designed based on the individual's scoliosis curve pattern as determined by x-ray or MRI imaging. The brace is designed in three dimensions utilizing CAD software similar to other modern braces and is manufactured out of thermoplastic allowing for further modifications based on the individual's growth over time. Based on current scientific literature, this asymmetric brace type is designed to both prevent progression as well as reduce the curve as in-brace correction correlates to treatment outcome.[4] This brace type is typically worn upwards of 18+ hours a day in conjunction with other conservative treatment options including physiotherapy scoliosis-specific exercises[5] such as Schroth.
SpineCor brace
The brace has a pelvic unit from which strong elastic bands wrap around the body, pulling against curves, rotations, and imbalances. It is most successful when the patient has relatively small and simple curvatures, is structurally young, and compliant—it is usually worn 20 hours a day. The patient is not to have it off for more than two hours at a time. While it is expected that patients can participate in activities as strenuous as competitive gymnastics while in brace, it also pulls down against shoulder misalignments which compresses the spine. SpineCor is marketed as a more comfortable, less restricted scoliosis brace option for adults. This brace was invented in Montréal, Canada and is used across the country as well as being widely used in other countries.[6]
Sport brace
SPoRT stands for "Symmetric, Patient-oriented, Rigid, Three-Dimensional active," which it intends to be. The brace is symmetrical, built with a plastic frame reinforced with aluminum rods. The brace corrects hip misalignments through padding. Large, sweeping, thick pads push the spine to a corrected position. To prevent overcorrection, however, the brace also has "stop" pads holding the spine from moving too far in the other direction. The brace runs from just above the chair to T3 in many instances—it is successful at correcting high thoracic curves. In front, it goes around the patient's breast and up, even to pushing against the collar bone. Though it sounds restricting, it has been tested for comfort while participating in athletics. The theory holds that the support that the brace gives will help the patient's body learn to work as though it had no curve muscularly. Then the muscles would be able to support the spine, preventing further collapse. This brace is used for all curve patterns and types, even ones considered past brace treatment by other schools. The brace is typically worn 22 hours a day, and often coupled with a physical therapy program.
Bracing for other purposes
Thoracolumbosacral orthosis
A thoracolumbosacral orthosis (TLSO), is a two-piece plastic brace supporting the spine from the thoracic vertebrae of the chest, to the base of the spine at the sacrum. The rigid lumbar or TLSO (Thoraco – Lumbo – Sacral – Orthosis) is used, when regardless of surgical correction, or in some cases in place of surgical correction, spinal stability has not been fully achieved. In some cases of spinal fractures these can be managed without surgery using such a TLSO brace but this is only in the case where the type of fracture has its own inherent stability. The brace provides additional immobilization, which should safely allow condition or fracture to heal with a minimal risk of further injury. Under these circumstances, this brace must be worn for approximately several months whenever the patient is out of bed. In other cases the doctor or orthotist may prescribe such a brace to deal post-surgery immobilization, or for the longer term treatment of conditions of a more progressive nature, such as correction of scoliosis in the growing adolescent. These are described briefly below:
After having undergoing complex spinal surgeries, this is especially the fusion procedures, a brace will probably be necessary. There are a number of factors determining the need for brace wear include: - the severity of any instability, the lack of good bone quality, the location of the surgery, or the nature of the deformity. In these situations, a rigid brace may be needed. Once again, the brace is specifically for immobilization and support. It should be worn whenever the patient is out of bed for more than 10 minutes. This brace will be worn for approximately several months after surgery but your doctor or surgeon will let the patient know if such a brace is necessary.
Rigid braces are also used for the correction of scoliosis in the growing children and adolescents. These braces are very specific in nature and are used until the adolescent has finished growing (usually to about 16 years of age). Use of a brace does not always control the scoliosis curvature. Indeed, the curvature in very aggressive scoliosis can continue to progress despite bracing. Typically in such circumstances, surgery to correct the scoliosis could eventually be necessary despite many years of bracing. However, the brace may replace the need for surgery and this is always preferred if possible.
The brace for scoliosis is a rigid plastic brace and must be worn a minimum of 18 out of 24 hours per day. Ongoing brace adjustments will needed and are necessary to maximize the scoliosis correction. If you are required to wear a brace to treat ongoing adolescent scoliosis, it will be necessary to visit the clinic or doctor or orthotist every few months. In a few circumstances, very restrictive braces that utilize thigh cuff extensions to control the pelvis are sometimes needed and this type of brace is worn to treat a very specific situation, such as a patient who has undergone pelvic fusion where the bone quality is at risk or questionable.
The brace comes in a variety of forms and can be used for treating severe or unstable compression fractures as well as other injuries and conditions.[7]
Jewett brace
A Jewett brace is a hyperextension brace that prevents the patient from bending forward too much. It is often used to facilitate healing of an anterior wedge compression fracture involving the T10 to L3 vertebrae.[7][8]
Corset brace
A corset brace is similar to a traditional corset. It typically has metal or plastic stays to limit forward movement. It puts pressure over the belly to take pressure off of the spine and promote healing.[9]
Posture Brace / Posture Corrector
A posture brace or a posture corrector is to help people improve their postures and maintain their bodies in a straight and upright position.
Posture corrector realign body to its original position by straightening from ankle to knee, pelvis, and shoulders to ear.
See also
- Back belt
- Orthotics
- Cervical collar
- vertebrae
- Orthotics
- Dental braces
- Orthopedic cast
- Kendrick Extrication Device
- long spine board
- Halo (medicine)
- spinal fusion
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References
- Negrini S, Donzelli S, Aulisa AG, Czaprowski D, Schreiber S, de Mauroy JC, Diers H, Grivas TB, Knott P, Kotwicki T, Lebel A, Marti C, Maruyama T, O'Brien J, Price N, Parent E, Rigo M, Romano M, Stikeleather L, Wynne J, Zaina F (2018-01-10). "2016 SOSORT guidelines: orthopaedic and rehabilitation treatment of idiopathic scoliosis during growth". Scoliosis and Spinal Disorders. 13: 3. doi:10.1186/s13013-017-0145-8. PMC 5795289. PMID 29435499.
- Weinstein SL, Dolan LA, Wright JG, Dobbs MB (October 2013). "Effects of bracing in adolescents with idiopathic scoliosis". The New England Journal of Medicine. 369 (16): 1512–21. doi:10.1056/NEJMoa1307337. PMC 3913566. PMID 24047455.
- Aulisa AG, Guzzanti V, Falciglia F, Galli M, Pizzetti P, Aulisa L (2017). "Curve progression after long-term brace treatment in adolescent idiopathic scoliosis: comparative results between over and under 30 Cobb degrees - SOSORT 2017 award winner". Scoliosis and Spinal Disorders. 12: 36. doi:10.1186/s13013-017-0142-y. PMC 5662099. PMID 29094108.
- Clin J, Aubin CÉ, Sangole A, Labelle H, Parent S (August 2010). "Correlation between immediate in-brace correction and biomechanical effectiveness of brace treatment in adolescent idiopathic scoliosis". Spine. 35 (18): 1706–13. doi:10.1097/BRS.0b013e3181cb46f6. PMID 21330954.
- Berdishevsky H, Lebel VA, Bettany-Saltikov J, Rigo M, Lebel A, Hennes A, Romano M, Białek M, M'hango A, Betts T, de Mauroy JC, Durmala J (2016). "Physiotherapy scoliosis-specific exercises - a comprehensive review of seven major schools". Scoliosis and Spinal Disorders. 11: 20. doi:10.1186/s13013-016-0076-9. PMC 4973373. PMID 27525315.
- Dunn S (January 23, 2008). "Amazing brace". Maclean's. Archived from the original on 2010-05-23.
- "Jewett vs. TLSO Replies". OANDP-L on oandp.com. 2010-09-27. Retrieved 2012-09-02.
- "What Is a Jewett Brace?". Retrieved 2012-09-01.
- "Types Of Back Braces For Compression Fractures". LIVESTRONG.COM. 2011-06-14. Retrieved 2012-09-01.
Further reading
- Atanasio S, Zaina F, Negrini S (2008). "The SPoRT (Symmetric, Patient-oriented, Rigid, Three-dimensional, active) concept for scoliosis bracing: principles and results". Studies in Health Technology and Informatics. 135: 356–69. PMID 18401104.
- Blount WP (March 1972). "Use of the Milwaukee brace". The Orthopedic Clinics of North America. 3 (1): 3–16. PMID 5012586.
- Emans JB, Kaelin A, Bancel P, Hall JE, Miller ME (October 1986). "The Boston bracing system for idiopathic scoliosis. Follow-up results in 295 patients". Spine. 11 (8): 792–801. doi:10.1097/00007632-198610000-00009. PMID 3810295.
- Howard A, Wright JG, Hedden D (November 1998). "A comparative study of TLSO, Charleston, and Milwaukee braces for idiopathic scoliosis". Spine. 23 (22): 2404–11. doi:10.1097/00007632-199811150-00009. PMID 9836354.
- Wong MS, Cheng JC, Lam TP, Ng BK, Sin SW, Lee-Shum SL, Chow DH, Tam SY (May 2008). "The effect of rigid versus flexible spinal orthosis on the clinical efficacy and acceptance of the patients with adolescent idiopathic scoliosis". Spine. 33 (12): 1360–5. doi:10.1097/BRS.0b013e31817329d9. PMID 18496349.
- Coillard C, Circo A, Rivard CH (May 2008). "A new concept for the non-invasive treatment of Adolescent Idiopathic Scoliosis: the Corrective Movement principle integrated in the SpineCor System". Disability and Rehabilitation: Assistive Technology. 3 (3): 112–9. doi:10.1080/17483100801903913. PMID 18465393.
- Katz DE, Durrani AA (November 2001). "Factors that influence outcome in bracing large curves in patients with adolescent idiopathic scoliosis". Spine. 26 (21): 2354–61. doi:10.1097/00007632-200111010-00012. PMID 11679821.
- Korovessis P, Zacharatos S, Koureas G, Megas P (April 2007). "Comparative multifactorial analysis of the effects of idiopathic adolescent scoliosis and Scheuermann kyphosis on the self-perceived health status of adolescents treated with brace". European Spine Journal. 16 (4): 537–46. doi:10.1007/s00586-006-0214-9. PMC 2229828. PMID 16953447.
- Sherman KA (2007). "Pilot study to validate a scoliosis-specific instrument that measures quality of life and treatment effect". Scoliosis. 2 (= Suppl 1): 11.
- Vasiliadis E, Grivas TB, Gkoltsiou K (May 2006). "Development and preliminary validation of Brace Questionnaire (BrQ): a new instrument for measuring quality of life of brace treated scoliotics". Scoliosis. 1: 7. doi:10.1186/1748-7161-1-7. PMC 1481574. PMID 16759366.
- Vasiliadis E, Grivas TB, Savvidou O, Triantafyllopoulos G (2006). "The influence of brace on quality of life of adolescents with idiopathic scoliosis". Studies in Health Technology and Informatics. 123: 352–6. PMID 17108451.