Spinal fusion

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Spinal fusion
Intervention
A 24-year old male showing a normal kyphosis curve after a 13-level spinal fusion to correct Scheuermann's disease
ICD-9-CM	81.0
MeSH	D013123
MedlinePlus	002968

Spinal fusion, also known as spondylodesis or spondylosyndesis, is a surgical technique used to join two or more vertebrae. Supplementary bone tissue, either from the patient (autograft) or a donor (allograft), is used in conjunction with the body's natural bone growth (osteoblastic) processes to fuse the vertebrae.

Fusing of the spine is used primarily to eliminate the pain caused by abnormal motion of the vertebrae by immobilizing the faulty vertebrae themselves, which is usually caused by degenerative conditions. However, spinal fusion is also the preferred way to treat most spinal deformities, specifically scoliosis and kyphosis.

Reasons for spinal fusion

Spinal fusion is done most commonly in the lumbar region of the spine, but it is also used to treat cervical and thoracic problems. The indications for lumbar spinal fusion are controversial.^[1] People rarely have problems with the thoracic spine because there is little normal motion in the thoracic spine. Spinal fusion in the thoracic region is most often associated with spinal deformities, such as scoliosis and kyphosis.

Patients requiring spinal fusion have either neurological deficits or severe pain which has not responded to conservative treatment. Spinal fusion surgeries are also common in patients who suffer from moderate to severe back deformities that require reconstructive surgery.

Conditions where spinal fusion may be considered:

degenerative disc disease
spinal disc herniation
discogenic pain
spinal tumor
vertebral fracture
scoliosis
kyphosis (e. g., Scheuermann's disease)
spondylolisthesis
spondylosis
posterior rami syndrome
other degenerative spinal conditions
any condition that causes instability of the spine

Types of spinal fusion

There are two main types of lumbar spinal fusion, which may be used in conjunction with each other:

Posterolateral fusion places the bone graft between the transverse processes in the back of the spine. These vertebrae are then fixed in place with screws and/or wire through the pedicles of each vertebra attaching to a metal rod on each side of the vertebrae.

Interbody fusion places the bone graft between the vertebra in the area usually occupied by the intervertebral disc. In preparation for the spinal fusion, the disc is removed entirely, for example in ACDF. A device may be placed between the vertebra to maintain spine alignment and disc height. The intervertebral device may be made from either plastic or titanium. The fusion then occurs between the endplates of the vertebrae. Using both types of fusion is known as 360-degree fusion. Fusion rates are higher with interbody fusion. Three types of interbody fusion are:

Anterior lumbar interbody fusion (ALIF)- the disc is accessed from an anterior abdominal incision
Posterior lumbar interbody fusion (PLIF) – the disc is accessed from a posterior incision
Transforaminal lumbar interbody fusion (TLIF) – the disc is accessed from a posterior incision on one side of the spine
Transpsoas interbody fusion (DLIF or XLIF) – the disc is accessed from an incision through the psoas muscle on one side of the spine

In most cases, the fusion is augmented by a process called fixation, involving the placement of metallic screws (pedicle screws often made from titanium), rods, plates, or cages to stabilize the vertebrae and facilitate bone fusion. The fusion process typically takes 6 to 12 months after surgery. During this time external bracing (orthotics) may be required. External factors such as smoking, osteoporosis, certain medications, and heavy activity can prolong or even prevent the fusion process. If fusion does not occur, patients may require reoperation.

Some newer technologies are being introduced which avoid fusion and preserve spinal motion. Such procedures, such as artificial disc replacement, are being offered as alternatives to fusion in the cervical spine. Their advantage over fusion has not been well established. Minimally invasive techniques have also been introduced to reduce complications and recovery time for lumbar spinal fusion.

In addition to lumbar fusions, cervical spinal fusions may also be performed on the neck. The purpose of a cervical spinal fusion is also to join certain bones in the spine. Bone, metal plates, or screws can be used to make a bridge between adjacent vertebrae. In extreme cases, whole vertebrae can be removed before the fusion occurs. In most cases, however, only the intervertebral disk is removed, and the bone or metal graft is subsequently inserted, allowing for healing of the vertebrae.

Cervical spinal fusion can be performed for several reasons. Following injury, this surgery can help stabilize the neck and prevent damage to the spinal cord. It can also be used to treat misaligned vertebrae or as a follow-up for other spinal injuries. Additionally, cervical spinal fusion can be used to remove or reduce pressure on nerve roots caused by bone fragments or ruptured intervertebral disks.

In spinal fusion, the accuracy with which screws are inserted in the pedicles has a direct effect on the surgical outcome. Accurate placement generally involves considerable judgmental skills that have been developed through a lengthy training process. Because the impact of misaligning one or more pedicle screws can directly affect patient safety, a number of navigational and trajectory verification approaches have been described and evaluated in the literature to provide some degree of guidance to surgeons. For example, Manbachi et. al (2013) presented an overview of the need and the current status of the guidance methods available for improving the surgical outcomes in spinal fusion. They also describe educational aids that have the potential for reducing the training process.^[2] Accurate guidance systems, such as the Mazor Robotics "Renaissance", have been developed to assist with spinal fusion procedures.

Notable persons who underwent spinal fusion

Phil Jackson, NBA basketball player^[3]
Ryan Kalish, major league baseball player^[4]
Orland Kurtenbach, NHL hockey player^[5]
Peyton Manning, NFL football quarterback^[6]
Lolo Jones, Olympic hurdler^[7]

References

↑ "Low Back Disorders (revised 2007)". Occupational Medicine Practice Guidelines (2 ed.). American College of Occupational and Environmental Medicine. 2007. p. 210.
↑ Manbachi, A., et al. (2013). Guided pedicle screw insertion: Techniques and training. The Spine Journal 13(4) 1–15.
↑ "Phil Jackson". Nba.com. Retrieved November 9, 2013.
↑ Mcgair, Brendan. "Red Sox OF Kalish hopes latest surgery does the trick". The Pawtucket Times. Retrieved November 9, 2013.
↑ "The NHL's Most Interesting Name: 1960s Part II". Arctic Ice Hockey. Retrieved November 9, 2013.
↑ "Spinal fusion surgery: The science behind Manning's life changing operation". News.medill.northwestern.edu. February 2, 2012. Retrieved November 9, 2013.
↑ "Cheryl Raye-Stout reviews some key moments from the 2012 Summer Olympic Games in London". Wbez.org. August 13, 2012. Retrieved November 9, 2013.

Additional images

Stabilization rods used after spinal fusion surgery.

External links

Wheeless, C. R., et al., Eds. Fusion of the Spine. Wheeless' Textbook of Orthopaedics. Division of Orthopedic Surgery. Duke University Medical Center.
Spinal Fusion. American Academy of Orthopaedic Surgeons. June 2010. Accessed 1 June 2013.
Spinasanta, S. What is Spinal Instrumentation and Spinal Fusion? SpineUniverse. September 2012. Accessed 1 June 2013.
Spinal fusion. Encyclopedia of Surgery. Accesses 1 June 2013.

Orthopedic surgery, operations/surgeries and other procedures on bones and joints (ICD-9-CM V3 76–81, ICD-10-PCS 0P–S)

Bones

Facial	Jaw reduction Dentofacial osteotomy Genioplasty/Mentoplasty Chin augmentation Orthognathic surgery

Spine	Coccygectomy Laminotomy Laminectomy Laminoplasty Corpectomy Facetectomy Foraminotomy Vertebral fixation Percutaneous vertebroplasty

Upper extremity	Acromioplasty

Lower extremity	Femoral head ostectomy Astragalectomy Distraction osteogenesis Ilizarov apparatus

General	Ostectomy Bone grafting Osteotomy Epiphysiodesis Reduction Internal fixation External fixation

Medical imaging	Dual energy X-ray absorptiometry/Digital X-ray radiogrammetry pQCT Skeletal survey Bone scintigraphy

Cartilage

Joints

Spine	Arthrodesis Spinal fusion Intervertebral discs Discectomy Annuloplasty Arthroplasty Back examination Straight leg raise Waddell's signs Schober's test

Upper extremity	Shoulder surgery Shoulder replacement Bankart repair Weaver–Dunn procedure Ulnar collateral ligament reconstruction Hand surgery Brunelli procedure exam: Shoulder examination Jobe's test Adson's sign Elbow examination Elbow extension test Wrist examination Tinel sign/Phalen maneuver Finkelstein's test

Lower extremity	Hip resurfacing Hip replacement Rotationplasty Anterior cruciate ligament reconstruction Knee replacement/Unicompartmental knee arthroplasty Ankle replacement Broström procedure Triple arthrodesis exam: Hip examination Knee examination Drawer test Ballottement Ankle examination Simmonds' test CPRs: Pittsburgh knee rules Ottawa knee rules Ottawa ankle rules

General	Arthrotomy Arthroplasty Synovectomy Arthroscopy Replacement joint imaging: Arthrogram Arthrocentesis

M: BON/CAR

anat (c/f/k/f, u, t/p, l)/phys/devp/cell

noco/cong/tumr, sysi/epon, injr

proc, drug (M5)

M: JNT

anat (h/c, u, t, l)/phys

noco (arth/defr/back/soft)/cong, sysi/epon, injr

proc, drug (M01C, M4)

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