Craniocervical instability

Craniocervical instability (CCI) is a pathological condition of increased mobility at the craniocervical junction, the area where the skull meets the spine. In CCI the ligamentous connections of the craniocervical junction can be stretched, weakened or ruptured. This can lead to stretching and/or compression of the brainstem, upper spinal cord, or cerebellum and result in myelopathy, neck pain and a range of other symptoms.

CCI usually develops as a result of physical trauma such as a car accident, an inflammatory disease such as rheumatoid arthritis or a congenital disorder such as Down's syndrome. More recently, physicians have reported an increased prevalence of CCI in patients with hereditary disorders of connective tissue such as Ehlers Danlos Syndromes (EDS). There have also been anecdotal reports of patients with myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) who were later diagnosed with CCI,  although no scientific publication on this subject exists. It frequently co-occurs with atlantoaxial instability (AAI).

Symptoms
Symptoms of craniocervical instability include occipital headache, neck pain and neurological abnormalities such as numbness, motor weakness, dizziness, and gait instability. Patients sometimes describe the feeling that their head is too heavy for their neck to support (“bobble-head”). No particular symptom is mandatory for a diagnosis of CCI and each symptom listed might have a cause other than CCI.

Other symptoms reported in patients with CCI include:
 * Muscle weakness, numbness, paralysis, parasthesias
 * Poor proprioception, impaired coordination, gait changes
 * Dizzinesss, vertigo,     syncope,    nausea
 * Headache behind the eyes, neck stiffness, torticollis, posterior scalp irritation, facial pain
 * Apnea, dyspnea (shortness of breath), and dysphagia (difficulty swallowing)
 * Visual disturbances downward nystagmus (irregular eye movements), tinnitus
 * Fatigue, sleep disturbance, cognitive impairment, and memory loss.

Risk factors and comorbidities
Established risk factors for CCI include physical trauma, inflammatory disease, neoplasms and congenital disorders.

More recently, physicians have reported an increased prevalence of CCI in patients with hereditary connective tissue disorders. According to Brodbelt & Flint, however, an "increased range of joint movement, caused by ligamentous laxity, is not the same as spinal instability resulting from trauma or major inflammatory arthropathies such as (historically) rheumatoid arthritis." Others have argued that "pathological instability at the cranio-cervical junction has not been clearly established in the literature for the hypermobility population."

It is not unusual for CCI to co-occur with other structural neurological abnormalities such as atlantoaxial instability (AAI) and chiari malformation (CM).

Diagnosis
The diagnosis of CCI is based on symptom presentation, a supportive history, demonstrable neurological findings and abnormal imaging.

Imaging
CCI is typically diagnosed via a cervical MRI, whether supine or upright. If supine, a 3 Tesla MRI is preferred over a 1.5 Tesla. Most neurosurgeons prefer upright MRI with flexion and extension. According to Henderson FC, “ventral brainstem compression may exist in flexion of the cervical spine, but appear normal on routine imaging.”

Measurements
More than twenty radiological measurements have been proposed or used in the diagnosis of CCI. However, three measurements are most commonly used: the Grabb-Oakes line, which measures ventral brainstem compression; the Clivo-Axial Angle (CXA), which measures brainstem deformity by the odontoid process; and the Basion Dens Interval, which measures vertical instability (cranial settling). According to a 2013 consensus statement on the assessment of CCI, a CXA of 135 degrees or less should be considered as "potentially pathological." as it is reported to be uncommon in the healthy population. Others have argued that these radiological measurements are "not accepted internationally as indicating instability." Some of the measurement ranges in the above table are also to be found in the 2nd International CSF Dynamics Symposium Consensus Statement (2013).

Traction
Manual traction, halo and invasive cervical traction may be used to aid in the diagnosis of CCI. Symptomatic improvement with traction can help determine whether a patient with abnormal measurements will benefit from craniocervical fusion surgery.

Conservative treatment
Traditional “conservative” treatments for CCI include rest, pain management, upper cervical chiropractic treatment, and bracing with a cervical collar. Although, in most cases these offer little relief.

Other experimental treatments for CCI include prolotherapy and stem cell therapy.

Surgery
If non-invasive treatments for CCI fail to work, occipito-cervical fusion (OCF) can be considered. OCF is a surgery that aims at a biomechanical stabilization of the craniocervical junction. Patients with objective radiological findings, a clinical picture supportive of the diagnosis, a positive response to traction, and who are significantly impaired may be candidates for this surgery. A common method involves internal fixation of the upper spine to the skull by mechanical rods and screws. (However, rod-wire, rigid rod-screws, occipital hooks and cervical claws are all methods currently in use. ) During surgery, titanium hardware is used to fixate the occiput, axis and atlas (i.e., C0 to C2) while rib graft or cadaver bone graft is used to help the bones fuse together. Wire methods are less biomechanically stable than rod methods and have high rates of dural laceration. Screw and rod fixation methods have lower complication rates and higher rates of successful fusion. Fusion rates across all hardware methods range from 89 to 100%. When cervical instability is present below C2, additional vertebrae may also be fused.

Outcomes, risks & complications
The outcome of OCF is generally favorable with most patients experiencing symptom relief post-surgery. In a study following following 20 EDS patients five years free O-2 fusion, most reported they were satisfied with the surgery and experienced significant improvements in symptoms such as vertigo, headaches, imbalance, dysarthria, dizziness, and frequent daytime urination. There was, however, only a small increase in objective outcomes such as work resumption, with 60% of patients remaining unable to work or go to school. Participants attributed this to other EDS comorbidities such as POTS, Mast Cell Activation Syndrome, and additional spinal problems.

The complications of OCF can be serious and occur in an estimated 7% to 33% of patients. Common complications include screw failure, wound infection, dural tear and cerebrospinal fluid leakage In some cases revision surgery is needed to treat infection or to remove hardware. Severe complications can include meningitis and accidental injury of the vertebral artery by misplaced screws.

A meta-study of 2274 procedures across 22 studies found the following complication rates:

Meta-studies place the rate of death from fusion surgery at 0-0.6%.

Side effects
OCF causes a substantial reduction in the neck’s range of motion, estimated at approximately 40% of total cervical flexion–extension.

Cost
OCF is estimated to cost tens of thousands of dollars, although some insurance schemes fully cover the cost of surgery depending on the country located and neurosurgeons involved.

Experimental treatments

 * Stem cell therapy: Some clinics offer stem cell therapy in order to regenerate the area, ligaments, connective and other tissues that may be damaged in the area.


 * PRP (Platelet Rich Plasma) therapy: Some clinics offer PRP therapy in order to help the body regenerate the area.

Dysautonomia and CCI in EDS
As CCI can lead to a compression of the brainstem, a number of experts believe it contributes to autonomic symptoms such as orthostatic tachycardia, dizziness and pre-/syncope that are frequently seen in patients with Ehlers Danlos Syndromes (EDS). In a 2007 influential paper Milhorat et al. followed-up on patients with Chiari malformation who did not improve with treatment and surgery. The authors discovered that many of these patients suffered from EDS and had other structural abnormalities at the upper spine such as CCI and cranial settling. Milhorat et al. speculated that the resulting compression of the brainstem might be the cause of the autonomic and other symptoms these patients were suffering from. Neurosurgeons and other EDS specialists have expounded on the connection between CCI and forms of dysautonomia such as postural orthostatic tachycardia syndrome (POTS) in a number of conference presentations.

Mechanical basis theory
Five ME/CFS patients diagnosed with CCI (some also had EDS) reported to have experienced remarkable improvements and even remission of their ME/CFS symptoms following OCF-surgery. They speculate that mechanical compression of the brainstem due to CCI has the potential to cause characteristic ME/CFS symptoms such as post-exertional malaise, although this theory is currently not supported by scientific evidence. The current literature does not suggest a connection between ME/CFS and CCI. Others have raised concerns about CCI surgery in patients with ME/CFS given the lack of research on OCF in this patient population.

Synonyms

 * Syndrome of Occipitoatlantialaxial Hypermobility
 * Hypermobility of the Craniocervical Junction
 * Craniocervical Junction Syndrome

Learn more

 * Could Craniocervical Instability Be Causing ME/CFS, Fibromyalgia & POTS? Pt I – The Spinal Series - from Health Rising
 * Jennifer Brea’s Amazing ME/CFS Recovering Story: the Spinal Series – Pt. II - From Health Rising
 * ME/CFS and Fibromyalgia Craniocervical Instability Surgery Effectiveness Poll - From Health Rising