Differentiating the Structural and Functional Instability of the Craniocervical Junction
Abstract
:1. Introduction
- (1)
- The anatomical aspect: A significant part of ligamentous stabilization for the C0/C1 level originates at the C2 segment (alar and accessory alar ligaments) with the coordinated movement of the C0/C1/C2/C3 segments in lateral flexion and rotation.
- (2)
- The neurophysiological aspect: The range of the spinal nucleus of the trigeminal nerve and the innervation of the suboccipital muscles reaching the C3 segment result in numerous clinical implications (certain types of headaches and dizziness and some temporomandibular joint dysfunctions).
- (3)
2. Diagnostics and Etiology of CCJ
- Ligamentous-Capsular Hypermobility: This condition is characterized by an increased range of motion due to excessive laxity in ligamentous capsular structures without associated damage. It typically presents with non-specific neck pain, occasional discomfort, or mild instability but without significant neurological symptoms or imaging findings indicative of structural damage [15].
- Functional Postural Disorders (Proprioceptive Dysfunction of the CCJ): Functional instability arises from a disruption in the proprioceptive system’s ability to accurately perceive and control cervical spine movement. Despite the absence of structural damage on imaging, patients may experience symptoms such as dizziness, balance issues, and muscle hyperactivity. This form of instability requires careful differentiation from structural causes as it can mimic neurological and musculoskeletal dysfunctions. Treatment typically involves conservative measures such as proprioceptive retraining and physical therapy [16].
- True Structural Instability: This condition involves an actual disruption of ligamentous capsular structures, such as tears, elongations, or ligament insufficiency. It is usually confirmed through imaging techniques and often requires surgical intervention to prevent further neurological damage or instability. Patients typically present with clear signs of instability, such as neurological deficits, significant pain, and radiographic evidence of vertebral misalignment or ligament damage [17].
3. The Biomechanics of the CCJ and Manual Examination
- -
- Flexion/Extension: This refers to the anterior and posterior glide of the occipital condyles on C1, totaling about 30° (10° in flexion and 20° in extension, constituting about 17% of the cervical spine’s flexion range); movement occurs around an axis passing through the external auditory meatuses [18]. The manual testing of the glide range at this level is performed with the patient seated. The therapist first stabilizes the atlas arch by placing one hand over the posterior aspect of the C1 transverse processes. With the other hand, the therapist stabilizes the patient’s head by placing their palm over the occiput and using their fingers to control the mandible. The head is then passively moved in the sagittal plane, maintaining alignment along an axis passing through the external auditory meatuses, with careful application of flexion and extension. The therapist assesses the range of motion (normal range: 10° flexion, 20° extension), tissue compliance, and end-feel resistance using repetitive movements to ensure consistency in the findings (Figure 1).
- -
- Rotation: This refers to movement by approximately 5–7° to each side; the movement is coupled with lateral flexion due to the configuration of the C1 articular surface and the forces exerted by the alar ligaments. The manual testing of the glide range at this level is performed with the patient in a supine position. The therapist elevates the atlas arch through its transverse process and assesses the range, quality of motion, and end-feel resistance of the relative posterior glide of the occipital condyle on the same side (Figure 2).
- -
- Lateral Flexion: This refers to movement by approximately 3–5° to each side; the movement is coupled with a component of contralateral rotation at the C1/C2 level due to the action of the alar ligaments, making it difficult to isolate (coupled movement extends to C2/C3). For example, lateral flexion to the right causes C1 to rotate in the opposite direction and manifests as increasing tension on the C1 transverse process (it appears to protrude and “harden” during the lateral glide of C0, with the alar ligament on the opposite side to lateral flexion providing resistance) [19] (Figure 3).
- -
- Flexion and lateral flexion: 0°.
- -
- Rotation: 30–40° to each side (comprising approximately 50% of the cervical spine’s rotational range). Isolation of rotational movement at this level typically occurs after full flexion or extension of the lower cervical spine. Coupled contralateral lateral flexion is also observed—for example, during right rotation, the C1 transverse process on the same side elevates [20].
4. Radiological Criteria for Instability
- -
- A change in the distance from the Basion to the posterior wall of C2 > 6 mm (Basion Atlas Interval, BAI)—an increased distance indicates anterior subluxation of C0/C1.
- -
- A change in the distance from the Basion to the apex of the dens > 5 mm (Basion Dens Interval, BDI)—an increased distance indicates distraction.
- -
- A change in the distance between the atlas and the dens > 2 mm (Atlas Dens Index, ADI)—a change of up to 4 mm in children is normal; an increased distance indicates transverse ligament insufficiency.
- -
- A change in the distance from the posterior aspect of the dens to the posterior aspect of the C1 arch < 13 mm—a decreased distance indicates spinal canal narrowing.
- -
- A change in the distance between the lateral masses of C1 > 7 mm—AP open-mouth projection on X-ray; an increased distance indicates rupture of the C1 arch.
- -
- Axial rotation C1/C2 > 45 degrees to each side—transverse projection on CT—an increased range of rotation indicates instability.
- -
- Axial rotation C0/C1 > 8 degrees to each side—transverse projection on CT—an increased range of rotation indicates instability.
- -
- Any crossing of the McRae line by the den’s apex, crossing of the McGregor line by the den’s apex > 4 mm, or crossing of the Chamberlain line > 6 mm indicates basilar invagination.
- -
- The ratio of the distance from the Basion (B) to the posterior arch of the atlas (C) to the distance between the anterior aspect of the C2 dens (A) and the Opisthion (O), known as the Powers ratio, where BC/AO > 1 (normal < 1) indicates C1/C2 instability.
- -
- Atlanto-occipital index (AOI) > 1 mm—an increased distance suggests distraction.
- -
- Clivo-axial angle (CXA), which is the angle between the bony part of the skull base and the posterior part of the C2 dens; a normal range is very wide in the range of 139°–172°, depending on the head position (neutral position is in the range of 150–165°), but an angle below 135° may cause compression of the anterior brainstem and medulla oblongata (Figure 6).
- -
- Space available for the cord (SAC) at C1 level > 14 mm.
5. Symptomatology of CCJ Instability
6. The Role of the Cervical Proprioception System
7. Differentiation of Dizziness and Postural Instability
8. Management for CCJ Conditions
9. Quality of Life in Patients with CCJ Instability
10. Summary
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Type of Dizziness | Character of Dizziness | Duration | Symptom Provocation | Symptom Reduction |
---|---|---|---|---|
Vestibular (Infectious Origin) | Vertigo, carousel-like movement, elevator ride, lateropulsion, vegetative symptoms, nausea and vomiting, clogged ear, hearing loss | Seconds to chronic | Independent of head position | Antibiotics, antiviral drugs, steroids, rehabilitation |
Cerebellar, Posterior Columns, Polyneuropathy | Swaying, ground instability, feeling drunk, feeling of empty ground without visual control, no visual or auditory disturbances | Chronic | Upright position and exclusion of visual control | Visual control inclusion, lying position |
CCJ Instability, CPS Dysfunction | General instability, swaying, ground instability, feeling drunk, feeling of empty ground, additional symptoms like dizziness, difficulty associating (dizziness), headaches, TMJ dysfunctions, tinnitus, dysautonomia, cranial nerve symptoms, visual disturbances | Seconds to chronic | Head position, flexion or extension (protrusion) in upper cervical segment, axial traction, whiplash, trunk rotation repetition (fixed head positioning while chair is mobile) | Orthopedic collar immobilization, “mechanical silence”, anti-inflammatory drugs or injections, muscle relaxants, anticonvulsants, antidepressants, positional training (biofeedback), manual therapy |
Vascular—VBI | Swaying, ground instability, feeling drunk, feeling of empty ground, additional symptoms like visual disturbances, nystagmus, facial paresthesias, nausea, drop attacks | A few minutes with a period of slow resolution | Head position, combination of flexion/rotation, extension/rotation, axial traction, rapid body position change | Neutral neck position, drugs to improve cerebral circulation |
Vascular—Vascular Diseases (Migraine), Orthostatic, Heart Rhythm Disorders, Stroke | Feeling of sliding and fainting, paresthesias, numbness of lips, visual disturbances of field loss type (ischemia), headache or eye pain, aura | Seconds—orthostatic; hours—migraine; chronic—stroke | Migraine triggers, dehydration, hormonal disorders | Antimigraine drugs, antiarrhythmics, hormones, hydration, rehabilitation |
Phobia | Situational sudden vertigo or “leg cut-off”, vegetative symptoms | Seconds | Height, speed, movement amplitude changes | Assistance |
BPPV | Head position-dependent, no visual or auditory disturbances | Seconds with a period of slow resolution | Head position | Hallpike maneuver |
Condition | Diagnosis | Management | Follow-Up |
---|---|---|---|
Ligamentous-Capsular Hypermobility | -Clinical history: non-specific neck pain, the feeling of a “heavy” head, periodic blocking, the habit of self-manipulation, hypermobility | -Conservative treatment: Platelet Rich Plasma (PRP), Autologous Conditioned Serum (ACS), collagen, prolotherapy injections | -Regular monitoring for improvement in joint stability and symptom management |
-Physical examination: mobility and tissue compliance tests, soft end-point | -Proprioceptive training, biofeedback | -Periodic evaluation to adjust therapy | |
-Radiological imaging: no significant findings but may use hyperextension/flexion radiographs | |||
-Strengthening exercises targeting cervical muscles and postural therapy in case of periodic orthosis | |||
Functional Postural Disorders (Proprioceptive Dysfunction) | -Clinical history: dizziness, imbalance issues, muscle hyperactivity, postural sway | -Conservative treatment: Platelet Rich Plasma (PRP), Autologous Conditioned Serum (ACS), collagen, prolotherapy injections | -Reassessment of proprioceptive function and postural control |
-Physical examination: proprioceptive tests, joint position error testing | -Proprioceptive retraining, biofeedback | -Monitor patient’s progress through periodic evaluation | |
-Imaging: normal or minimal findings | -Vestibular rehabilitation (if applicable) | ||
-Manual therapy: soft tissue release techniques for muscle tension and postural control therapy, joint mobilization Pharmacology: antidepressant, myorelaxants, anticonvulsant, anxiolytics | |||
True Structural Instability | -Clinical history: severe symptoms, neurological deficits | -Surgical referral: neurosurgery or orthopedic department | -Post-surgical rehabilitation: strengthening, mobility, and proprioception exercises |
-Physical examination: provocative tests (e.g., Sharp Purser, Anterior Shear) | -Surgical stabilization, fusion, or decompression based on imaging and clinical findings | -Regular post-operative follow-up to ensure stabilization and prevent further complications | |
-Imaging (X-ray, MRI, CT): signs of vertebral misalignment, ligamentous injury | -Pre-operative conservative management: cervical collar or immobilization to prevent worsening |
Criteria | Structural Instability | Functional Instability |
---|---|---|
Definition | Physical defects such as ligamentous laxity, bone deformities, or structural abnormalities | Proprioceptive dysfunction with no clear structural abnormalities on imaging |
Primary Symptoms | Neurological deficits, abnormal movement patterns, chronic neck pain, fixed deformities | Dizziness, imbalance, postural sway, a feeling of disharmony of movements and disintegration of the body, muscle hypertension, tiredness |
Diagnostic Criteria | Identified via radiological imaging (X-rays, CT, MRI), positive mobility tests, and provocative tests indicating ligament damage | Diagnosed through proprioceptive and neuromuscular control assessments, joint position error testing, and dynamic balance tests. |
Key Diagnostic Tests | Sharp Purser Test, Anterior Shear Test | Joint position error testing, dynamic balance assessments |
Provocative Tests | Positive for ligament damage or vertebral misalignment | Proprioceptive dysfunction detected through dynamic assessments |
Management Approach | Surgical intervention: fusion, decompression, stabilization | Conservative therapy: injections, physical therapy, proprioceptive retraining, pharmacological support |
Expected Outcome | Restored structural stability, prevention of further damage | Improved symptom management, enhanced proprioceptive function |
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Godek, P.; Ruciński, W. Differentiating the Structural and Functional Instability of the Craniocervical Junction. Healthcare 2024, 12, 2003. https://doi.org/10.3390/healthcare12192003
Godek P, Ruciński W. Differentiating the Structural and Functional Instability of the Craniocervical Junction. Healthcare. 2024; 12(19):2003. https://doi.org/10.3390/healthcare12192003
Chicago/Turabian StyleGodek, Piotr, and Wojciech Ruciński. 2024. "Differentiating the Structural and Functional Instability of the Craniocervical Junction" Healthcare 12, no. 19: 2003. https://doi.org/10.3390/healthcare12192003
APA StyleGodek, P., & Ruciński, W. (2024). Differentiating the Structural and Functional Instability of the Craniocervical Junction. Healthcare, 12(19), 2003. https://doi.org/10.3390/healthcare12192003