Atlas Orthogonal Chiropractic Technique

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Atlas Orthogonal Chiropractic Technique is a branch of upper cervical specific chiropractic, a branch of the healing arts which focuses on the spine's influence on overall health, utilising very minute, but supremely focused forces to correct spinal and neck imbalances.

One of the very first specialities in chiropractic was to focus on the upper neck, or the base of the skull. Correcting poor alignment here can normalise muscular tone and alleviate many conditions causing discomfort or even disease. This was termed "Upper Cervical Specific Chiropractic", or "upper cervical" for short.

Upper cervical specific

Dan Murphy DC DABCO, wrote :

Over the past 100 years, the practice of chiropractic has branched into dozens of specialty techniques. However, historically, for a third of this time, from the 1930s into the 1960s, the predominant practice of chiropractic involved primarily the upper cervical spine.

As for the reasons why Upper Cervical has taken such a back seat to other techniques just as worthy of discipline is up for dispute. Possibly today, the logic and dynamic probing instigated byB. J. Palmer tends to get lost in the ramblings of devotees who have elevated the man above the message. True, some of his messages may have been plainly wrong, opening the way for more allopathically accepted methodologies like mobilisation and therapeutic manipulative techniques, that do not focus on philosophical, quasi-religious themes such as innate intelligence or vitalism. These undoubtedly have a place, but are somewhat different from the theory and practice of adjusting the occipito-atlanto-axial joint area, which this article investigates.

Is it scientifically supported that C1 is the most influential area of the skeletal system, and most difficult to apply a specific force to?

Clinically, for neck pain syndromes, chiropractic atlas adjustment works to great reliability, but when it comes to other diseases and syndromes the research is almost non-existent. In the neuro-musculo-skeletal realm, pharmacology has limited efficacy, and that is largely why chiropractic and other physical therapies flourish, despite venomous opposition, as reported by authors like Eisenberg or Shekelle.

Introduction to Atlas Orthogonality

Atlas Orthogonal Chiropractic Technique (AO) is a specialty technique because it focuses on adjusting the atlas vertebra and studying its relationship to human anatomy and health. It is based upon the pioneering work of Drs. BJ Palmer and, subsequently, Dr John Grostic.

It is a whole-body technique because it focuses on the atlas as a biomechanical and neurological “keystone” of body function, much like BJ Palmer did when he wrote:

WHY should three superior cervical vertebrae be so important that facts warrant our making statement that nothing done at any other place in human body is of value in restoration of health, except as it is done here?

Chiropractors have moved away from Palmer’s notion that the upper cervical area “is cause of every dis-ease possible in the human race”, but unfortunately they have also a paucity of research investigation upper cervical chiropractic. So much so that chiropractic teaching institutions exist totally without any upper cervical specific technique in their curriculum, perhaps in order to disengage from this early fundamentalism of treating “all dis-ease”.

The AO program recognises the need to work with other healing arts and also with other chiropractors, and in conjunction with other technique or secondary systems if the chiropractor wishes. Referral is given without delay in the event that the patient worsens or does not achieve symptomatic improvement within a reasonable amount of visits. (Upper Cervical chiropractors generally disagree with extended plans and bulk sales of adjustments, other than where it benefits the patient to do so.)

History

In 1909 BJ Palmer introduced spinography at the Palmer School in Davenport, Iowa. To this day, upper cervical specific chiropractors deem that this is the best tool for accuracy in assessing vectors of adjustment. Reproducible, reliable and within acceptable error, based on clinical results and research (see Table one).

John F. Grostic consulted a chiropractor for a condition that did not respond to orthodox medical approaches, and with the success of such, graduated as a chiropractor in 1933. He modified Palmer’s enlightened approach (“hole in one”) to incorporate a more quantifiable listing of vectors.

Dr Roy Sweat, the developer of AO, was born June 25, 1927 in Albany Georgia. After leaving the military in 1946 he entered Palmer College of Chiropractic in Davenport Iowa in January of 1947 and completed the four year course of study and graduated in January of 1950.

In 1952 Dr. Sweat began a course of study specialising in the upper cervical occipital-atlanto-axial complex under Dr. John F. Grostic in Ann Arbor, Michigan. In 1960 Dr. Grostic chose Dr. Sweat to become an instructor at his seminars. Dr. Grostic died in 1964, at which time Dr. Sweat and four other doctors organized the Grostic Presentation Seminars and continued the specialised training seminars in Atlanta Georgia.

In 1981 Dr. Sweat created the program of Chiropractic Atlas Orthogonality, which continued in the specialized educational seminars. The AO program is taught as an elective course at Sherman Chiropractic College and at Palmer College, and as a post-graduate course at Life Chiropractic College. He is an associate professor of Life Chiropractic College in Marietta, Georgia and is involved with their research program.

Dr. Sweat received the Daniel David Palmer Scientific Award on June 9, 1995 from Palmer College. He has recognised the need for specialties within chiropractic practice and for doctors of chiropractic to refer within these specialties.

He has stated that the first generation of chiropractors discovered the principles of the profession, the second generation proved it was worth discovering via clinical successes, because “it works and that what counts”, and the third (we in practice today) must demonstrate why it works. Further, we must not leave it to the medical profession explain the “why” to us. Research is the key. It would also be helpful to know the when in the equation.

Instrument adjusting Eugene T. Patronis, Jr., Ph.D., professor at the School of Physics, Georgia Institute of Technology describes the operation of the Atlas Orthogonal Adjusting Instrument as follows: "A mechanical impulse is imparted to the metal stylus by means of a spring loaded plunger. The strength of this impulse is determined by the initial degree of compression given to the plunger spring. The impulse imparted to the stylus by the plunger excites a compressional wave in the stylus. The velocity of this wave in the stylus material is determined by the square root of the ratio of the Young's modulus to the density of the stylus material. At the patient-stylus interface, dependent on the impedance match, a portion of this wave energy is transmitted into the patient and a portion is reflected back to the plunger."

Dr Sweat adjusted the atlas for 25 years by hand and in 1970 designed a chiropractic adjusting instrument and has made a series of six different models.

He comments that because he has eliminated the aspect of manual adjusting skills, a new graduate can deliver an adjustive thrust with equal quantity and quality.

He has designed an atlas orthogonal x-ray frame, x-ray chair and attachments for the x-ray machine, and even a computerized x-ray analysis program.

Knowledge of the upper cervical spine begs specific questions of Occiput to Axis: 1. Why do we use so much rotation for a rotary break adjustment of Occ-C1 when standard ranges of motion are only around 5º? 2. What is the co-efficient of friction in the joint complex and how much force is require to “move” it? 3. How do you move, adjust or manipulate a joint complex with such a complexity of arcs, concavities and neuro-muscular stabilisers?

Anatomical knowledge is the key, taught from a chiropractic perspective, and that is what we do in the AO programs. BJ Palmer wrote of the value of knowing the normal osteology in understanding why this area is so important:

One difficulty we have found in instructing on this question, even amongst Chiropractors who are supposed to know spinal columns better than other distinctively separate types of students, is that they do not sufficiently know their NORMAL osteology.

Leg Length Inequality

Travell wrote “A discrepancy of 0.5cm, can perpetuate myofascial trigger points”. The AO doctor uses a supine leg length check as a pre and post-adjustment measure. Many authors have studied the phenomenon of unequal leg length, and proposed that it can perpetuate myofascial trigger points , create scoliosis syndromes and low back pain.

Agreement on whether there is a discrepancy in length has also been good in numerous significant studies on prone leg checking.

Leg length changes after adjustment can be explained as a change in mechanoreceptor firing altering input to the cerebello-thalamo-cortical pathway, inhibiting cotical-ponto-medullary inhibition of the muscles of posture and segmental motion via the alpha-motor neuron on the descending medial longitudinal fasciculus (vestibulospinal tract). Simply put: If subluxation is present, the tone of postural muscles will increase unilaterally. This may cause leg length inequality, and responses to changes in mechanoreceptor stimulation may also occur via local stress or pressure challenges.

We would of course be excited to know that a branch from the cortical pontine medullary tract is also sent to the hypothalamus which, via the descending reticular formation and intermediolateral (IML) columns, can affect vasoconstriction and immune function (IML is visceral efferent, synapsing in lamina VII).

Scanning Palpation: Palpable nerve facilitation

The AO protocol makes major use of palpatory skills in detecting full spine, particularly suboccipital, pain point tenderness, myofascial trigger points and hypertonicity. Pain point tenderness has exhibited acceptable inter-examiner reliability. The course of the first two spinal nerves runs dorsally to the intervertebral joints while all others leave the intervertebral foramina in front of the articular processes. (Note: this is not motion palpation.)

The AO practitioner contacts the soft tissue overlying the approximate points of exit of the left and right C1 and C2 spinal nerves, and assesses tissue compliance, inflammation and point tenderness. The four points are then rated from 0-3, with 3 being severe and eliciting a “jump sign” from the patient. This, in conjunction with the leg check, x ray listings, clinical data and history indicate the need for adjustment .

How can chiropractors explain clinical results from adjusting the atlas?

The Occipital-Atlanto-Axial joint has been described as the most complex in the axial skeleton . The mechanism of how any type of adjustment can specifically “move” the atlas, and why it affects such diverse clinical conditions is controversial. We can, however, postulate credible hypotheses, based on widely accepted facts and theories, explaining the clinical outcomes after adjustment of the upper cervical spine. Some theories follow:

Vestibular: The cervical spine is a rich reservoir of proprioceptive vestibular input. Dysfunction of spinal segments in this area are likely to affect vestibular function, which in turn, may affect visceral function. Research on rabbits suggests vestibular projections to the areas of the autonomic nervous system known as the nucleus tractus solitarius and the dorsal motor nucleus of the vagus nerve. Studies on rats show that upper cervical proprioceptors make direct connection to portions of the vestibular complex, and stimulation or inhibition may result in vertigo or nystagmus . Through the above, relationship may be postulated between postural controls, somatic mechanoreceptors, visual reflexes, and visceral autonomics.

Periaqueductal Grey: Cervical spine connections to the periaqueductal grey (PAG) have been observed in animal research. The PAG plays an important role in analgesia as well as in motor activities, such as vocalization, cardiovascular changes, and movements of the neck, back, and hind limbs. The strongest PAG-spinal connections have been observed to exist to the upper cervical cord . The upper cervical connections terminate in laminae V, VII, and VIII, containing pre-motor interneurons of the neck muscles.

Mechanoreceptor function: Mendel and McLain stated the purpose of the mechanoreceptors in the intervertebral disc and facet joint capsular ligaments is to tell the central nervous system about changes in spinal alignment and position. Thus it can be understood that this afferent receptor input plays a vital role in posture.

Posture: If cervical spine dysfunction can affect vestibular function, then postural influences may relay to the autonomic nervous system. For example, a paper observing the phenomenon of sweating suggests “...that the autonomic nervous system is controlled at least in part, by body posture.”

Dural connections: Hack et al, concluded after 11 dissections of human cadavers that there is a physical attachment between the rectus capitis posterior minor muscle and the dura mater of the spinal cord.

Brain Stem connections and Cervicogenic Headache: The trigeminal cervical nucleus can extend down to C4. Studies injecting noxious chemicals into the upper neck musculature showed that there was subsequent contracture of muscles of the TMJ. There may also be headache. Nilsson also stated that the prevalence of cervicogenic headache in random population sample “...appears to be a relatively common form of headache, similar to migraine in prevalence.” What is hypothesized is a confusion of the sensory information to the thalamus, causing cortical firing to the head area of the homunculus, by a disturbance of upper cervical afferentation, involving the trigeminal pathways. Bogduk wrote that cervicogenic headache can arise from abnormalities in normal joint end-play, and abnormalities of position found on radiographs. He clearly states:

The neuroanatomical basis for cervicogenic headache is convergence in the trigeminocervical nucleus between nociceptive afferents from the field of the trigeminal nerve and the receptive fields of the first three cervical nerves. Structures innervated by C1-3 have been shown to be capable of causing headache...

Evidently, there is renewed interest in upper cervical today. This author's experience and enquiries from around Australia and the world , patient groups illuminating their own experience through the power of the World Wide Web, medical books endorsing it at risk of being criticised by the establishment, and excellent compendia of research for chiropractors and clinicians paint the way for an interesting future.

The general public should approach chiropractic, and all specialities with the same caution and scientific probing as they would any drug or surgical procedure for efficacy, professional regulations, possible risk and comparative procedures available.

Summary: Why is the upper cervical area so important to health?

1. It is the most complex area of articulation in the body.
2. There is communication between this area and the vestibular system directly
3. There may be direct muscular connection between this area and the spinal cord (dura)
4. There is direct input to the Thalamus from levels above C3.
5. There is mechanoreceptor input to the thalamus from the entire body. However, the number of these receptors being far greater in the upper cervical area, coupled with an absence of synapses that potentially modify representation in the neuraxis, makes the upper cervical area unique and highly influential.
6. Input into the periaqueductal grey area from the cervical spine has a role in various activities including pain regulation.

The Upper Cervical programs, like most chiropractic techniques, are largely ignored by the majority of mainstream medical peer-reviewed literature, usually accompanied by chants of lacking research. Though true, they are also backed by a century of results and discerning consumer choice, which, we hope is influencing the current younger generations. Atlas Orthogonal, and other upper cervical programs, are also re-emerging in popularity, based upon the demand experience by this author largely through the internet experience (see appendix one).

References

1. Eriksen K. Upper Cervical Subluxation Complex. A review of the chiropractic and medical literature. LWW, 2004; pvii
2. Palmer BJ. Chiropractic Clinical Controlled Research. Vol 25. 1951. Chiropractic Fountain Head. Davenport IA USA. Page 724.
3. Sweat RW. Atlas Orthogonal Basic IV. RW Sweat Foundation, Atlanta USA. 2000. p227
4. Travell JG; Simons DG. Myofascial Pain and Dysfunction- The Trigger Point Manual. Williams and Wilkins. p.48
5. Lower Limb Length Inequality And Scoliosis, in Etiology of Adolescent Idiopathic Scoliosis. Spine: State of the Art Reviews-Vol. 14, No. 2, May 20006. Fuhr AW, Osterbauer PJ. Interexaminer Reliability of Relative Leg Length Evaluations in the Prone Extended Position. Chiropractic Technique 1989; 1(1):13-8.
7.Youngquist MW, Fuhr AW, Osterbauer PJ. Interexaminer Reliability of an Isolation Test for the Presence of an Upper Cervical Isolation Subluxation. J Manipulative Physiol Ther 1989; 12:93-97.
8. Sato, A. Somatovisceral reflexes. Conference proceedings of the Chiropractic Centennial Foundation, Washington DC, Jul. 6-8, 1995.
9. White & Panjabi. Clinical Biomechanics of the Spine, 2nd Ed. JB Lippincott. 1990. p92
10. Balaban, C. Vestibular nucleus projections to the parabrachial nucleus in rabbits: implications for vestibular influences on the autonomic nervous system. Exp Brain Res 108:367-381, 1996.
11.Neuhuber WL, Zenker W. Central distribution of cervical primary afferents in the rat, with emphasis on proprioceptive projections to vestibular, perihypoglossal, and upper thoracic spinal nuclei. J Compar Neur 1989; 280:231-53
12.Mouton, LJ. Holstege, G. The periaqueductal grey in the cat projects to lamina VIII and the medial part of lamina VII throughout the length of the spinal cord. Exp Brain Res 101(2):253-64, 1994.
13.Mendel, T, et al. Neural elements in human cervical intervertebral discs. Spine. 17(2); 132-4, 1992
14. McLain, R. Mechanoreceptor Endings in human cervical facet joints. Spine. 19(5); 495-510, 1994
15. Vaidya, JS. Dhume, RA. Influence of lateral posture on sweating: does posture alter the sympathetic outflow to the sweat glands? Indian J Physiol & Pharmacol. 38(4); 319-22, 1994.
16. Hack, GD et al. Anatomic relation between the rectus capitis posterior minor muscle and the dura mater. Spine 20:2484-2486;1995
17. Nilsson, N. The prevalence of cervicogenic headache in a random population sample of 20-59 year olds. Spine 20(17):1884-8, 1995.
18. Bogduk, N. The anatomical basis for cervicogenic headache. JMPT. 15(1):67-70, 1992.
19. See www.spine.net.au
20. Buchanan, Greg. www.upcspine.com/tmlinks.asp
21. Weigel, G; Casey, KF. Striking Back! The Trigeminal Neuralgia and Face Pain Handbook. 2004.Trigeminal Neuralgia Association, Florida, USA.
22.Biederman, H. Manual Therapy in Children. 2004. Elsevier. 23. Ibid ref. no. 1

External links

• http://www.atlasorthogonality.com
• http://www.atlasorthogonal.info
• http://www.atlasorthogonal.com.au
• http://www.upcspine.com
• http://www.atlasvertebra.com
• http://www.aucco.org/
• http://www.palmer.edu/
• http://www.sherman.edu/edu/index.html
• http://www.uppercervical.org/