Back Clinic Clinical CaseReports. These reports represent the most basic type of study design, in which researchers describe the experience of a single person (case report) or a group of people (case series). Case reports and case series describe individuals who develop a particular new disease or condition. Case reports & case series can provide compelling reading because they present a detailed account of the clinical experience of individual study subjects. Dr. Alex Jimenez discusses these reports, as he conducts his own case reports.
In medicine, clinical case reports offer scientific detailed documentation of the symptoms, signs, diagnosis, treatment, and follow-up of an individual patient. Case reports can contain a demographic profile of the patient, however, they usually describe an unusual occurrence. Case reports are the traditional method in medicine and scientific publication. Case reports describe and analyze the diagnosis and the management of one or two patients.
This is the first line of evidence in health care. A case report is used to disseminate information on unusual clinical syndromes, disease associations, unusual side effects from certain therapies, or responses to certain forms of treatment. Case reports have been used for years as a means to teach health science students and can be a valuable learning experience for authors and readers. They are well-read and easily accessible. For answers to any questions you may have please call Dr. Jimenez at 915-850-0900
Sandra Rubio discusses the symptoms, causes and treatments of neck pain. Headaches, migraines, dizziness, confusion and weakness in the upper extremities are some of the most common symptoms associated with neck pain. Trauma from an injury, such as that from an automobile accident or a sports injury, or an aggravated condition due to improper posture can commonly cause neck pain and other symptoms. Dr. Alex Jimenez utilizes spinal adjustments and manual manipulations, among other chiropractic treatment methods like deep-tissue massage, to restore the alignment of the cervical spine and improve neck pain. Chiropractic care with Dr. Alex Jimenez is the non surgical choice for improving overall health and wellness.
Cervical Pain Treatment
Neck pain is a common health issue, with approximately two-thirds of the population being affected by neck pain at any time throughout their lives. Neck pain originating in the cervical spine, or upper spine, can be caused by numerous other spinal health issues. Neck pain can result due to the pinching of the nerves emanating from the vertebrae, or because of muscular tightness in both the upper spine and the neck. Joint disruption in the neck can generate a variety of other common symptoms, including headache, or head pain, and migraines, as does joint disturbance in the back. Neck pain affects about 5 percent of the global population as of 2010, according to statistics.
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Massage Therapy: Damaris Formeman is a massage therapist at Dr. Alex Jimenez’s chiropractic care clinic. As an employee, Damaris has witnessed the recovery process and the tremendous improvement of many patients receiving chiropractic care with Dr. Alex Jimenez. Damaris Formeman understands how chiropractic treatment methods, like massage therapy, can help patients with a variety of health issues, including sciatica, low back pain, neck pain and shoulder pain, among others. Damaris describes how each patient is carefully cared for by Dr. Alex Jimenez and she adds that building a strong bond with the patient during treatment is an important part of the patient’s healing journey.�
Massage Therapy Chiropractic Care
Massage therapy is medically defined as the manipulation of the soft tissues of the body for the purpose of restoring the health of those tissues. Massage therapy consists of manual techniques that include applying fixed or movable pressure and holding, and/or causing movement of or to the body. Massage is commonly believed to affect the circulation of blood and the flow of blood and lymph, reduce muscular tension or flaccidity, affect the nervous system through stimulation or sedation, and enhance tissue healing. These effects can provide a variety of health benefits for individuals affected by musculoskeletal injuries and conditions, including those affecting the nervous system, among others.
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Dr. Alex Jimenez DC, C.C.S.T
Chronic Pain Treatment: Sandra Rubio has worked with Dr. Alex Jimenez for about 6 years, providing health care services to patients at Dr. Jimenez’s clinic. As a result, Sandra has learned and witnessed how many health benefits chiropractic care can provide for patients who begin treatment with Dr. Alex Jimenez. Although chiropractic care may sometimes require more than a single treatment session as well as regular maintenance to completely improve the patient’s symptoms, Dr. Alex Jimenez offers positive, trustworthy, safe and effective non-invasive alternative treatment options without the use of drugs and/or medications and he also makes sure to educate patients thoroughly regarding their specific health issue. Sandra Rubio discusses how essential it is for people with chronic pain to first seek chiropractic care with Dr. Alex Jimenez as the non-surgical choice for their injuries and/or conditions in order for them to achieve overall health and wellness.
Chronic Pain Treatment
Chronic pain is medically defined as pain which lasts for an extended amount of time. The distinction between acute and chronic pain is sometimes determined by an arbitrary interval of time since onset; the two most commonly used markers being 3 months and 6 months since onset, although many healthcare professionals have established the transition from acute to chronic pain at 12 months. Other healthcare specialists and researchers apply the definition of acute pain symptoms to pain that lasts less than 30 days, while the definition of chronic pain symptoms to pain that lasts more than six months. Subacute pain is medically defined as pain that lasts from one to six months. Chronic pain may originate anywhere in the body, such as in the case of chronic back pain, or it may originate in the brain or spinal cord, such as in the case of fibromyalgia. While chronic pain is considered difficult to treat, many healthcare professionals, including chiropractors, can effectively improve chronic pain.
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Dr. Alex Jimenez DC, C.C.S.T
David Garcia is a proud father and maintenance facility worker at the Region 19 Education Services Center in El Paso, TX. However, Mr. Garcia’s daily life is often affected by his chronic lower back pain. After experiencing worsening symptoms for approximately two years, David Garcia was recommended to seek chiropractic care with Dr. Alex Jimenez by his sister, a previous patient of Dr. Jimenez. Mr. Garcia has since experienced tremendous relief from his lower back pain and he is grateful to Dr. Alex Jimenez and his staff for providing him with education regarding his health issues as well as properly caring for his injuries and/or conditions. David Garcia recommends Dr. Alex Jimenez as the non surgical choice for lower back pain.
Chiropractic Care For Lower Back Pain
Low back pain is not a specific injury or condition but rather a symptoms which may be caused by a wide variety of underlying health issues, all of varying levels of severity. The majority of low back pain does not have a clear cause but is believed to be the result of non-serious musculoskeletal problems, including sprains or strains. Obesity, smoking, weight gain during pregnancy, stress, poor physical condition, poor posture and poor sleeping positions have also been attributed to develop low back pain.A full list of possible causes includes many less common conditions. Physical causes may include osteoarthritis, degeneration of the discs between the vertebrae or a spinal disc herniation, broken vertebra(e) (such as from osteoporosis) or, rarely, an infection or tumor of the spine.
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Dr. Alex Jimenez DC, C.C.S.T
Sports Injuries: Sandra Rubio has been working with Dr. Alex Jimenez for about 6 years. By caring for patients on a regular basis, Sandra has learned how essential and effective chiropractic care can be. Sandra describes how Dr. Alex Jimenez provides patients with a better way of healing themselves naturally, without the use of drugs/medications and surgery. The trust between Dr. Jimenez and the patient establishes a positive treatment outcome for many athletes with sports injuries as well as patients with other types of injuries and/or conditions through chiropractic care. Sandra Rubio expresses that Dr. Alex Jimenez is a safe non surgical choice for sports injuries.
Sports Injuries
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Sprains and strains are some of the most common type of sports injuries frequently reported by the average athlete. Sprains are injuries that affect the ligaments, tough bands which connect bones to the joints. Abrupt stretching of the ligaments beyond their natural range can deform or tear them. Strains are injuries that affect the muscle fibers or tendons, which function by anchoring muscles to bones. While most sports injuries are mild or moderate in nature, seeking immediate medical attention can help these heal faster in order for the athlete to be able to return-to-play quicker. A variety of treatment options, including chiropractic care can help treat sports injuries.
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Dr. Alex Jimenez DC, C.C.S.T
Migraine headache pain can be characterized as a throbbing pain or a pulsing sensation of varying intensity, which is generally accompanied by nausea as well as extreme sensitivity to light and sound. According to the American Migraine Association, migraines affect about 36 million Americans, or approximately 12 percent of the population in the United States. Because the symptoms can often become very debilitating, many migraine sufferers will have tried everything to attempt to relieve their headache pain, including avoiding triggers and using drugs and/or medications to reduce the symptoms. However, research studies have found that one alternative treatment option can greatly benefit migraineurs: chiropractic care.
Chiropractor Treating Migraine Pain
Chiropractic care is a safe and effective alternative treatment option which focuses on the diagnosis, treatment and prevention of a variety of injuries and/or conditions associated with the musculoskeletal and nervous system. A doctor of chiropractic, or chiropractor, will commonly utilize a series of chiropractic methods and techniques, including spinal adjustments and manual manipulations, to carefully correct any spinal misalignment, or subluxation, located along the length of the spine. Although the true source of migraines is still misunderstood today, healthcare professionals believe that a misalignment of the cervical spine, or neck, may trigger migraine symptoms. By correcting the alignment of the spine, a chiropractor can release the pressure being placed against the spinal column which may be irritating and/or compressing the complex structures surrounding the spine, manifesting the well-known symptoms of migraines. Furthermore, chiropractic care can decrease muscle tension and increase circulation, eliminating stress in the body which is also known to be a factor behind migraines, promoting further relief.
The Efficacy of Chiropractic Spinal Manipulative Therapy (SMT) in the Treatment of Migraine
Abstract
Objective: To test the efficacy of Chiropractic spinal manipulative therapy (SMT) in the treatment of migraine, using an uncontrolled clinical trial.
Design: A clinical trial of six months duration. The trial consisted of 3 stages: two months of pre-treatment, two months of treatment, and two months post treatment. Comparison was made to initial baseline episodes of migraine preceding commencement of SMT.
Setting: Chiropractic Research Centre of Macquarie University
Participants: Thirty two volunteers, between the ages of 23 to 60 were recruited through media advertising. The diagnosis of migraine based on a detailed questionnaire, regarding self reported symptoms or signs, with minimum of one migraine with aura per month.
Interventions: Two months of SMT provided by an experienced chiropractor at a university clinic.
Main Outcome Measures: Participants completed diaries during the entire trial noting the frequency, intensity, duration, disability, associated symptoms and use of medication for each migraine episode. In addition, clinic records were compared to their diary entries of migraine episodes.
Results: A total of fifty nine participants responded to the advertising, with twenty five being excluded or deciding not to continue in the trial. Two participants (5.9%) withdrew during the trial, one due to alteration in work situation and one following soreness after SMT. The Chiropractic SMT group showed statistically significant improvement (p < 0.05) in migraine frequency and duration, when compared to initial baseline levels. Only one participant (3.1%) reported that the migraine episodes were worse after the two months of SMT, and this was not sustained at the two month post treatment follow up period.
Conclusion: The results of this study suggest that Chiropractic SMT is an effective treatment for migraine with aura. However, due to the cyclical nature of migraine with aura, and the finding that episodes usually reduce following any intervention, further research is required. A prospective randomised controlled trial utilising detuned EPT (interferential), a sham manipulation group and an SMT group is nearing conclusion. It is anticipated this trial will provide further information of the efficacy of Chiropractic SMT in the treatment of migraine with aura.
According to the American Chiropractic Association, a 2011 report published in the Journal of Manipulative and Physiological Therapeutics, or JMPT, found that chiropractic care, including spinal adjustments and manual manipulations, can improve migraine and cervicogenic headache symptoms. Healthcare professionals have associated primary headaches with stress and muscle tension. Chiropractic care can help decrease the frequency of migraines and manage its symptoms by carefully correcting any spinal misalignment, or subluxation, found along the spine. By restoring the proper alignment of the spine, chiropractic care can improve overall spinal function by alleviating pressure on the nervous system, increasing circulation and reducing muscle tension and stress which causes migraine pain.
Introduction
Some studies appear to have demonstrated significant reduction in migraines following chiropractic intervention (1-8). However, this reduction may in part have been due to inaccurate diagnosis or overlapping symptoms (4,9,10). Many different conditions of the cervical spine, including mechanical and joint pathology, have been reported to cause headache (10-16). Sjaastad (17) used the term �cervicogenic headache� to describe a type of the chronic paroxysmal unilateral headache, which is accompanied by autonomic symptoms and provacated by movements of the head and neck. Sjaastad proposed that entrapment of the occipital nerve or a C2-C3 rhizopathy may produce this headache (18).
There are a number of aetiologies of migraines proposed in the literature. These include: vascular (19-21); autonomic (22); biochemical/cellular/immunological (23- 27); psychophysiological (28,29); neurogenic (9,15,25,30) and somatic (1-9,31,32). This has made a common treatment regime difficult. One early medical model was vascular cause of migraine, where a migrainous attack is initiated by a decreased blood flow to the cerebral vasculature or a cerebrovascular spasm, but characterized by extracranial vasodilation during the headache phase (19,20). However, later aetiological models have demonstrated more complex vascular changes with associated neurological changes (9).
Many practitioners involved in the treatment of migraine would, however, accept that a number of aetiological factors are involved and that there is substantial overlap in both aetiology or diagnosis (9,15,26,33,34). In addition, no single model appears to explain all the possible symptoms associated with migraine.
One possible aetiological factor is cervical spondylosis with associated neck pain and stiffness (34). Anthony states �when this is recognised, appropriate treatment can give impressive results…the aim is to relieve pressure on nerve roots in the upper neck thereby reducing activation of the spinal tract of the trigeminal nerve, which is part of the pain centre in the head and neck� (34). Surgical decompression of the lower cervical nerve�roots as carried out by Ghavamian (36) showed relief of migraine symptoms. He proposed that irritation and compression of the deep sympathetic fibres incited such symptomatology.
Vernon (7), proposed a vertebrogenic model which involves components from the different categories previously stated. One part involves lesions in the low cervical/upper thoracic spine and the upper cervical spine. The low cervical spine/upper thoracic spine (C7-T4) model proposed that dysfunction (i.e. somatic dysfunction) at these vertebral levels causes joint fixation and pain. This pain alters the neural messages received, and therefore sent, by the Central Nervous System (CNS). The Autonomic Nervous System which controls, amongst other functions, blood supply, is thus also affected. It is proposed that when certain threshold levels of transient cerebral ischaemia (due to vasoconstriction caused by the above mechanism) are reached, a migraine cascade of symptomatology may be precipitated.
A second part involves somatic dysfunction in the upper cervical spine (Occiput-C2), which produces local pain and fixation leading to increased neural input to the CNS. This results in a reduction in descending pain-inhibiting impulses from the CNS and consequently increases activity within the spinal trigeminal tract (which transmits the majority of sensory afferents and pain signals from the upper cervical region to the brain). Having exceeded a threshold level, this excessive afferent input to the CNS will trigger focal, and spreading vasoconstriction within the intracerebral vasculature. This will in turn promote extra-carotid vasodilation and cranial pain which is mediated by the ipsilateral trigeminal nerve (7).
Another model contends that irritation of the vertebral nerve by cervical lesions can produce a sympathetic syndrome, giving symptoms of headache, vertigo, visual disturbances and tinnitus. However, this model has not been well substantiated and appears more likely a cause of vascular headache as opposed to migraine (11). The source of pain in migraines is found in the intra- and extracranial blood vessels. The blood vessel walls are pain sensitive to distension, traction or displacement. The idiopathic dilation of cranial blood vessels, together with an increase in a pain threshold lowering substance, result in headache of migraine type (26).
Migraine has a well established symptomatology that has been outlined in various studies (4,12,15). The debilitating and frequent nature of symptoms that include head pain, nausea, vomiting, phonophobia, and photophobia, costs our society both socially and economically (4,12,15,20). As such, effective treatment has long been sought, therefore justifying study in this area. However, there is substantial overlap of symptoms between migraine and cervicogenic�headache, and some authors believe elements of the migraine headache continuum involve cervical headache (9,10).
The Headache Classification Committee of the International Headaches Society, has discarded the former terms classical migraine and common migraine in favour of migraine with aura and migraine without aura. In migraine with aura (MA), this condition is defined as recurrent, periodic, unilateral headache which is preceded or accompanied by transient visual, sensory, motor, or other focal neurological symptoms which localise to the cerebral cortex or brainstem. Migraine without aura, (MWA) is defined as a vascular headache without striking prodromal or associated symptoms of cerebral dysfunction (37).
The incidence of migraine in Australia is estimated at 12%, with the cost to industry an estimated $250 million (38). In the USA approximately 8% of headaches diagnosed by medical practitioners are called migraine headaches (39). Migraine, in its various forms, affects an estimated 5-20% of people throughout the world (40).
A review of the literature appears to indicate that migraine is an associated feature of cervical dysfunction. This paper will evaluate chiropractic spinal manipulative treatment directed towards improving vertebral function, and its role in the management of the migraines.
Methodology
Chiropractic spinal manipulative therapy (SMT) is defined as a passive manual manoeuvre during which the three joint complex is carried beyond the normal physiological range of movement without exceeding the boundaries of anatomical integrity (41). SMT requires a dynamic force in a specific direction, usually with a short amplitude, to correct a problem of reduced vertebral motion or positional fault.
The study design was based on a previous study which involved 82 subjects who received either chiropractic SMT, physiotherapy manipulation, or a control treatment of medical mobilization (1). Parker et al, concluded that manipulation was not found to be more effective than mobilisation, and chiropractic treatment not more effective than the other two groups (3). However, much criticism was received over the study, especially the statistical analysis (42).
People with migraines were advertised for participation in the study via the radio and newspapers within a local region of Sydney. All applicants completed a questionnaire, developed from Vernon (12), which contains over 25 sections, including details of the initial�history, frequency, severity, location and reaction to the pain, associated symptoms, precipitating or aggravating factors, relieving factors, past treatment for migraines, medical history including medications and other diagnostic tests.
The participants to take part in the trial were selected according to responses in the questionnaire of specific symptoms. The criteria for migraine diagnosis was compliance with at least 5 out of the following indicators: reaction to pain requiring cessation of activities or the need to seek a quiet dark area; pain located around the temples; pain described as throbbing; associated symptoms of nausea, vomiting, aura, photophobia or phonophobia; migraine precipitated by weather changes; migraine aggravated by head or neck movements; previous diagnosis of migraine by a specialist; and a family history of migraine.
Participants also had to experience migraine at least once a month, but not daily, and the migraines could not have been initiated by trauma. Participants were excluded from the study if there were contra-indications to SMT, such as meningitis or cerebral aneurysm. In addition, participants with temporal arteritis, benign intracranial hypertension or space occupying lesions, were also excluded due to safety aspects.
Participants were informed that they were involved in a trial of manipulative therapy for migraine, and that they may be randomly assigned to a control group which would receive a placebo (non effective) treatment, or to an intervention group which would receive Chiropractic SMT. However, because of the small numbers of participants that were involved in the trial, a control group was not used. Participants were also informed that a thorough physical examination would be performed prior to commencement of treatment to assess any physical problems precluding them receiving SMT. Patients were blinded, by believing that they may or may not receive an effective treatment. In addition, practitioners were not aware of ongoing treatment results, therefore they were also �blinded� to the stage of progress of the patients condition or response to treatment.
The trial was conducted over six months, and consisted of 3 stages: two months pretreatment, two months treatment, and two months post treatment. Participants completed diaries during the entire trial noting the frequency, intensity, duration, disability, associated symptoms and use of medication for each migraine episode. In addition, clinic records were compared to their diary entries of migraine episodes. Concurrently, the subjects were contacted by telephone by the author every month and asked to describe the migraine episodes for comparison to their diaries.
Patients were instructed at the beginning of the study on the use of the diary and were given an instruction sheet to use throughout the course of the trial. The diary consisted of a table for entries of each of the outcome measures. This included noting the date of each episode, a number representing a visual analogue score, letters denoting associated symptoms, the length (in hours) of each migraine, the time (in hours) before the person could return to normal duties, type and use of medications and the overall relief from the medication. The diaries were modified from standard diaries used by the Brain Foundation of Australia.
A detailed history of the patient’s subjective pain features was taken during the initial consultation. This included the type of pain, duration, onset, severity, radiation, aggravating and relieving factors. The history also included medical features, a systems review for potential pathologies, previous treatments and its effects.
Factors for assessing subluxation included: orthopaedic and neurological testing, segmental springing, mobility measures such as visual estimation of range of motion, assessment of previous radiographs, specific chiropractic vertebral testing procedures, as well as response of the patient to SMT.
In addition, several vascular investigations were performed where indicated, which included: vertebral artery test, manipulative provocation test, blood pressure assessment, and abdominal aortic aneurysm screening.
During the treatment period, the subjects continued to record migraine episodes in their diary, and receive telephone calls from the authors. Treatment consisted of short amplitude, high velocity spinal manipulative thrusts, or areas of fixation determined by the physical examination. Patients were allowed a maximum of sixteen treatments, and the frequency of treatment was dependent on the clinicians opinion of the severity of the vertebral dysfunction. The majority of patients received a minimum of twelve treatments.
Comparison was made to initial baseline episodes of migraine preceding commencement of SMT. Statistical analysis involved comparing the effects of the different treatment regimes on the incidence, intensity, and duration of migraines throughout the trial. Statistical tests employed were a students t test to test for significant difference between each group and a one way analysis of variance (ANOVA) to test for changes for all groups. Statistical calculations were performed via a computer software program Minitab for Macintosh.
Results
A total of fifty nine participants responded to the�advertising, with twenty five being excluded or deciding not to continue in the trial. These included: six cases of infrequent recurrence of the migraines (less than one per month); two cases of contraindications to SMT; one case of cluster headache; one case of motor vehicle accident during pre treatment; one case of fear of SMT; fourteen cases where the university clinic was inconvenient or time constraints were too difficult for participants. Two participants (5.9%) withdrew during the trial, one due to alteration in work situation and one following soreness after SMT.
Thirty two participants, between the ages of 23 to 60, joined the study with there being 14 males and 18 females. Table 1 gives the comparative descriptive statistics for the group.
The Chiropractic SMT group showed statistically significant improvement (p < 0.05) in migraine severity (Figure 1), duration (Figure 2) and disability (Figure 3), when compared to initial baseline levels. Only one participant (3.1%) reported that their migraine episodes were worse after the two months of SMT, but this was not sustained at the two month post treatment follow up period. Table 2 demonstrates variate scores in each of the six diary categories for the three phases of the trial.
The greatest area for improvement was with disability scores (p < 0.01), where participants were asked to rate the time that elapsed before they could return to normal activities (Table 3). In addition, the duration of the migraine and the use of medication, reduced significantly following the SMT intervention (p < 0.05). Table 3 shows mean variate scores for the three phases of the trial�and statistical significance by analysis of variance (ANOVA).
There was no apparent difference in the number of associated symptoms and the time taken for treatment to give relief of each migraine episode (Table 3). In addition, self reported possible trigger factors demonstrated no significant findings, predominantly due to the small sample size. Common trigger factors that were cited included stress, lack of sleep, work changes, or family situations. Most participants could not state a particular trigger factor.
Discussion
The majority of people who participated in this trial had chronic migraines that were severe and debilitating. However, the results have demonstrated a significant (p< 0.05) reduction in their�migraine episodes and their associated disability. The mean number of migraine per month reduced from 7.6 to 4.9 episodes.
This trial was conducted using a similar design to a previous study which demonstrated significant improvement in migraines following chiropractic SMT (1,3). The initial trial had limitations due to an inadequate control group, and this could also be a limitation with this study(2). However, the use of self reported, non treatment period as a control, allows flexibility regarding use of medication and any alteration during the trial.
Figure 1: Comparison of visual analogue scores for pre-treatment, treatment and post-treatment group means.
Figure 2: Comparison of duration time of migraine (hours) for pre-treatment, treatment and post-treatment group means.
Figure 3: Comparison of disability time of migraine (hours) for pre-treatment, treatment and post-treatment group means.
A similar design to this study has also been used in a study of headache and SMT (14). The Boline study was a randomised controlled trial using two parallel groups, with a two week baseline, a six week treatment period and a four week post treatment period. The results of this study show that SMT was an effective method of treatment for tension type headaches, and that the benefit was sustained for the four weeks after cessation of the treatment.
The present study was conducted over a six month period which gives the results substantial significance because early criticisms of studies were that the length of the trial was too short to allow for the cyclical nature of migraines. However, the study is limited in the sample size and the fact that the trial was a pragmatic study which did not consider what aspects of chiropractic SMT had contributed to the improvement in the migraine episodes.
In addition, the study is limited due to the lack of a control group. However, the fact that the trial was conducted over a six month period, with two months pre-treatment, it could be argued that participants acted as their own form of control.
A further limitation of this study, as with other studies of migraine or headaches is that there is substantial overlap in diagnosis and classification of migraines. The questionnaire used in this study proved to have good reliability, however, there is strong suggestion that many headache sufferers may have more than one type of headache (12). An advantage with the design of this study is that regardless of the exact �diagnosis� of the migraine, self reported, non-treatment controls still allow assessment of the therapy in question.
The measurement used for relief scores proved to be poor, which was probably due in part to the small scale for response that participants were given. Future studies should address this issue. In addition, associated symptoms did not give a clear result because the study only measured the total number of associated symptoms, and the sample size was too small for a significant percentage breakdown. Future studies should also address this issue.
Conclusion
The results of this study suggest that Chiropractic SMT may be an effective treatment for migraine. However, due to the cyclical nature of migraine, and the finding that episodes usually reduce following any intervention, further research is required. A prospective randomised controlled trial utilising detuned EPT (interferential), a sham manipulation group and an SMT group is nearing�conclusion. It is anticipated this trial will provide further information of the efficacy of Chiropractic SMT in the treatment of migraine.
In conclusion,�chiropractic care is a safe and effective alternative treatment option which can be used to improve migraine symptoms as well as decrease their frequency. A chiropractor will utilize spinal adjustments and manual manipulations to correct spinal misalignments, or subluxations, releasing pressure being placed against the complex structures surrounding the spine, decreasing muscle tension and improving circulation to eliminate stress, ultimately benefitting migraine sufferers. Finally, the purpose of the article above was to demonstrate the efficacy of chiropractic spinal manipulative therapy, or SMT, in the treatment of migraine. Information referenced from the National Center for Biotechnology Information (NCBI). The scope of our information is limited to chiropractic as well as to spinal injuries and conditions. To discuss the subject matter, please feel free to ask Dr. Jimenez or contact us at 915-850-0900 .
Curated by Dr. Alex Jimenez
Additional Topics: Back Pain
According to statistics, approximately 80% of people will experience symptoms of back pain at least once throughout their lifetimes. Back pain is a common complaint which can result due to a variety of injuries and/or conditions. Often times, the natural degeneration of the spine with age can cause back pain. Herniated discs occur when the soft, gel-like center of an intervertebral disc pushes through a tear in its surrounding, outer ring of cartilage, compressing and irritating the nerve roots. Disc herniations most commonly occur along the lower back, or lumbar spine, but they may also occur along the cervical spine, or neck. The impingement of the nerves found in the low back due to injury and/or an aggravated condition can lead to symptoms of sciatica.
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Several types of headaches can affect the average individual and each may result due to a variety of injuries and/or conditions, however, migraine headaches can often have a much more complex reason behind them. Many healthcare professionals and numerous evidence-based research studies have concluded that a subluxation in the neck, or a misalignment of the vertebrae in the cervical spine, is the most common reason for migraine headaches. Migraine is characterized by severe head pain typically�affecting one side of the head, accompanied by nausea and disturbed vision. Migraine headaches can be debilitating. The information below describes a case study regarding the effect of atlas vertebrae realignment on patients with migraine.
Effect of Atlas Vertebrae Realignment in Subjects with Migraine: An Observational Pilot Study
Abstract
Introduction. In a migraine case study, headache symptoms significantly decreased with an accompanying increase in intracranial compliance index following atlas vertebrae realignment. This observational pilot study followed eleven neurologist diagnosed migraine subjects to determine if the case findings were repeatable at baseline, week four, and week eight, following a National Upper Cervical Chiropractic Association intervention. Secondary outcomes consisted of migraine-specific quality of life measures. Methods. After examination by a neurologist, volunteers signed consent forms and completed baseline migraine-specific outcomes. Presence of atlas misalignment allowed study inclusion, permitting baseline MRI data collection. Chiropractic care continued for eight weeks. Postintervention reimaging occurred at week four and week eight concomitant with migraine-specific outcomes measurement. Results. Five of eleven subjects exhibited an increase in the primary outcome, intracranial compliance; however, mean overall change showed no statistical significance. End of study mean changes in migraine-specific outcome assessments, the secondary outcome, revealed clinically significant improvement in symptoms with a decrease in headache days. Discussion. The lack of robust increase in compliance may be understood by the logarithmic and dynamic nature of intracranial hemodynamic and hydrodynamic flow, allowing individual components comprising compliance to change while overall it did not. Study results suggest that the atlas realignment intervention may be associated with a reduction in migraine frequency and marked improvement in quality of life yielding significant reduction in headache-related disability as observed in this cohort. Future study with controls is necessary, however, to confirm these findings. Clinicaltrials.gov registration number is NCT01980927.
Introduction
It has been proposed that a misaligned atlas vertebra creates spinal cord distortion disrupting neural traffic of brain stem nuclei in the medulla oblongata encumbering normal physiology [1�4].
The objective of the National Upper Cervical Chiropractic Association (NUCCA) developed atlas correction procedure is restoration of misaligned spinal structures to the vertical axis or gravity line. Described as the �restoration principle,� realignment aims to reestablish a patient’s normal biomechanical relationship of the upper cervical spine to the vertical axis (gravity line). Restoration is characterized as being architecturally balanced, being capable of unrestricted range of motion, and allowing a significant decrease in gravitational stress [3]. The correction theoretically removes the cord distortion, created by an atlas misalignment or atlas subluxation complex (ASC), as specifically defined by NUCCA. Neurologic function is restored, specifically thought to be in the brain stem autonomic nuclei, which affect the cranial vascular system that includes Cerebrospinal Fluid (CSF) [3, 4].
The intracranial compliance index (ICCI) appears to be a more sensitive assessment of changes made in craniospinal biomechanical properties in symptomatic patients than the local hydrodynamic parameters of CSF flow velocities and cord displacement measurements [5]. Based on that information, previously observed relationships of increased intracranial compliance to marked reduction in migraine symptoms following atlas realignment provided incentive for using the ICCI as the study objective primary outcome.
ICCI affects the ability of the Central Nervous System (CNS) to accommodate physiologic volume fluctuations that occur, thereby avoiding ischemia of underlying neurologic structures [5, 6]. A state of high intracranial compliance enables any volume increase to occur in the intrathecal CNS space without causing an intracranial pressure increase that occurs primarily with arterial inflow during systole [5, 6]. Outflow occurs in the supine position via the internal jugular veins or when upright, via paraspinal or secondary venous drainage. This extensive venous plexus is valveless and anastomotic, allowing blood to flow in a retrograde direction, into the CNS through postural changes [7, 8]. Venous drainage plays an important role in regulating the intracranial fluid system [9]. Compliance appears to be functional and dependent on the free egress of blood via these extracranial venous drainage pathways [10].
Head and neck injury could create abnormal function of the spinal venous plexus that may impair spinal venous drainage, possibly because of autonomic dysfunction secondary to spinal cord ischemia [11]. This decreases accommodation of volume fluctuations within the cranium creating a state of decreased intracranial compliance.
Damadian and Chu describe return of a normal CSF outflow measured at mid-C-2, exhibiting a 28.6% reduction of the measured CSF pressure gradient in the patient where the atlas had been optimally realigned [12]. The patient reported freedom from symptoms (vertigo and vomiting when recumbent) consistent with the atlas remaining in alignment.
A hypertension study using the NUCCA intervention suggests a possible mechanism underlying the blood pressure decrease could be resultant from changes in cerebral circulation in relation to atlas vertebrae position [13]. Kumada et al. investigated a trigeminal-vascular mechanism in brain stem blood pressure control [14, 15]. Goadsby et al. have presented compelling evidence that migraine originates via a trigeminal-vascular system mediated through the brain stem and upper cervical spine [16�19]. Empirical observation reveals significant reduction of migraine patients’ headache disability after application of the atlas correction. Using migraine-diagnosed subjects seemed ideal for investigating proposed cerebral circulation changes following atlas realignment as originally theorized in the hypertension study conclusions and seemingly supported by a possible brain stem trigeminal-vascular connection. This would further advance a developing working pathophysiologic hypothesis of atlas misalignment.
Results from an initial case study demonstrated substantial increase in ICCI with decrease in migraine headache symptoms following the NUCCA atlas correction. A 62-year-old male with neurologist diagnosed chronic migraine volunteered for a before-after intervention case study. Using Phase Contrast-MRI (PC-MRI), changes in cerebral hemodynamic and hydrodynamic flow parameters were measured at baseline, 72 hours, and then four weeks after the atlas intervention. The same atlas correction procedure used in the hypertension study was followed [13]. 72 hours after study revealed a noteworthy change in the intracranial compliance index (ICCI), from 9.4 to 11.5, to 17.5 by week four, after intervention. Observed changes in venous outflow pulsatility and predominant secondary venous drainage in the supine position warranted additional investigation further inspiring a study of migraine subjects in this case series.
The possible effects of the atlas misalignment or ASC on venous drainage are unknown. Careful examination of intracranial compliance in relation to effects of an atlas misalignment intervention may provide insight into how the correction might influence migraine headache.
Using PC-MRI, this current study’s primary objective, and primary outcome, measured ICCI change from baseline to four and eight weeks following a NUCCA intervention in a cohort of neurologist selected migraine subjects. As observed in the case study, the hypothesis supposed that a subject’s ICCI would increase following the NUCCA intervention with a corresponding decrease in migraine symptoms. If present, any observed changes in venous pulsatility and drainage route were to be documented for further comparison. To monitor migraine symptoms response, the secondary outcomes included patient reported outcomes to measure any related change in Health Related Quality of Life (HRQoL), similarly used in migraine research. Throughout the study, subjects maintained headache diaries documenting the decrease (or increase) in the number of headache days, intensity, and medication used.
Conducting this observational case series, pilot study, allowed for additional investigation into aforementioned physiologic effects in further development of a working hypothesis into the pathophysiology of an atlas misalignment. Data required for estimation of statistically significant subject sample sizes and resolving procedural challenges will provide needed information for developing a refined protocol to conduct a blinded, placebo controlled migraine trial using the NUCCA correction intervention.
Methods
This research maintained compliance with the Helsinki Declaration for research on human subjects. The University of Calgary and Alberta Health Services Conjoint Health Research Ethics Board approved the study protocol and subject informed consent form, Ethics ID: E-24116. ClinicalTrials.gov assigned the number NCT01980927 after registration of this study (clinicaltrials.gov/ct2/show/NCT01980927).
Subject recruitment and screening occurred at the Calgary Headache Assessment and Management Program (CHAMP), a neurology-based specialist referral clinic (see Figure 1, Table 1). CHAMP evaluates patients resistant to standard pharmacotherapy and medical treatment for migraine headache that no longer provides migraine symptom relief. Family and primary care physicians referred potential study subjects to CHAMP making advertising unnecessary.
Figure 1: Subject disposition and study flow (n = 11). GSA: Gravity Stress Analyzer. HIT-6: Headache Impact Test-6. HRQoL: Health Related Quality of Life. MIDAS: Migraine Disability Assessment Scale. MSQL: Migraine-Specific Quality of Life Measure. NUCCA: National Upper Cervical Chiropractic Association. PC-MRI: Phase Contrast Magnetic Resonance Imaging. VAS: Visual Analog Scale.
Table 1: Subject inclusion/exclusion criteria. Potential subjects, na�ve to upper cervical chiropractic care, demonstrated between ten and twenty-six headache days per month self-reported over the previous four months. Requisite was at least eight headache days per month, where intensity reached at least four, on a zero to ten Visual Analog Scale (VAS) pain scale.
Study inclusion required volunteers, between the ages of 21 and 65 years, that satisfy specific diagnostic criteria for migraine headache. A neurologist with several decades of migraine experience screened applicants utilizing the International Classification of Headache Disorders (ICHD-2) for study inclusion [20]. Potential subjects, na�ve to upper cervical chiropractic care, must have demonstrated through self-report between ten and twenty-six headache days per month over the previous four months. At least eight headache days per month had to reach an intensity of at least four on a zero to ten VAS pain scale, unless treated successfully with a migraine-specific medication. At least four separate headache episodes per month separated by at least a 24-hour pain-free interval were required.
Significant head or neck trauma occurring within one year prior to study entry excluded candidates. Further exclusion criteria included acute medication overuse, a history of claustrophobia, cardiovascular or cerebrovascular disease, or any CNS disorder other than migraine. Table 1 describes the complete inclusion and exclusion criteria considered. Using an experienced board certified neurologist to screen potential subjects while adhering to the ICHD-2 and guided by the inclusion/exclusion criteria, the exclusion of subjects with other sources of headache such as muscular tension and medication overuse rebound headache would increase the likelihood of successful subject recruitment.
Those meeting initial criteria signed informed consent and then completed a baseline Migraine Disability Assessment Scale (MIDAS). The MIDAS requires twelve weeks to demonstrate clinically significant change [21]. This allowed adequate time to pass to discern any possible changes. Over the next 28 days, candidates recorded a headache diary providing baseline data while confirming the number of headache days and intensity required for inclusion. After the four weeks, the diary check diagnostic substantiation permitted administration of remaining baseline HRQoL measures:
Migraine-Specific Quality of Life Measure (MSQL) [22],
Headache Impact Test-6 (HIT-6) [23],
Subject current global assessment of headache pain (VAS).
Referral to the NUCCA practitioner, to determine presence of atlas misalignment, confirmed need for intervention finalizing a subject’s study inclusion?exclusion. Absence of atlas misalignment indicators excluded candidates. After scheduling appointments for NUCCA intervention and care, qualified subjects obtained baseline PC-MRI measures. Figure 1 summarizes subject disposition throughout the study.
The initial NUCCA intervention required three consecutive visits: (1) Day One, atlas misalignment assessment, before-correction radiographs; (2) Day Two, NUCCA correction with after-correction assessment with radiographs; and (3) Day Three, after-correction reassessment. Follow-up care occurred weekly for four weeks, then every two weeks for the remainder of the study period. At each NUCCA visit, subjects completed a current assessment of headache pain (please rate your headache pain on average over the past week) using a straight edge and pencil in marking a 100?mm line (VAS). One week after the initial intervention, subjects completed a �Possible Reaction to Care� questionnaire. This assessment has past been used for successfully monitoring adverse events related to various upper cervical correction procedures [24].
At week four, PC-MRI data were obtained and subjects completed an MSQL and HIT-6. End of study PC-MRI data were collected at week eight followed by a neurologist exit interview. Here, subjects completed final MSQOL, HIT-6, MIDAS, and VAS outcomes and headache diaries were collected.
At the week-8 neurologist visit, two willing subjects were offered a long-term follow-up opportunity for a total study period of 24 weeks. This involved further NUCCA reassessment monthly for 16 weeks after completion of the initial 8-week study. The purpose of this follow-up was to help determine if headache improvement continued contingent upon maintenance of atlas alignment while observing for any long-term effect of NUCCA care on ICCI. Subjects desiring to participate signed a second informed consent for this phase of study and continued monthly NUCCA care. At the end of 24 weeks from the original atlas intervention, the fourth PC-MRI imaging study occurred. At the neurologist exit interview, final MSQOL, HIT-6, MIDAS, and VAS outcomes and headache diaries were collected.
The same NUCCA procedure as previously reported was followed using the established protocol and standards of care developed through NUCCA Certification for assessment and atlas realignment or correction of the ASC (see Figures ?Figures22�5) [2, 13, 25]. Assessment for the ASC includes screening for functional leg-length inequality with the Supine Leg Check (SLC) and examination of postural symmetry using the Gravity Stress Analyzer (Upper Cervical Store, Inc., 1641 17 Avenue, Campbell River, BC, Canada V9W 4L5) (see Figures ?Figures22 and 3(a)�3(c)) [26�28]. If SLC and postural imbalances are detected, a three-view radiographic exam is indicated to determine the multidimensional orientation and degree of craniocervical misalignment [29, 30]. A thorough radiographic analysis provides information to determine a subject specific, optimal atlas correction strategy. The clinician locates anatomic landmarks from the three-view series, measuring structural and functional angles that have deviated from established orthogonal standards. The degree of misalignment and atlas orientation are then revealed in three dimensions (see Figures 4(a)�4(c)) [2, 29, 30]. Radiographic equipment alignment, reduction of collimator port size, high-speed film-screen combinations, special filters, specialized grids, and lead shielding minimize subject radiation exposure. For this study, average total measured Entrance Skin Exposure to subjects from the before-after-correction radiographic series was 352 millirads (3.52 millisieverts).
Figure 2: Supine Leg Check Screening Test (SLC). Observation of an apparent �short leg� indicates possible atlas misalignment. These appear even.
Figure 3: Gravity Stress Analyzer (GSA). (a) Device determines postural asymmetry as a further indicator of atlas misalignment. Positive findings in the SLC and GSA indicate need for NUCCA radiographic series. (b) Balanced patient with no postural asymmetry. (c) Hip calipers used to measure pelvis asymmetry.
Figure 4: NUCCA radiograph series. These films are used to determine atlas misalignment and developing a correction strategy. After-correction radiographs or postfilms ensure the best correction has been made for that subject.
Figure 5: Making a NUCCA correction. The NUCCA practitioner delivers a triceps pull adjustment. The practitioner’s body and hands are aligned to deliver an atlas correction along an optimal force vector using information obtained from radiographs.
The NUCCA intervention involves a manual correction of the radiographically measured misalignment in the anatomical structure between the skull, atlas vertebra, and cervical spine. Utilizing biomechanical principles based on a lever system, the doctor develops a strategy for proper
subject positioning,
practitioner stance,
force vector to correct the atlas misalignment.
Subjects are placed on a side-posture table with the head specifically braced using a mastoid support system. Application of the predetermined controlled force vector for the correction realigns the skull to the atlas and neck to the vertical axis or center of gravity of the spine. These corrective forces are controlled in depth, direction, velocity, and amplitude, producing an accurate and precise reduction of the ASC.
Using the pisiform bone of the contact hand, the NUCCA practitioner contacts the atlas transverse process. The other hand encircles the wrist of the contact hand, to control the vector while maintaining the depth of force generated in application of the �triceps pull� procedure (see Figure 5) [3]. By understanding spinal biomechanics, the practitioner’s body and hands are aligned to produce an atlas correction along the optimal force vector. The controlled, nonthrusting force is applied along the predetermined reduction pathway. It is specific in its direction and depth to optimize the ASC reduction assuring no activation in the reactive forces of the neck muscles in response to the biomechanical change. It is understood that an optimal reduction of the misalignment promotes long-term maintenance and stability of spinal alignment.
Following a short rest period, an after-assessment procedure, identical to the initial evaluation, is performed. A postcorrection radiograph examination uses two views to verify return of the head and cervical spine into optimum orthogonal balance. Subjects are educated in ways to preserve their correction, thus preventing another misalignment.
Subsequent NUCCA visits were comprised of headache diary checks and a current assessment of headache pain (VAS). Leg length inequality and excessive postural asymmetry were used in determining the need for another atlas intervention. The objective for optimal improvement is for the subject to maintain the realignment for as long as possible, with the fewest number of atlas interventions.
In a PC-MRI sequence, contrast media are not used. PC-MRI methods collected two data sets with different amounts of flow sensitivity acquired by relating gradient pairs, which sequentially dephase and rephase spins during the sequence. The raw data from the two sets are subtracted to calculate a flow rate.
An on-site visit by the MRI Physicist provided training for the MRI Technologist and a data transfer procedure was established. Several practice scans and data transfers were performed to ensure data collection succeeded without challenges. A 1.5-tesla GE 360 Optima MR scanner (Milwaukee, WI) at the study imaging center (EFW Radiology, Calgary, Alberta, Canada) was used in imaging and data collection. A 12-element phased array head coil, 3D magnetization-prepared rapid-acquisition gradient echo (MP-RAGE) sequence was used in anatomy scans. Flow sensitive data were acquired using a parallel acquisition technique (iPAT), acceleration factor 2.
To measure blood flow to and from the skull base, two retrospectively gated, velocity-encoded cine-phase-contrast scans were performed as determined by individual heart rate, collecting thirty-two images over a cardiac cycle. A high-velocity encoding (70?cm/s) quantified high-velocity blood flow perpendicular to the vessels at the C-2 vertebra level includes the internal carotid arteries (ICA), vertebral arteries (VA), and internal jugular veins (IJV). Secondary venous flow data of vertebral veins (VV), epidural veins (EV), and deep cervical veins (DCV) were acquired at the same height using a low-velocity encoding (7�9?cm/s) sequence.
Subject data were identified by Subject Study ID and imaging study date. The study neuroradiologist reviewed MR-RAGE sequences to rule out exclusionary pathologic conditions. Subject identifiers were then removed and assigned a coded ID permitting transfer via a secured tunnel IP protocol to the physicist for analysis. Using proprietary software volumetric blood, Cerebrospinal Fluid (CSF) flow rate waveforms and derived parameters were determined (MRICP version 1.4.35 Alperin Noninvasive Diagnostics, Miami, FL).
Using the pulsatility-based segmentation of lumens, time-dependent volumetric flow rates were calculated by integrating the flow velocities inside the luminal cross-sectional areas over all thirty-two images. Mean flow rates were obtained for the cervical arteries, primary venous drainage, and secondary venous drainage pathways. Total cerebral blood flow was obtained by summation of these mean flow rates.
A simple definition of compliance is a ratio of volume and pressure changes. Intracranial compliance is calculated from the ratio of the maximal (systolic) intracranial volume change (ICVC) and pressure fluctuations during the cardiac cycle (PTP-PG). Change in ICVC is obtained from momentary differences between volumes of blood and CSF entering and exiting the cranium [5, 31]. Pressure change during the cardiac cycle is derived from the change in the CSF pressure gradient, which is calculated from the velocity-encoded MR images of the CSF flow, using the Navier-Stokes relationship between derivatives of velocities and the pressure gradient [5, 32]. An intracranial compliance index (ICCI) is calculated from the ratio of ICVC and pressure changes [5, 31�33].
Statistical analysis considered several elements. ICCI data analysis involved a one-sample Kolmogorov-Smirnov test revealing a lack of normal distribution in the ICCI data, which were therefore described using the median and interquartile range (IQR). Differences between baseline and follow-up were to be examined using a paired t-test.
NUCCA assessments data were described using mean, median, and interquartile range (IQR). Differences between baseline and follow-up were examined using a paired t-test.
Depending on the outcome measure, baseline, week four, week eight, and week twelve (MIDAS only) follow-up values were described using the mean and standard deviation. MIDAS data collected at initial neurologist screening had one follow-up score at the end of twelve weeks.
Differences from baseline to each follow-up visit were tested using a paired t-test. This resulted in numerous p values from two follow-up visits for each outcome except the MIDAS. Since one purpose of this pilot is to provide estimates for future research, it was important to describe where differences occurred, rather than to use a one-way ANOVA to arrive at a single p value for each measure. The concern with such multiple comparisons is the increase in Type I error rate.
To analyze the VAS data, each subject scores were examined individually and then with a linear regression line that adequately fits the data. Use of a multilevel regression model with both random intercepts and random slope provided an individual regression line fitted for each patient. This was tested against a random intercept-only model, which fits a linear regression line with a common slope for all subjects, while intercept terms are allowed to vary. The random coefficient model was adopted, as there was no evidence that random slopes significantly improved the fit to the data (using a likelihood ratio statistic). To illustrate the variation in the intercepts but not in the slope, the individual regression lines were graphed for each patient with an imposed average regression line on top.
Results
From initial neurologist screening, eighteen volunteers were eligible for inclusion. After completion of baseline headache diaries, five candidates did not meet inclusion criteria. Three lacked the required headache days on baseline diaries to be included, one had unusual neurological symptoms with persistent unilateral numbness, and another was taking a calcium channel blocker. The NUCCA practitioner found two candidates ineligible: one lacking an atlas misalignment and the second with a Wolff-Parkinson-White condition and severe postural distortion (39�) with recent involvement in a severe high impact motor vehicle accident with whiplash (see Figure 1).
Eleven subjects, eight females and three males, average age forty-one years (range 21�61 years), qualified for inclusion. Six subjects presented chronic migraine, reporting fifteen or more headache days a month, with a total eleven-subject mean of 14.5 headache days a month. Migraine symptom duration ranged from two to thirty-five years (mean twenty-three years). All medications were maintained unchanged for the study duration to include their migraine prophylaxis regimens as prescribed.
Per exclusion criteria, no subjects included received a diagnosis of headache attributed to traumatic injury to the head and neck, concussion, or persistent headache attributed to whiplash. Nine subjects reported a very remote past history, greater than five years or more (average of nine years) prior to neurologist screen. This included sports-related head injuries, concussion, and/or whiplash. Two subjects indicated no prior head or neck injury (see Table 2).
Table 2: Subject intracranial compliance index (ICCI) data (n = 11). PC-MRI6 acquired ICCI1 data reported at baseline, week four, and week eight following NUCCA5 intervention. Bolded rows signify subject with secondary venous drainage route. MVA or mTBI occurred at least 5 years prior to study inclusion, average 10 years.
Individually, five subjects demonstrated an increase in ICCI, three subject’s values remained essentially the same, and three showed a decrease from baseline to end of study measurements. Overall changes in intracranial compliance are seen in Table 2 and Figure 8. The median (IQR) values of ICCI were 5.6 (4.8, 5.9) at baseline, 5.6 (4.9, 8.2) at week four, and 5.6 (4.6, 10.0) at week eight. Differences were not statistically different. The mean difference between baseline and week four was ?0.14 (95% CI ?1.56, 1.28), p = 0.834, and between baseline and week eight was 0.93 (95% CI ?0.99, 2.84), p = 0.307. These two subject’s 24-week ICCI study results are seen in Table 6. Subject 01 displayed an increasing trend in ICCI from 5.02 at baseline to 6.69 at week 24, whereas at week 8, results were interpreted as consistent or remaining the same. Subject 02 demonstrated a decreasing trend in ICCI from baseline of 15.17 to 9.47 at week 24.
Figure 8: Study ICCI data compared to previously reported data in the literature. The MRI time values are fixed at baseline, week 4, and week 8 after intervention. This study’s baseline values fall similar to the data reported by Pomschar on subjects presenting only with mTBI.
Table 6: 24-week ICCI findings showing an increasing trend in subject 01 whereas at end of study (week 8), results were interpreted as consistent or remaining the same. Subject 02 continued to show a decreasing trend in ICCI.
Table 3 reports changes in NUCCA assessments. The mean difference from before to after the intervention is as follows: (1) SLC: 0.73 inches, 95% CI (0.61, 0.84) (p < 0.001); (2) GSA: 28.36 scale points, 95% CI (26.01, 30.72) (p < 0.001); (3) Atlas Laterality: 2.36 degrees, 95% CI (1.68, 3.05) (p < 0.001); and (4) Atlas Rotation: 2.00 degrees, 95% CI (1.12, 2.88) (p < 0.001). This would indicate that a probable change occurred following the atlas intervention as based on subject assessment.
Table 3: Descriptive statistics [mean, standard deviation, median, and interquartile range (IQR2)] of NUCCA1 assessments before-after initial intervention (n = 11).
Headache diary results are reported in Table 4 and Figure 6. At baseline subjects had mean 14.5 (SD = 5.7) headache days per 28-day month. During the first month following NUCCA correction, mean headache days per month decreased by 3.1 days from baseline, 95% CI (0.19, 6.0), p = 0.039, to 11.4. During the second month headache days decreased by 5.7 days from baseline, 95% CI (2.0, 9.4), p = 0.006, to 8.7 days. At week eight, six of the eleven subjects had a reduction of >30% in headache days per month. Over 24 weeks, subject 01 reported essentially no change in headache days while subject 02 had a reduction of one headache day a month from study baseline of seven to end of study reports of six days.
Figure 6: Headache days and headache pain intensity from diary (n = 11). (a) Number of headache days per month. (b) Average headache intensity (on headache days). Circle indicates the mean and the bar indicates the 95% CI. Circles are individual subject scores. A significant decrease in headache days per month was noticed at four weeks, almost doubling at eight weeks. Four subjects (#4, 5, 7, and 8) exhibited a greater than 20% decrease in headache intensity. Concurrent medication use may explain the small decrease in headache intensity.
At baseline, mean headache intensity on days with headache, on a scale of zero to ten, was 2.8 (SD = 0.96). Mean headache intensity showed no statistically significant change at four (p = 0.604) and eight (p = 0.158) weeks. Four subjects (#4, 5, 7, and 8) exhibited a greater than 20% decrease in headache intensity.
Quality of life and headache disability measures are seen in Table 4. The mean HIT-6 score at baseline was 64.2 (SD = 3.8). At week four after NUCCA correction, mean decrease in scores was 8.9, 95% CI (4.7, 13.1), p = 0.001. Week-eight scores, compared to baseline, revealed mean decrease by 10.4, 95% CI (6.8, 13.9), p = 0.001. In the 24-week group, subject 01 showed a decrease of 10 points from 58 at week 8 to 48 at week 24 while subject 02 decreased 7 points from 55 at week 8 to 48 at week 24 (see Figure 9).
Figure 9: 24-week HIT-6 scores in long-term follow-up subjects. Monthly scores continued to decrease after week 8, end of first study. Based on Smelt et al. criteria, it can be interpreted that a within-person minimally important change occurred between week 8 and week 24. HIT-6: Headache Impact Test-6.
MSQL mean baseline score was 38.4 (SD = 17.4). At week four after correction, mean scores for all eleven subjects increased (improved) by 30.7, 95% CI (22.1, 39.2), p < 0.001. By week eight, end of study, mean MSQL scores had increased from baseline by 35.1, 95% CI (23.1, 50.0), p < 0.001, to 73.5. The follow-up subjects continued to show some improvement with increasing scores; however, many scores plateaued remaining the same since week 8 (see Figures 10(a)�10(c)).
Figure 10: ((a)�(c)) 24-week MSQL scores in long-term follow-up subjects. (a) Subject 01 has essentially plateaued after week 8 throughout to end of the second study. Subject 02 shows scores increasing over time demonstrating minimally important differences based on Cole et al. criteria by week 24. (b) Subject scores seem to peak by week 8 with both subjects showing similar scores reported at week 24. (c) Subject 2 scores remain consistent throughout the study while subject 01 shows steady improvement from baseline to the end of week 24. MSQL: Migraine-Specific Quality of Life Measure.
Mean MIDAS score at baseline was 46.7 (SD = 27.7). At two months after NUCCA correction (three months following baseline), the mean decrease in subject’s MIDAS scores was 32.1, 95% CI (13.2, 51.0), p = 0.004. The follow-up subjects continued to show improvement with decreasing scores with intensity showing minimal improvement (see Figures 11(a)�11(c)).
Figure 11: 24-week MIDAS scores in long-term follow-up subjects. (a) Total MIDAS scores continued a decreasing trend over the 24-week study period. (b) Intensity scores continued improvement. (c) While 24-week frequency was higher than at week 8, improvement is observed when compared to baseline. MIDAS: Migraine Disability Assessment Scale.
Assessment of current headache pain from VAS scale data is seen in Figure 7. The multilevel linear regression model showed evidence of a random effect for the intercept (p < 0.001) but not for the slope (p = 0.916). Thus, the adopted random intercept model estimated a different intercept for each patient but a common slope. The estimated slope of this line was ?0.044, 95% CI (?0.055, ?0.0326), p < 0.001, indicating that there was a significant decrease in the VAS score of 0.44 per 10 days after baseline (p < 0.001). The mean baseline score was 5.34, 95% CI (4.47, 6.22). The random effects analysis showed substantial variation in the baseline score (SD = 1.09). As the random intercepts are normally distributed, this indicates that 95% of such intercepts lie between 3.16 and 7.52 providing evidence of substantial variation in the baseline values across patients. VAS scores continued showing improvement in the 24-week two-subject follow-up group (see Figure 12).
Figure 7: Subject global assessment of headache (VAS) (n = 11). There was substantial variation in baseline scores across these patients. The lines show individual linear fit for each of eleven patients. The thick dotted black line represents the average linear fit across all eleven patients. VAS: Visual Analog Scale.
Figure 12: 24-week follow-up group global assessment of headache (VAS). When subjects were queried, �please rate your headache pain on average over the past week� VAS scores continued showing improvement in the 24-week two-subject follow-up group.
The most obvious reaction to the NUCCA intervention and care reported by ten subjects was mild neck discomfort, rated an average of three out of ten on pain assessment. In six subjects, pain began more than twenty-four hours after the atlas correction, lasting more than twenty-four hours. No subject reported any significant effect on their daily activities. All subjects reported satisfaction with NUCCA care after one week, median score, ten, on a zero to ten rating scale.
Dr. Alex Jimenez’s Insight
“I’ve been experiencing migraine headaches for several years now. Is there a reason for my head pain? What can I do to decrease or get rid of my symptoms?”�Migraine headaches are believed to be a complex form of head pain, however, the reason for them is much the same as any other type of headache. A traumatic injury to the cervical spine, such as that of whiplash from an automobile accident or a sports injury, can cause a misalignment in the neck and upper back, which may lead to migraine. An improper posture can also cause neck issues which could lead to head and neck pain. A healthcare professional who specializes in spinal health issues can diagnose the source of your migraine headaches. Furthermore, a qualified and experienced specialist can perform spinal adjustments as well as manual manipulations to help correct any misalignments of the spine which could be causing the symptoms. The following article summarizes a case study based on the improvement of symptoms after atlas vertebrae realignment in participants with migraine.
Discussion
In this limited cohort of eleven migraine subjects, there was no statistically significant change in ICCI (primary outcome) after the NUCCA intervention. However, a significant change in HRQoL secondary outcomes did occur as summarized in Table 5. The consistency in the magnitude and direction of improvement across these HRQoL measures indicates confidence in enhancement of headache health over the two-month study following the 28-day baseline period.
Table 5: Summary Comparison of Measured Outcomes
Based on the case study results, this investigation hypothesized a significant increase in ICCI after the atlas intervention which was not observed. Use of PC-MRI allows quantification of the dynamic relationship between arterial inflow, venous outflow, and CSF flow between the cranium and the spinal canal [33]. Intracranial compliance index (ICCI) measures the brain’s ability to respond to incoming arterial blood during systole. Interpretation of this dynamic flow is represented by a monoexponential relationship existing between CSF volume and CSF pressure. With increased or higher intracranial compliance, also defined as good compensatory reserve, the incoming arterial blood can be accommodated by the intracranial contents with a smaller change in intracranial pressure. While a change in intracranial volume or pressure could occur, based on the exponential nature of the volume-pressure relationship, a change in after-intervention ICCI may not be realized. An advanced analysis of the MRI data and further study are required for pinpointing practical quantifiable parameters to use as an objective outcome sensitive for documenting a physiologic change following atlas correction.
Koerte et al. reports of chronic migraine patients demonstrate a significantly higher relative secondary venous drainage (paraspinal plexus) in the supine position when compared to age- and gender-matched controls [34]. Four study subjects exhibited a secondary venous drainage with three of those subjects demonstrating notable increase in compliance after intervention. The significance is unknown without further study. Similarly, Pomschar et al. reported that subjects with mild traumatic brain injury (mTBI) demonstrate an increased drainage through the secondary venous paraspinal route [35]. The mean intracranial compliance index appears significantly lower in the mTBI cohort when compared to controls.
Some perspective may be gained in comparison of this study’s ICCI data to previously reported normal subjects and those with mTBI seen in Figure 8 [5, 35]. Limited by the small number of subjects studied, the significance these study’s findings may have in relation to Pomschar et al. remains unknown, offering only speculation of possibilities for future exploration. This is further complicated by the inconsistent ICCI change observed in the two subjects followed for 24 weeks. Subject two with a secondary drainage pattern exhibited a decrease in ICCI following intervention. A larger placebo controlled trial with a statistically significant subject sample size could possibly demonstrate a definitive objectively measured physiologic change after application of the NUCCA correction procedure.
HRQoL measures are used clinically to assess the effectiveness of a treatment strategy to decrease pain and disability related to migraine headache. It is expected that an effective treatment improves patient perceived pain and disability measured by these instruments. All HRQoL measures in this study demonstrated significant and substantial improvement by week four following the NUCCA intervention. From week four to week eight only small improvements were noted. Again, only small improvements were noted in the two subjects followed for 24 weeks. While this study was not intended to demonstrate causation from the NUCCA intervention, the HRQoL results create compelling interest for further study.
From the headache diary, a significant decrease in headache days per month was noticed at four weeks, almost doubling at eight weeks. However, significant differences in headache intensity over time were not discernable from this diary data (see Figure 5). While the number of headaches decreased, subjects still used medication to maintain headache intensity at tolerable levels; hence, it is supposed that a statistically significant difference in headache intensity could not be determined. Consistency in the headache day numbers occurring in week 8 in the follow-up subjects could guide future study focus in determining when maximum improvement occurs to help in establishing a NUCCA standard of migraine care.
Clinically relevant change in the HIT-6 is important for completely understanding observed outcomes. A clinically meaningful change for an individual patient has been defined by the HIT-6 user guide as ?5 [36]. Coeytaux et al., using four different analysis methods, suggest that a between-group difference in HIT-6 scores of 2.3 units over time may be considered clinically significant [37]. Smelt et al. studied primary care migraine patient populations in developing suggested recommendations using HIT-6 score changes for clinical care and research [38]. Dependent on consequences resulting from false positives or negatives, within-person minimally important change (MIC) using a �mean change approach� was estimated to be 2.5 points. When using the �receiver operating characteristic (ROC) curve analysis� a 6-point change is needed. Recommended between-group minimally important difference (MID) is 1.5 [38].
Using the �mean change approach,� all subjects but one reported a change (decrease) greater than ?2.5. The �ROC analyses� also demonstrated improvement by all subjects but one. This �one subject� was a different person in each comparison analysis. Based on Smelt et al. criteria, the follow-up subjects continued to demonstrate within-person minimally important improvement as seen in Figure 10.
All subjects but two showed improvement on the MIDAS score between baseline and three-month results. The magnitude of the change was proportional to the baseline MIDAS score, with all subjects but three reporting an overall fifty percent or greater change. The follow-up subjects continued to show improvement as seen in continued decrease in scores by week 24; see Figures 11(a)�11(c).
Use of the HIT-6 and MIDAS together as a clinical outcome may provide a more complete assessment of headache-related disability factors [39]. The differences between the two scales can predict disability from headache pain intensity and headache frequency, by providing more information on factors related to the reported changes than either outcome used alone. While the MIDAS appears to change more by headache frequency, headache intensity seems to affect HIT-6 score more than the MIDAS [39].
How migraine headache affects and limits patient perceived daily functioning is reported by the MSQL v. 2.1, across three 3 domains: role restrictive (MSQL-R), role preventive (MSQL-P), and emotional functioning (MSQL-E). An increase in scores indicates improvement in these areas with values ranging from 0 (poor) to 100 (best).
MSQL scales reliability evaluation by Bagley et al. report results to be moderately to highly correlated with HIT-6 (r = ?0.60 to ?0.71) [40]. Study by Cole et al. reports minimally important differences (MID) clinical change for each domain: MSQL-R = 3.2, MSQL-P = 4.6, and MSQL-E = 7.5 [41]. Results from the topiramate study report individual minimally important clinical (MIC) change: MSQL-R = 10.9, MSQL-P = 8.3, and MSQL-E = 12.2 [42].
All subjects except one experienced an individual minimally important clinical change for MSQL-R of greater than 10.9 by the week-eight follow-up in MSQL-R. All but two subjects reported changes of more than 12.2 points in MSQL-E. Improvement in MSQL-P scores increased by ten points or more in all subjects.
Regression analysis of VAS ratings over time showed a significant linear improvement over the 3-month period. There was substantial variation in baseline scores across these patients. Little to no variation was observed in the rate of improvement. This trend appears to be the same in the subjects studied for 24 weeks as seen in Figure 12.
Many studies using pharmaceutical intervention have shown a substantial placebo effect in patients from migrainous populations [43]. Determining possible migraine improvement over six months, using another intervention as well as no intervention, is important for any comparison of results. The investigation into placebo effects generally accepts that placebo interventions do provide symptomatic relief but do not modify pathophysiologic processes underlying the condition [44]. Objective MRI measures may help in revealing such a placebo effect by demonstrating a change in physiologic measurements of flow parameters occurring after a placebo intervention.
Use of a three-tesla magnet for MRI data collection would increase the reliability of the measurements by increasing the amount of data used to make the flow and ICCI calculations. This is one of the first investigations using change in ICCI as an outcome in evaluating an intervention. This creates challenges in interpretation of MRI acquired data to base conclusions or further hypothesis development. Variability in relationships between blood flow to and from the brain, CSF flow, and heart rate of these subject-specific parameters has been reported [45]. Variations observed in a small three-subject repeated measures study have led to conclusions that information gathered from individual cases be interpreted with caution [46].
The literature further reports in larger studies significant reliability in collecting these MRI acquired volumetric flow data. Wentland et al. reported that measurements of CSF velocities in human volunteers and of sinusoidally fluctuating phantom velocities did not differ significantly between two MRI techniques used [47]. Koerte et al. studied two cohorts of subjects imaged in two separate facilities with different equipment. They reported that intraclass correlation coefficients (ICC) demonstrated a high intra- and interrater reliability of PC-MRI volumetric flow rate measurements remaining independent of equipment used and skill-level of the operator [48]. While anatomic variation exists between subjects, it has not prevented studies of larger patient populations in describing possible �normal� outflow parameters [49, 50].
Being based solely on patient subjective perceptions, there are limitations in using patient reported outcomes [51]. Any aspect affecting a subject’s perception in their quality of life is likely to influence the outcome of any assessment used. Lack of outcome specificity in reporting symptoms, emotions, and disability also limits interpretation of results [51].
Imaging and MRI data analysis costs precluded use of a control group, limiting any generalizability of these results. A larger sample size would allow for conclusions based on statistical power and reduced Type I error. Interpretation of any significance in these results, while revealing possible trends, remains speculation at best. The big unknown persists in the likelihood that these changes are related to the intervention or to some other effect unknown to the investigators. These results do add to the body of knowledge of previously unreported possible hemodynamic and hydrodynamic changes after a NUCCA intervention, as well as changes in migraine HRQoL patient reported outcomes as observed in this cohort.
The values of collected data and analyses are providing information required for estimation of statistically significant subject sample sizes in further study. Resolved procedural challenges from conducting the pilot allow for a highly refined protocol to successfully accomplish this task.
In this study, the lack of robust increase in compliance may be understood by the logarithmic and dynamic nature of intracranial hemodynamic and hydrodynamic flow, allowing individual components comprising compliance to change while overall it did not. An effective intervention should improve subject perceived pain and disability related to migraine headache as measured by these HRQoL instruments used. These study results suggest that the atlas realignment intervention may be associated with reduction in migraine frequency, marked improvement in quality of life yielding significant reduction in headache-related disability as observed in this cohort. The improvement in HRQoL outcomes creates compelling interest for further study, to confirm these findings, especially with a larger subject pool and a placebo group.
Acknowledgments
The authors acknowledge Dr. Noam Alperin, Alperin Diagnostics, Inc., Miami, FL; Kathy Waters, Study Coordinator, and Dr. Jordan Ausmus, Radiography Coordinator, Britannia Clinic, Calgary, AB; Sue Curtis, MRI Technologist, Elliot Fong Wallace Radiology, Calgary, AB; and Brenda Kelly-Besler, RN, Research Coordinator, Calgary Headache Assessment and Management Program (CHAMP), Calgary, AB. Financial support is provided by (1) Hecht Foundation, Vancouver, BC; (2) Tao Foundation, Calgary, AB; (3) Ralph R. Gregory Memorial Foundation (Canada), Calgary, AB; and (4) Upper Cervical Research Foundation (UCRF), Minneapolis, MN.
Abbreviations
ASC: Atlas subluxation complex
CHAMP: Calgary Headache Assessment and Management Program
CSF: Cerebrospinal Fluid
GSA: Gravity Stress Analyzer
HIT-6: Headache Impact Test-6
HRQoL: Health Related Quality of Life
ICCI: Intracranial compliance index
ICVC: Intracranial volume change
IQR: Interquartile range
MIDAS: Migraine Disability Assessment Scale
MSQL: Migraine-Specific Quality of Life Measure
MSQL-E: Migraine-Specific Quality of Life Measure-Emotional
MSQL-P: Migraine-Specific Quality of Life Measure-Physical
MSQL-R: Migraine-Specific Quality of Life Measure-Restrictive
NUCCA: National Upper Cervical Chiropractic Association
PC-MRI: Phase Contrast Magnetic Resonance Imaging
SLC: Supine Leg Check
VAS: Visual Analog Scale.
Conflict of Interests
The authors declare that there are no financial or any other competing interests regarding the publication of this paper.
Authors’ Contribution
H. Charles Woodfield III conceived the study, was instrumental in its design, helped in coordination, and helped to draft the paper: introduction, study methods, results, discussion, and conclusion. D. Gordon Hasick screened subjects for study inclusion/exclusion, provided NUCCA interventions, and monitored all subjects on follow-up. He participated in study design and subject coordination, helping to draft the Introduction, NUCCA Methods, and Discussion of the paper. Werner J. Becker screened subjects for study inclusion/exclusion, participated in study design and coordination, and helped to draft the paper: study methods, results and discussion, and conclusion. Marianne S. Rose performed statistical analysis on study data and helped to draft the paper: statistical methods, results, and discussion. James N. Scott participated in study design, served as the imaging consultant reviewing scans for pathology, and helped to draft the paper: PC-MRI methods, results, and discussion. All authors read and approved the final paper.
In conclusion, the case study regarding the improvement of migraine headache symptoms following atlas vertebrae realignment demonstrated an increase in the primary outcome, however, the average results of the research study also demonstrated no statistical significance. Altogether, the case study concluded that patients who received atlas vertebrae realignment treatment experienced considerable improvement in symptoms with decreased headache days. Information referenced from the National Center for Biotechnology Information (NCBI). The scope of our information is limited to chiropractic as well as to spinal injuries and conditions. To discuss the subject matter, please feel free to ask Dr. Jimenez or contact us at 915-850-0900 .
Curated by Dr. Alex Jimenez
Additional Topics: Neck Pain
Neck pain is a common complaint which can result due to a variety of injuries and/or conditions. According to statistics, automobile accident injuries and whiplash injuries are some of the most prevalent causes for neck pain among the general population. During an auto accident, the sudden impact from the incident can cause the head and neck to jolt abruptly back-and-forth in any direction, damaging the complex structures surrounding the cervical spine. Trauma to the tendons and ligaments, as well as that of other tissues in the neck, can cause neck pain and radiating symptoms throughout the human body.
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