Can physical therapy with instrument-assisted soft tissue mobilization or IASTM improve mobility, flexibility, and health for individuals with musculoskeletal injuries or illnesses?
Instrument Assisted Soft Tissue Mobilization
Instrument-assisted soft tissue mobilization or IASTM is also known as the Graston technique. It is a myofascial release and massage technique used in physical therapy where the therapist uses metal or plastic tools to improve soft tissue mobility in the body. The ergonomically shaped tool is gently or vigorously scraped and rubbed across the injured or painful area. The rubbing is used to locate and release tightness in the fascia/collagen covering the muscles and the tendons. This helps reduce pain and improve movement.
Individuals often develop tissue tightness or restrictions in the muscles and fascia after an injury. These soft tissue restrictions can limit the range of motion – ROM and can trigger pain symptoms. (Kim J, Sung DJ, Lee J. 2017)
History
The Graston technique of instrument-assisted soft tissue mobilization was developed by an athlete who created their instruments to treat soft tissue injuries. The practice has grown with input from medical experts, trainers, researchers, and clinicians.
Physical therapists use different types of tools to perform IASTM.
These massage instruments comprise various types for specific massage and release.
The Graston company designs some of the tools.
Other companies have their version of metal or plastic scraping and rubbing tools.
The objective is to help release soft tissue and myofascial restrictions to improve body movement. (Kim J, Sung DJ, Lee J. 2017)
How It Works
The theory is that scraping the tissues causes microtrauma to the affected area, activating the body’s natural inflammatory response. (Kim J, Sung DJ, Lee J. 2017)
The body activates to reabsorb the tightened or scar tissue, causing the restriction.
The therapist can then stretch the adhesions to alleviate pain and improve mobility.
Treatment
Certain conditions respond well to instrument-assisted soft tissue mobilization, including (Kim J, Sung DJ, Lee J. 2017)
Limited mobility
Decreased muscle recruitment
Loss of range of motion – ROM
Pain with movement
Excessive scar tissue formation
Augmented soft tissue mobilization or ASTM techniques can treat certain injuries and medical conditions that include:
A review compared hands-on myofascial release to instrument myofascial release for chronic low back pain. (Williams M. 2017)
Little difference was found between the two techniques for pain relief.
Another review compared IASTM to other methods for treating pain and function loss. (Matthew Lambert et al., 2017)
The researchers concluded that IASTM could positively affect blood circulation and tissue flexibility and reduce pain.
Another study examined the use of IASTM, pseudo-fake ultrasound therapy, and spinal manipulation for patients with thoracic/upper back pain. (Amy L. Crothers et al., 2016)
All groups improved over time with no significant negative events.
The researchers concluded that instrument-assisted soft tissue mobilization is no more or less effective than spinal manipulation or pseudo-ultrasound therapy for thoracic back pain.
Every case is different, and musculoskeletal conditions respond differently to various treatments. For any questions or concerns, contact your primary healthcare provider to determine if IASTM is an appropriate treatment that can help.
From Injury To Recovery
References
Kamali, F., Panahi, F., Ebrahimi, S., & Abbasi, L. (2014). Comparison between massage and routine physical therapy in women with sub acute and chronic nonspecific low back pain. Journal of back and musculoskeletal rehabilitation, 27(4), 475–480. doi.org/10.3233/BMR-140468
Kim, J., Sung, D. J., & Lee, J. (2017). Therapeutic effectiveness of instrument-assisted soft tissue mobilization for soft tissue injury: mechanisms and practical application. Journal of exercise rehabilitation, 13(1), 12–22. doi.org/10.12965/jer.1732824.412
Chughtai, M., Newman, J. M., Sultan, A. A., Samuel, L. T., Rabin, J., Khlopas, A., Bhave, A., & Mont, M. A. (2019). Astym® therapy: a systematic review. Annals of translational medicine, 7(4), 70. doi.org/10.21037/atm.2018.11.49
Matthew Lambert, Rebecca Hitchcock, Kelly Lavallee, Eric Hayford, Russ Morazzini, Amber Wallace, Dakota Conroy & Josh Cleland (2017) The effects of instrument-assisted soft tissue mobilization compared to other interventions on pain and function: a systematic review, Physical Therapy Reviews, 22:1-2, 76-85, DOI: 10.1080/10833196.2017.1304184
Crothers, A. L., French, S. D., Hebert, J. J., & Walker, B. F. (2016). Spinal manipulative therapy, Graston technique® and placebo for non-specific thoracic spine pain: a randomised controlled trial. Chiropractic & manual therapies, 24, 16. doi.org/10.1186/s12998-016-0096-9
Individuals turn to chiropractic care neck adjustments to help ease neck problems and alleviate pain. Some of the different types of neck-cervical conditions that chiropractic treats include:
Cervical intervertebral disc injuries
Cervical sprain injuries
Degenerative joint syndrome of the neck
Facet joint sprain
Whiplash
A chiropractor will evaluate the whole spine because other regions may be affected and/or contribute to the problems. They will determine areas of restricted movement and will look at walking gait, overall posture, and spinal alignment. Before deciding which approach to use, the chiropractor will thoroughly examine the specific cause of the problems. Neck adjustments consist of various techniques and methods.
Neck Adjustments
Cervical Mobilization
Cervical mobilization focuses on using gentle motions around the neck.
This adjustment is best for reducing pain and increasing the neck’s range of motion.
Cervical Drop
The cervical drop technique requires the individual to lie on their stomach or side as the chiropractor adjusts the neck, and to prevent any added pressure around the neck, the headrest drops.
After the chiropractor prepares the neck for the adjustment, they will work on specific points, release the headrest, and quickly twist the neck.
This technique improves spinal flexibility by placing the vertebrae in their correct position.
Manual Traction
The patient sits in a chair for this neck adjustment.
Manual traction allows the chiropractor to move the neck at different angles and helps them determine the right amount of force during the adjustment.
A chiropractor will cradle the head in the palms of their hands and quickly move it from side to side.
Soft Tissue Massage
This technique is often used after a complete adjustment.
A chiropractor will gently massage the neck and apply pressure to any inflamed areas.
This increases blood circulation and prevents muscles from tensing and contracting.
Chiropractic Benefits
The benefits that come with using chiropractic neck adjustments include.
Improves Flexibility
One benefit of chiropractic neck adjustments is that they improve your flexibility.
Tight muscles or joints out of place make it harder for the neck to move, limiting its range of motion.
Chiropractic works to reduce poor flexibility by ensuring the bones and muscles are in their proper position.
Prevents Tension
Individuals that deal with severe tension often notice their neck and upper back feeling sore.
Tension tightens the muscles and can cause them to press on nerves.
If too much pressure is on them, the nerves can send out painful pulses.
A chiropractor will feel around the neck and shoulders to identify areas of concern. After the examination, they will make the proper adjustments to reduce pressure on the nerves and calm inflamed muscles.
Prevents Arthritis
Arthritis causes inflammation throughout the body. If not treated, this inflammation can increase the wearing down of bones.
Worn-down bones reduce strength and can irritate nerves.
Chronic neck pain could indicate that the joints in the neck are misplaced.
If these joints are not correctly realigned, the constant friction can begin to break down the bones leading to arthritis.
Chiropractic neck adjustments prevent this by ensuring the joints are in place and maintaining joint health by flushing toxins in and around them.
Anti-Inflammatory Food
Most neck pain is the result of inflammation. Individuals can take synthetic medications to reduce inflammation, but they have side effects. It is recommended to add natural anti-inflammatory foods to one’s diet. These won’t only reduce inflammation but can increase energy levels and help the body heal quicker. A few recommended foods include:
Heart disease is the leading cause of death of adults in the United States. Many factors can contribute to heart disease, and research has pointed to inflammation caused by obesity as one of the most significant factors contributing to the development. The main culprits are cytokines produced by excess fat in the body. These cytokines cause inflammation of the walls of the arteries, causing damage and increasing blood pressure. Blood pressure is the force of blood pushing against the walls of the blood vessels. When high blood pressure is present, the heart does not pump blood effectively, causing the heart to enlarge. An enlarged heart is a significant risk factor for heart failure if steps are not taken to remedy it.
References
Bradley S. Polkinghorn, Christopher J. Colloca, Chiropractic treatment of postsurgical neck syndrome with mechanical force manually assisted short-lever spinal adjustments, Journal of Manipulative and Physiological Therapeutics, Volume 24, Issue 9,
2001, Pages 589-595, ISSN 0161-4754, doi.org/10.1067/mmt.2001.118985. (www.sciencedirect.com/science/article/pii/S0161475401836915)
Haldeman S. Principles and Practice of Chiropractic. York, PA: McGraw-Hill; 2005.
Hawk, Cheryl et al. “Best Practices for Chiropractic Management of Patients with Chronic Musculoskeletal Pain: A Clinical Practice Guideline.” Journal of alternative and complementary medicine (New York, N.Y.) vol. 26,10 (2020): 884-901. doi:10.1089/acm.2020.0181
Eric L. Hurwitz, Hal Morgenstern, Philip Harber, Gerald F. Kominski, Fei Yu, and Alan H. Adams, 2002: A Randomized Trial of Chiropractic Manipulation and Mobilization for Patients With Neck Pain: Clinical Outcomes From the UCLA Neck-Pain Study American Journal of Public Health 92, 1634_1641, doi.org/10.2105/AJPH.92.10.1634
Wang, Zhaoxia, and Tomohiro Nakayama. “Inflammation, a link between obesity and cardiovascular disease.” Mediators of inflammation vol. 2010 (2010): 535918. doi:10.1155/2010/535918
Individuals experiencing radiculopathy in and around the neck notice it immediately often driving them to the medicine cabinet. This condition presents with:
Acute pain
Numbness
Muscle spasms
However, medication will only help relieve the pain temporarily but it won’t alleviate what is causing the radiculopathy. This is because pain medication/s can exacerbate the condition by blocking the pain signals with the root nerve issue never being resolved. Chiropractic is a complete solution that specifically mobilizes the cervical joints where nerve impingement is happening. The objective is to help individuals understand the underlying cause of the acute pain induced by radiculopathy and provide long-term pain relief through cervical joint mobilization.
Radiculopathy Pain
To determine what cervical nerve bundles are being affected by a subluxation or vertebral compression a chiropractor needs to isolate the pain. This is accomplished through a description of symptoms, radiological imaging to provide visual confirmation, and an examination of the affected area. Isolating the pain allows the chiropractor to determine the extent of misalignment and how much the nerve is being compressed. This will help in the development of a customized treatment plan. A chiropractor will be able to see and feel the degree of pressure being placed on the nerve or bundle of nerves.
Mobilizing The Cervical Joints
Chiropractors approach this directly based on the individual and the severity of the case. The most common joint mobilizations include:
Low-impact adjusting will shift the misaligned vertebrae back into place
Adjustments to the opposite non-painful area will help counterbalance stress in the spine
Radiculopathy improvement consists of:
The cervical spine is stabilized through bracing and posture supports
Isometric exercises will recondition the neck, shoulders, and upper back
Range of motion exercises will prevent any subtle compression/s
Corrective restoration of the cervical spine’s curve
The spine returns to normal during cervical joint mobilization and alleviates radiculopathy immediately and long term.
Proper chiropractic care will correct the affected nerve bundle, and stabilize the cervical spine to prevent/resist:
Compression
Translation
Subluxation
Other shifts that can occur
Chiropractic Mobilization Long Term Relief
A pinched nerve should not be treated with over-the-counter medications for long-term health. Corrective chiropractic mobilization is a recommended course of action for alleviating this and other musculoskeletal conditions. Chiropractic understands the nature and severity of radiculopathy as well as developing the proper customized treatment plan that will bring optimal results.
Body Composition
DASH Diet Example
Breakfast
3/4 cup bran flakes cereal with 1 banana and 1 cup low-fat milk
1 slice whole-wheat bread with 1 tsp. unsalted butter
1 orange
1 cup coffee
Lunch
Sandwich 2 slices of whole-wheat bread
3 oz. grilled thin chicken breast
2 slices low-fat cheese
1 tbsp. mustard
Salad
1/2 cup chopped/diced cucumbers
1/2 cup chopped/diced tomatoes
1 tablespoon sunflower seeds
1 teaspoon low-calorie non-cream dressing
1/2 cup fruit cocktail with no sugar
Snack
1/3 cup unsalted almonds
Dinner
3 oz. lean beef with 2 tbsp. fat-free, low sodium gravy
The information herein is not intended to replace a one-on-one relationship with a qualified health care professional, licensed physician, and is not medical advice. We encourage you to make your own health care decisions based on your research and partnership with a qualified health care professional. Our information scope is limited to chiropractic, musculoskeletal, physical medicines, wellness, sensitive health issues, functional medicine articles, topics, and discussions. We provide and present clinical collaboration with specialists from a wide array of disciplines. Each specialist is governed by their professional scope of practice and their jurisdiction of licensure. We use functional health & wellness protocols to treat and support care for the musculoskeletal system’s injuries or disorders. Our videos, posts, topics, subjects, and insights cover clinical matters, issues, and topics that relate to and support, directly or indirectly, our clinical scope of practice.* Our office has made a reasonable attempt to provide supportive citations and has identified the relevant research study or studies supporting our posts. We provide copies of supporting research studies available to regulatory boards and the public upon request. We understand that we cover matters that require an additional explanation of how it may assist in a particular care plan or treatment protocol; therefore, to further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900.
Dr. Alex Jimenez DC, MSACP, CCST, IFMCP*, CIFM*, CTG*
email: coach@elpasofunctionalmedicine.com
phone: 915-850-0900
Licensed in Texas & New Mexico
Open Orthop J. 2016. A Qualitative Description of Chronic Neck Pain has Implications for Outcome Assessment and Classification. Available at: www.ncbi.nlm.nih.gov/pmc/articles/PMC5301418/
Evid Based Complement Alternat Med. 2015. Complementary and Alternative Medicine for the Management of Cervical Radiculopathy: An Overview of Systematic Reviews. Available at: www.ncbi.nlm.nih.gov/pmc/articles/PMC4541004/
Traditional medical treatment for sciatica can sometimes be not as effective or ineffective for individuals, but nerve flossing is an option that could help. Flossing is not something individuals expect to hear from a medical professional treating their sciatica. However, when sciatica does not respond to common treatment methods like light physical activity or medications, a physician, chiropractor, or physical therapist might suggest combining traditional treatment with nerve flossing to alleviate sciatic nerve pain.
Nerve Flossing
The nerves can get jammed/stuck between the tissues and are not able to move, flex as they should. Nerve flossing involves performing gentle exercises to mobilize and stretch the nerves that help reduce irritation, inflammation, and improve mobility, especially in the hips. Nerve flossing is also known as:
The exercises can be done at home with no equipment and simple instructions. When used in combination with other treatments, like chiropractic and physical therapy the effectiveness is increased. Consult with a doctor or doctor of chiropractic for an accurate diagnosis, because what is causing sciatica helps significantly to determine the best treatment plan.
Guidelines
These are simple exercises but they are still exercises that require following safety guidelines to prevent injury or pain. These include:
The body will need time to adjust to new exercises so individuals should start slow
Only a few repetitions should be done at a time
Gradually increase
Stop if pain presents with any of the exercises and report the pain to a doctor or chiropractic physical therapist to see if there is a problem with how the exercises are being performed or if the exercises should be done later on after further treatment.
Focus on staying relaxed, as tensing up the muscles decreases the effectiveness
Breathing properly is key. Individuals unknowingly stop breathing when doing exercises, which is not healthy. Breathe deep in and out.
Nerve Exercises
True nerve flossing is an active movement with motion otherwise, it is just stretching.
Mobilizing floss
Lie on the floor with both knees bent, feet flat on the floor, and with space at hip-width
A flat pillow can be used for the head if it makes it more comfortable
Tuck the chin in and be sure to keep the upper body relaxed throughout the exercise
Pull the right leg in towards the chest
Keep holding behind the right knee
Slowly straighten the leg until there is a comfortable stretch
Slowly return the knee to the starting position
Breathe deeply, slowly, and try not to press the lower back into the floor
Lower the leg back towards the chest then lower it back to the starting position
Perform with the left leg
Complete five repetitions on each side
Seated nerve floss
Sitting upright in a chair, knees spaced hip-width, feet flat on the floor, and face forward
Extend the left leg
Flex the foot toward the body
Extend the head up and back looking up at the ceiling
Gently lower head and leg down, tucking the chin into the chest while bending the leg slightly backward
Extend and lower head at the same time when extending and lowering the leg
Perform 10 repetitions
Switch legs and repeat the exercise
Perform exercise 2–3 times every day
Hamstring floss
Stand up straight, raise the right leg onto a step or other stable surface while keeping the leg straight and toes pointed up
Keeping the back straight, tilt the head and neck forward until there is a slight pull/stretch in the back
Point the toe and bring the chin to the chest
Flex the foot and return
Repeat five times
Return to starting position
Switch legs
Repeat three sets on each leg
Exercise for Piriformis Syndrome
The piriformis muscle joins the base of the spine to the upper leg. Because this muscle is so close to the sciatic nerve, any type of irritation or compression of the sciatic nerve can also cause piriformis syndrome. Piriformis syndrome can cause radiating pain to the:
Hips
Buttocks
Hamstrings
Pain when sitting down or walking upstairs
Nerve flossing can also help relieve the symptoms increasing flexibility and range of motion.
Mobilizing stretch
Lie flat on the floor on the back
Extend both legs
Bend the right leg and bring it up
Hold the right knee and foot
While holding, gently pull the leg across the right side of the body and up toward the right shoulder
Return to the original position
Repeat five times
Gently lower the right leg
Switch legs
Complete five repetitions on each side two to three times a day
Risks
These exercises are not about pushing the body to its limits or in a way that causes pain. They are designed to rehabilitate, stretch, and strengthen the sciatic nerve making risks for further injury minimal. If there are still concerns about the safety of nerve flossing exercises, check with a doctor, doctor of chiropractic, or physical therapist. If there is severe nerve damage or undiagnosed acute pain, nerve flossing could worsen symptoms.Nerve flossing for acute cases of nerve irritation is not recommended as this can cause nerve root aggravation with the stretching/pulling.
There is a difference between being tired after a long day working, playing, etc, and being tired on a regular daily basis. This can be referred to as Chronic Fatigue Syndrome, a clinical condition where fatigue lasts longer than 6 months. With acute, non-clinical fatigue, it is typical to experience many of the symptoms that hamper an individual’s ability to function. Symptoms can include:
The information herein is not intended to replace a one-on-one relationship with a qualified health care professional, licensed physician, and is not medical advice. We encourage you to make your own health care decisions based on your research and partnership with a qualified health care professional. Our information scope is limited to chiropractic, musculoskeletal, physical medicines, wellness, sensitive health issues, functional medicine articles, topics, and discussions. We provide and present clinical collaboration with specialists from a wide array of disciplines. Each specialist is governed by their professional scope of practice and their jurisdiction of licensure. We use functional health & wellness protocols to treat and support care for the musculoskeletal system’s injuries or disorders. Our videos, posts, topics, subjects, and insights cover clinical matters, issues, and topics that relate to and support, directly or indirectly, our clinical scope of practice.* Our office has made a reasonable attempt to provide supportive citations and has identified the relevant research study or studies supporting our posts. We provide copies of supporting research studies available to regulatory boards and the public upon request. We understand that we cover matters that require an additional explanation of how it may assist in a particular care plan or treatment protocol; therefore, to further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900.
Dr. Alex Jimenez DC, MSACP, CCST, IFMCP, CIFM, CTG* email: coach@elpasofunctionalmedicine.com phone: 915-850-0900 Licensed in Texas & New Mexico
References
Anikwe EE, Tella BA, Aiyegbusi AI, Chukwu SC: Influence of Nerve Flossing Technique on acute sciatica and hip range of motion, International Journal of Medicine and Biomedical Research, 4(2) May – August 2015, www.ijmbr.com
Jeong UC, Kim CY, Park YH, Hwang-Bo G, Nam CW. The effects of self-mobilization techniques for the sciatic nerves on physical functions and health of low back pain patients with lower limb radiating pain. J Phys Ther Sci. 2016;28(1):46-50. doi:10.1589/jpts.28.46
Chiropractic spinal mobilization techniques involve the slow and steady movements of the spine’s joints reestablishing their range of motion. Because it is a slower treatment style the techniques are done with the hands. However, a chiropractor can use various instruments/tools as well.
Spinal mobilization treatment has the same focus as spinal manipulation. To get the body back to optimal health and allow the body to heal itself naturally. However, there can be a variety of reasons for utilizing spinal stabilization, with treatment depending on the patient’s needs, if there are underlying conditions, or previous injury/s, and individual preference.
Some prefer mobilization because it is gentler and does not generate the pops or cracking sounds. And the chiropractor’s style/specialization comes into play. Some work in the firm manipulation high-velocity style, while others utilize the softer mobilization style and others work in combination.
This adjustment re-alignment utilizes the necessary force to release the joint out of its restricted motion to improve mobility and reduce pain. There are various types of high-velocity low-amplitude manipulation approaches. These are the more common manipulation techniques:
Diversified Technique
This high-velocity low-amplitude technique is the one that is commonly associated with chiropractic manual adjustments. The chiropractor applies a short – low-amplitude, quick high-velocity thrust of the restricted joints. This is done one at a time with the objective to restore the normal range of motion. The patient is positioned in various positions to optimize the adjustment/alignment.
Gonstead Adjustment
The Gonstead technique is another high-velocity low amplitude adjustment. It is similar to the diversified technique. The difference is the evaluation performed to specifically locate the painful joint and positioning of the body as the treatment is performed. Chiropractic or physical therapy chairs and tables can be used to position the patient for optimal treatment, like a cervical chair or a chest-knee table.
Thompson Terminal Point Drop Technique
Here specialized treatment tables with sections that drop down during a high-velocity low-amplitude thrust. The idea is that as the table drops the piece dropped allows for easier movement of the joint. A cracking sound can sometimes be heard. It depends on the patient and their condition. This type of manipulation can also be done in a gentle fashion making it a form of spinal mobilization.
Spinal mobilization
Slow steady motion/movements are performed to mobilize the joint. Spinal mobilization can be recommended for certain individuals for different reasons like:
Individual preference for spinal mobilization over spinal manipulation
Individuals with a sensitive nervous system can benefit from the gentle technique. This can keep the body from experiencing a negative reaction that can cause muscle spasms or other issues.
Individuals with certain conditions could be given a recommendation for spinal mobilization. This could be:
Individuals in the acute stage of their condition and experiencing severe pain
Obesity can be a factor as the positioning and the manipulation procedures can be a challenge for the provider and the patient requiring a low force approach.
Mobilization Approaches
The more common spinal mobilization approaches include:
Activator Technique
The Activator is a hand-held, spring-loaded tool that generates a low-force impulse. A patient lies face down on the adjustment table, while the chiropractor:
Examines leg length
Performs muscle testing
Adjusts the spine and/or extremity joints
Cox Flexion-Distraction Technique
Here a gentle adjustment is designed to adjust the vertebrae by gently stretching the lower spine. This is usually performed in a series of repetitive slow movements like a steady rocking motion.
Toggle Drop
Here gravity is utilized to apply the adjustment. The chiropractors’ hands are crossed and on top of each other. Then the chiropractor presses down quickly and firmly on the area of the spine while a section of the table drops. The table sections can be raised and dropped according to the localization of the spinal adjustment.
McKenzie Technique
This technique incorporates active patient involvement, empowerment, and self-care as part of the treatment.
Spinal Release
The chiropractor separates the misaligned vertebrae by applying gentle pressure using the fingertips, with the objective to restore the spine back to a natural position.
Sacro-Occipital Technique – SOT
This technique utilizes wedges/blocks under the pelvis. This allows gravity with added low-force to assist the chiropractor to realign the pelvis.
Sciatica Alleviation
All of these techniques can be utilized by a chiropractor for sciatic nerve pain alleviation or can discover other conditions that could be mimicking sciatica.
Nerve mobilization techniques have been recently used as a method to adjust radiating pain related to disc disease, and in particular, mobilization techniques for the sciatic nerves improve mobility of the sciatic nerves, decrease mechanosensitivity of the nervous system, and heighten compliance of nerve tissues, relieving low back pain. Jeong, Ui-Cheol et al. �The effects of self-mobilization techniques for the sciatic nerves on physical functions and health of low back pain patients with lower limb radiating pain.��Journal of physical therapy science�vol. 28,1 (2016): 46-50. doi:10.1589/jpts.28.46
Sciatica Rehabilitation Causes and Symptoms
Dr. Alex Jimenez�s Blog Post Disclaimer
The scope of our information is limited to chiropractic, musculoskeletal, physical medicines, wellness, and sensitive health issues and/or functional medicine articles, topics, and discussions. We use functional health & wellness protocols to treat and support care for injuries or disorders of the musculoskeletal system. Our posts, topics, subjects, and insights cover clinical matters, issues, and topics that relate and support directly or indirectly our clinical scope of practice.*
Our office has made a reasonable attempt to provide supportive citations and has identified the relevant research study or studies supporting our posts. We also make copies of supporting research studies available to the board and or the public upon request. We understand that we cover matters that require an additional explanation as to how it may assist in a particular care plan or treatment protocol; therefore, to further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900. The provider(s) Licensed in Texas& New Mexico*
There is a multitude of chiropractic techniques for spinal alignment. They are used by chiropractors all over the world. All chiropractors have their favorite and specific techniques that they utilize. Depending on how long they have been practicing they can have five to ten different approaches or more refined techniques from years of experience.
The focus of these chiropractic techniques is to get the body back to optimal health and allow the body to heal itself naturally. As the body gets restored joint function is enhanced, muscle tension is released, and inflammation and pain are alleviated.
Various approaches use a form of force, hence the manipulation of the spine. The chiropractic adjustment technique that is the most common is spinal manipulation. It can also be called the diversified technique or HVLA – high-velocity, low-amplitude thrust.
However, chiropractic techniques are continually evolving. This comes from creating variations on existing techniques, a combination of techniques, or the chiropractor needs to adjust/tweak their own specific technique/s because they begin to suffer overuse injury/s from the constant adjusting, pushing, thrusting motions. Most techniques are named after the chiropractor that developed the method. These are the most common spinal manipulation techniques currently in use.
Manipulation Techniques
Chiropractic adapts to the condition/s and specific needs of each individual. Treatment plans can involve a forceful approach and a gentler force technique. This could happen during the same visit or the treatment plan could be half forceful adjustments, that could range from 6 to 10 visits, with the final visits using the gentle approach.
Spinal Manipulation
This is the High-Velocity Low-Amplitude Thrust technique. The most frequently used chiropractic technique. This is the manipulation that most are familiar with because of the audible pop that results. This is from the chiropractor’s hands applying a controlled quick forceful thrust to the spine while the body is positioned in a specific way.
Spinal Mobilization
This is the Low-Force/Gentle Chiropractic Technique. These techniques are for individuals that require a gentler approach. The technique is known as spinal mobilization. This approach could be utilized due to:
Underlying conditions like Osteoporosis for example
Some chiropractors prefer and/or specialize in mild spinal mobilization techniques. These are techniques that do not involve twisting the body or using forceful thrusts. Along with spinal mobilization, chiropractors often employ complementary therapy, as part of an overall treatment plan. This could be:
Ice
Heat
Physical therapy
Electric stimulation
Ultrasound
Individuals need to discuss symptoms and preferences with the chiropractor. It is their role to perform a thorough examination to determine the most optimal treatment plan satisfactory to the patient. Chiropractors are not the only health care providers who utilize spinal manipulation for back pain. Osteopathic physicians can also provide types of spinal adjustments. Physical and massage therapists often work with chiropractors with continued treatment. They are fully trained in providing spinal therapy as well.
Pregnancy Lower Back Pain Chiropractic Treatment
Dr. Alex Jimenez�s Blog Post Disclaimer
The scope of our information is limited to chiropractic, musculoskeletal, physical medicines, wellness, and sensitive health issues and/or functional medicine articles, topics, and discussions. We use functional health & wellness protocols to treat and support care for injuries or disorders of the musculoskeletal system. Our posts, topics, subjects, and insights cover clinical matters, issues, and topics that relate and support directly or indirectly our clinical scope of practice.*
Our office has made a reasonable attempt to provide supportive citations and has identified the relevant research study or studies supporting our posts. We also make copies of supporting research studies available to the board and or the public upon request. We understand that we cover matters that require an additional explanation as to how it may assist in a particular care plan or treatment protocol; therefore, to further discuss the subject matter above, please feel free to ask Dr. Alex Jimenez or contact us at 915-850-0900. The provider(s) Licensed in Texas& New Mexico*
A primary headache is characterized as head pain caused by a headache disorder itself. The three types of primary headache disorders include, migraine, tension-type headaches and cluster headaches. Head pain is a painful and debilitating symptom that can also occur as a result of another underlying cause. A secondary headache is characterized as head pain which occurs due to an injury and/or condition. A spinal misalignment, or subluxation, along the cervical spine, or neck, is commonly associated with a variety of headache symptoms.
Cervicogenic headache is a secondary headache caused by an injury and/or condition affecting the surrounding structures of the cervical spine, or neck. Many healthcare professionals will recommend the use of drugs/medications to help improve headache, however, several alternative treatment options can be safely and effectively used to treat secondary headaches. The purpose of the following article is to demonstrate the impact of upper cervical and upper thoracic manipulation versus mobilization and exercise in patients with cervicogenic headache.
Upper Cervical and Upper Thoracic Manipulation Versus Mobilization and Exercise in Patients with Cervicogenic Headache: a Multi-Center Randomized Clinical Trial
Abstract
Background: Although commonly utilized interventions, no studies have directly compared the effectiveness of cervical and thoracic manipulation to mobilization and exercise in individuals with cervicogenic headache (CH). The purpose of this study was to compare the effects of manipulation to mobilization and exercise in individuals with CH.
Methods: One hundred and ten participants (n?=?110) with CH were randomized to receive both cervical and thoracic manipulation (n?=?58) or mobilization and exercise (n?=?52). The primary outcome was headache intensity as measured by the Numeric Pain Rating Scale (NPRS). Secondary outcomes included headache frequency, headache duration, disability as measured by the Neck Disability Index (NDI), medication intake, and the Global Rating of Change (GRC). The treatment period was 4 weeks with follow-up assessment at 1 week, 4 weeks, and 3 months after initial treatment session. The primary aim was examined with a 2-way mixed-model analysis of variance (ANOVA), with treatment group (manipulation versus mobilization and exercise) as the between subjects variable and time (baseline, 1 week, 4 weeks and 3 months) as the within subjects variable.
Results: The 2X4 ANOVA demonstrated that individuals with CH who received both cervical and thoracic manipulation experienced significantly greater reductions in headache intensity (p?<?0.001) and disability (p?<?0.001) than those who received mobilization and exercise at a 3-month follow-up. Individuals in the upper cervical and upper thoracic manipulation group also experienced less frequent headaches and shorter duration of headaches at each follow-up period (p?<?0.001 for all). Additionally, patient perceived improvement was significantly greater at 1 and 4-week follow-up periods in favor of the manipulation group (p?<?0.001).
Conclusions: Six to eight sessions of upper cervical and upper thoracic manipulation were shown to be more effective than mobilization and exercise in patients with CH, and the effects were maintained at 3 months.
Trial registration: NCT01580280 April 16, 2012.
Keywords:Cervicogenic headache, Spinal manipulation, Mobilization, High velocity low amplitude thrust
Dr. Alex Jimenez’s Insight
In comparison to primary headache, such as migraine, cluster headache and tension-type headache, secondary headache is characterized as head pain caused by another illness or physical issue. In the case of cervicogenic headache, the cause of head pain is due to an injury and/or condition along the cervical spine and its surrounding structures, including the vertebrae, intervertebral discs and soft tissues. In addition, many healthcare professionals believe that primary headache can be associated with health issues in the cervical spine, or neck. Cervicogenic headache treatment should target the source of the symptoms and it can vary depending on the patient. Chiropractic care utilizes spinal adjustments and manual manipulations to carefully restore the original structure and function of the spine, helping to reduce stress and pressure in order to improve cervicogenic headache symptoms, among other type of headache. Chiropractic care can also be utilized to help treat primary headaches, such as migraines.
Background
The International Classification of Headache Disorders defines cervicogenic headache (CH) as, �headache caused by a disorder of the cervical spine and its component bony, disc, and/or soft tissue elements, usually but not invariably accompanied by neck pain.� [1] (p.760) The prevalence of CH has been reported to be between 0.4 and 20 % of the headache population [2, 3], and as high as 53 % in patients with headache after whiplash injury [4]. The dominant features of CH usually include: unilaterality of head pain without side-shift, elicitation of pain with external pressure over the ipsilateral upper neck, limited cervical range of motion, and the triggering of attacks by various awkward or sustained neck movements [4, 5].
Individuals with CH are frequently treated with spinal manipulative therapy including both mobilization and manipulation [6]. Spinal mobilization consists of slow, rhythmical, oscillating techniques whereas manipulation consists of high-velocity low-amplitude thrust techniques. [7] In a recent systematic review, Bronfort and colleagues reported that spinal manipulative therapy (both mobilization and manipulation) were effective in the management of adults with CH [8]. However, they did not report if manipulation resulted in superior outcomes compared to mobilization for the management of this population.
Several studies have investigated the effect of spinal manipulation in the management of CH [9�13]. Haas et al. [10] investigated the effectiveness of cervical manipulation in subjects with CH. Jull et al. [11] demonstrated treatment efficacy for manipulative therapy and/or exercise in the management of CH. However the manipulative therapy group included manipulation and mobilization therefore it cannot be determined if the beneficial effect was a result of the manipulation, mobilization or the combination.
A few studies have examined the benefits of manipulation versus mobilization for the management of mechanical neck pain with or without exercise [14�16]. However, no studies have directly compared the effects of manipulation versus mobilization and exercise in patients with CH. Considering the purported risks of manipulation [17], it is essential to determine if manipulation results in improved outcomes compared to mobilization for the management of patients with CH. Therefore, the purpose of this randomized clinical trial was to compare the effects of manipulation versus mobilization and exercise in patients with CH. We hypothesized that patients receiving manipulation over a 4-week treatment period would experience greater reductions in headache intensity, headache frequency, headache duration, disability, and medication intake at a 3-month follow-up than patients receiving cervical and thoracic mobilization combined with exercise.
Methods
Participants
In this multi-center randomized clinical trial, consecutive patients with CH presenting to 1 of 8 outpatient physical therapy clinics from a variety of geographical locations (Arizona, Georgia, New York, Ohio, Pennsylvania, South Carolina) were recruited over a 29-month period (from April 2012 to August 2014). For patients to be eligible, they had to present with a diagnosis of CH according to the revised diagnostic criteria [5] developed by the Cervicogenic Headache International Study Group (CHISG) [5, 18, 19]. CH was classified according to the �major criteria� (not including confirmatory evidence by diagnostic anesthetic blockades) and �head pain characteristics� of the CHISG. Therefore, in order to be included in the study, patients had to exhibit all of the following criteria: (1) unilaterality of the head pain without sideshift, starting in the upper posterior neck or occipital region, eventually spreading to the oculofrontotemporal area on the symptomatic side, (2) pain triggered by neck movement and/or sustained awkward positions, (3) reduced range of motion in the cervical spine [20] (i.e., less than or equal to 32 � of right or left passive rotation on the Flexion-Rotation Test [21�23], (4) pain elicited by external pressure over at least one of the upper cervical joints (C0-3), and (5) moderate to severe, non-throbbing and non-lancinating pain. In addition, participants had to have a headache frequency of at least 1 per week for a minimum of 3 months, a minimum headache intensity pain score of two points (0�10 on the NPRS scale), a minimum disability score of 20 % or greater (i.e., 10 points or greater on the 0�50 NDI scale), and be between 18 and 65 years of age.
Patients were excluded if they exhibited other primary headaches (i.e., migraine, TTH), suffered from bilateral headaches, or exhibited any red flags (i.e., tumor, fracture, metabolic diseases, rheumatoid arthritis, osteoporosis, resting blood pressure greater than 140/90 mmHg, prolonged history of steroid use, etc.), presented with two or more positive neurologic signs consistent with nerve root compression (muscle weakness involving a major muscle group of the upper extremity, diminished upper extremity deep tendon reflex, or diminished or absent sensation to pinprick in any upper extremity dermatome), presented with a diagnosis of cervical spinal stenosis, exhibited bilateral upper extremity symptoms, had evidence of central nervous system involvement (hyperreflexia, sensory disturbances in the hand, intrinsic muscle wasting of the hands, unsteadiness during walking, nystagmus, loss of visual acuity, impaired sensation of the face, altered taste, the presence of pathological reflexes), had a history of whiplash injury within the previous 6 weeks, had prior surgery to the head or neck, had received treatment for head or neck pain from any practitioner within the previous month, had received physical therapy or chiropractic treatment for head or neck pain within the previous 3 months, or had pending legal action regarding their head or neck pain.
The most recent literature suggests that pre-manipulative cervical artery testing is unable to identify those individuals at risk of vascular complications from cervical manipulation [24, 25], and any symptoms detected during pre-manipulative testing may be unrelated to changes in blood flow in the vertebral artery [26, 27]. Hence, pre-manipulative cervical artery testing was not performed in this study; however, screening questions for cervical artery disease had to be negative [24, 28, 29]. This study was approved by the Institutional Review Board at Long Island University, Brooklyn, NY. The study was registered at www.clinicaltrials.gov with trial identifier NCT01580280. All patients were informed that they would receive either manipulation or mobilization and exercise and then provided informed consent before their enrollment in the study.
Treating Therapists
Twelve physical therapists (mean age 36.6 years, SD 5.62) participated in the delivery of treatment for patients in this study. They had an average of 10.3 (SD 5.66, range 3�20 years) years of clinical experience, and all had completed a 60 h post-graduate certification program that included practical training in manual techniques including the use of cervical and thoracic manipulation. To ensure all examination, outcome assessments, and treatment procedures were standardized, all participating physical therapists were required to study a manual of standard operating procedures and participate in a 4 h training session with the principal investigator.
Examination Procedures
All patients provided demographic information, completed the Neck Pain Medical Screening Questionnaire, and completed a number of self-report measures, followed by a standardized history and physical examination at baseline. Self-report measures included headache intensity as measured by the NPRS (0�10), the NDI (0�50), headache frequency (number of days with headache in the last week), headache duration (total hours of headache in the last week), and medication intake (number of times the patient had taken narcotic or over-the-counter pain medication in the past week).
The standardized physical examination was not limited to, but included measurements of C1-2 (atlanto-axial joint) passive right and left rotation ROM using the Flexion-Rotation Test (FRT). The inter-rater reliability for the FRT has been found to be excellent (ICC: 0.93; 95 % CI: 0.87, 0.96) [30].
Outcome Measures
The primary outcome measure used in this study was the patient�s headache intensity as measured by the NPRS. Patients were asked to indicate the average intensity of headache pain over the past week using an 11-point scale ranging from 0 (�no pain�) to 10 (�worst pain imaginable�) at baseline, 1-week, 1-month, and 3-months following the initial treatment session [31]. The NPRS is a reliable and valid instrument to assess pain intensity [32�34]. Although no data exists in patients with CH, the MCID for the NPRS has been shown to be 1.3 in patients with mechanical neck pain [32] and 1.74 in patients with a variety of chronic pain conditions [34]. Therefore, we chose to only include patients with an NPRS score of 2 points (20 %) or greater.
Secondary outcome measures included the NDI, the Global Rating of Change (GRC), headache frequency, headache duration, and medication intake. The NDI is the most widely used instrument for assessing self-rated disability in patients with neck pain [35�37]. The NDI is a self-report questionnaire with 10-items rated from 0 (no disability) to five (complete disability) [38]. The numeric responses for each item are summed for a total score ranging between 0 and 50; however, some evaluators have chosen to multiply the raw score by two, and then report the NDI on a 0�100 % scale [36, 39]. Higher scores represent increased levels of disability. The NDI has been found to possess excellent test-retest reliability, strong construct validity, strong internal consistency and good responsiveness in assessing disability in patients with mechanical neck pain [36], cervical radiculopathy [33, 40], whiplash associated disorder [38, 41, 42], and mixed non-specific neck pain [43, 44]. Although no studies have examined the psychometric properties of the NDI in patients with CH, we chose to only include patients with an NDI score of ten points (20 %) or greater, because this cut-off score captures the MCID for the NDI, which has been reported to approximate four, eight, and nine points (0�50) in patients with mixed non-specific neck pain [44], mechanical neck pain [45], and cervical radiculopathy [33], respectively. Headache frequency was measured as the number of days with headache in the last week, ranging from 0 to 7 days. Headache duration was measured as the total hours of headache in the last week, with six possible ranges: (1) 0�5 h, (2) 6�10 h, (3) 11�15 h, (4) 16�20 h, (5) 21�25 h, or (6) 26 or more hours. Medication intake was measured as the number of times the patient had taken prescription or over-the-counter analgesic or anti-inflammatory medication in the past week for their headaches, with five options: (1) not at all, (2) once a week, (3) once every couple of days, (4) once or twice a day, or (5) three or more times a day.
Patients returned for 1-week, 4-weeks, and 3-months follow-ups where the aforementioned outcome measures were again collected. In addition, at the 1-week, 4-weeks and 3-months follow-ups, patients completed a 15-point GRC question based on a scale described by Jaeschke et al. [46] to rate their own perception of improved function. The scale ranges from -7 (a very great deal worse) to zero (about the same) to +7 (a very great deal better). Intermittent descriptors of worsening or improving are assigned values from -1 to -6 and +1 to +6, respectively. The MCID for the GRC has not been specifically reported but scores of +4 and +5 have typically been indicative of moderate changes in patient status [46]. However, it should be noted that recently Schmitt and Abbott reported that the GRC might not correlate with changes in function in a population with hip and ankle injuries [47]. All outcome measures were collected by an assessor blind to group assignment.
On the initial visit patients completed all outcome measures then received the first treatment session. Patients completed 6�8 treatment sessions of either manipulation or mobilization combined with exercise over 4 weeks. Additionally, subjects were asked if they had experienced any �major� adverse events [48, 49] (stroke or permanent neurological deficits) at each follow-up period.
Randomization
Following the baseline examination, patients were randomly assigned to receive either manipulation or mobilization and exercise. Concealed allocation was performed by using a computer-generated randomized table of numbers created by an individual not involved with recruiting patients prior to the beginning of the study. Individual, sequentially numbered index cards with the random assignment were prepared for each of 8 data collection sites. The index cards were folded and placed in sealed opaque envelopes. Blinded to the baseline examination, the treating therapist opened the envelope and proceeded with treatment according to the group assignment. Patients were instructed not to discuss the particular treatment procedure received with the examining therapist. The examining therapist remained blind to the patient�s treatment group assignment at all times; however, based on the nature of the interventions it was not possible to blind patients or treating therapists.
Manipulation Group
Manipulations targeting the right and left C1-2 articulations and bilateral T1-2 articulations were performed on at least one of the 6�8 treatment sessions (Figs. 1 and ?and2).2). On other treatment sessions, therapists either repeated the C1-2 and/or T1-2 manipulations or targeted other spinal articulations (i.e., C0-1, C2-3, C3-7, T2-9, ribs 1�9) using manipulation. The selection of the spinal segments to target was left to the discretion of the treating therapist and it was based on the combination of patient reports and manual examination. For both the upper cervical and upper thoracic manipulations, if no popping or cracking sound was heard on the first attempt, the therapist repositioned the patient and performed a second manipulation. A maximum of 2 attempts were performed on each patient similar to other studies [14, 50�53]. The clinicians were instructed that the manipulations are likely to be accompanied by multiple audible popping sounds [54�58]. Patients were encouraged to maintain usual activity within the limits of pain; however, mobilization and the prescription of exercises, or any use of other modalities, were not provided to this group.
The manipulation targeting C1-2 was performed with the patient in supine. For this technique, the patient�s left posterior arch of the atlas was contacted with the lateral aspect of the proximal phalanx of the therapist�s left second finger using a �cradle hold�. To localize the forces to the left C1-2 articulation, the patient was positioned using extension, a posterior-anterior (PA) shift, ipsilateral side-bend and contralateral side-shift. While maintaining this position, the therapist performed a single high-velocity, low-amplitude thrust manipulation to the left atlanto-axial joint using right rotation in an arc toward the underside eye and translation toward the table (Fig. 1). This was repeated using the same procedure but directed to the right C1-2 articulation.
The manipulation targeting T1-2 was performed with the patient in supine. For this technique, the patient held her/his arms and forearms across the chest with the elbows aligned in a superoinferior direction. The therapist contacted the transverse processes of the lower vertebrae of the target motion segment with the thenar eminence and middle phalanx of the third digit. The upper lever was localized to the target motion segment by adding rotation away and side-bend towards the therapist while the underside hand used pronation and radial deviation to achieve rotation toward and side-bend away moments, respectively. The space inferior to the xiphoid process and costochondral margin of the therapist was used as the contact point against the patient�s elbows to deliver a manipulation in an anterior to posterior direction targeting T1-2 bilaterally (Fig. 2).
Mobilization and Exercise Group
Mobilizations targeting the right and left C1-2 articulations and bilateral T1-2 articulations were performed on at least one of the 6�8 treatment sessions. On other treatment sessions, therapists either repeated the C1-2 and/or T1-2 mobilizations or targeted other spinal articulations (i.e., C0-1, C2/3, C3-7, T2-9, ribs 1�9) using mobilization. The selection of the spinal segments to target was left to the discretion of the treating therapist and it was based on the combination of patient reports and manual examination. However, in order to avoid a �contact� or �attention effect� when compared with the manipulation group, therapists were instructed to mobilize one cervical segment (i.e., right and left) and one thoracic segment or rib articulation on each treatment session.
The mobilization targeting the C1-2 articulation was performed in prone. For this technique, the therapist performed one 30 s bout of left-sided unilateral grade IV PA mobilizations to the C1-2 motion segment as described by Maitland [7]. This same procedure was repeated for one 30 s bout to the right atlanto-axial joint. In addition, and on at least one session, mobilization directed to the upper thoracic (T1-2) spine with the patient prone was performed. For this technique, the therapist performed one 30 s bout of central grade IV PA mobilizations to the T1-2 motion segment as described by Maitland [7]. Therefore, we used 180 (i.e., three 30 s bouts at approximately 2 Hz) end-range oscillations in total on each subject for the mobilization treatment. Notably, there is no high quality evidence to date to suggest that longer durations of mobilization result in greater pain reduction than shorter durations or dosages of mobilization [59, 60].
Cranio-cervical flexion exercises [11, 61�63] were performed with the patient in supine, with the knees bent and the position of the head standardized by placing the craniocervical and cervical spines in a mid-position, such that a line between the subject�s forehead and chin was horizontal, and a horizontal line from the tragus of the ear bisected the neck longitudinally. An air-filled pressure biofeedback unit (Chattanooga Group, Inc., Hixson, TN) was placed suboccipitally behind the patient�s neck and preinflated to a baseline of 20 mmHg [63]. For the staged exercises, patients were required to perform the craniocervical flexion action (�a nod of the head, similar to indicating yes�) [63] and attempt to visually target pressures of 22, 24, 26, 28, and 30 mmHg from a resting baseline of 20 mmHg and to hold the position steady for 10 s [61, 62]. The action of nodding was performed in a gentle and slow manner. A 10 s rest was allowed between trials. If the pressure deviated below the target pressure, the pressure was not held steady, substitution with the superficial flexors (sternocleidomastoid or anterior scalene) occurred, or neck retraction was noticed before the completion of the 10 s isometric hold, it was regarded as a failure [63]. The last successful target pressure was used to determine each patient�s exercise level wherein 3 sets of 10 repetitions with a 10 s isometric hold were performed. In addition to mobilizations and cranio-cervical flexion exercises, patients were required to perform 10 min of progressive resistance exercises (i.e., using Therabands� or free weights) to the muscles of the shoulder girdle during each treatment session, within their own tolerance, and specifically focusing on the lower trapezius and serratus anterior [11].
Sample Size
The sample size and power calculations were performed using online software from the MGH Biostatistics Center (Boston, MA). The calculations were based on detecting a 2-point (or 20 %) difference in the NPRS (headache intensity) at the 3 months follow-up, assuming a standard deviation of three points, a 2-tailed test, and an alpha level equal to 0.05. This generated a sample size of 49 patients per group. Allowing for a conservative dropout rate of 10 %, we planned to recruit at least 108 patients into the study. This sample size yielded greater than 90 % power to detect a statistically significant change in the NPRS scores.
Data Analysis
Descriptive statistics, including frequency counts for categorical variables and measures of central tendency and dispersion for continuous variables were calculated to summarize the data. The effects of treatment on headache intensity and disability were each examined with a 2-by-4 mixed-model analysis of variance (ANOVA), with treatment group (manipulation versus mobilization and exercise) as the between-subjects variable and time (baseline, 1 week, 4 weeks, and 3 months follow-up) as the within-subjects variable. Separate ANOVAs were performed with the NPRS (headache intensity) and NDI (disability) as the dependent variable. For each ANOVA, the hypothesis of interest was the 2-way interaction (group by time).
An independent t-test was used to determine the between group differences for the percentage change from baseline to 3-month follow-up in both headache intensity and disability. Separate Mann�Whitney U tests were performed with the headache frequency, GRC, headache duration and medication intake as the dependent variable. We performed Little�s Missing Completely at Random (MCAR) test [64] to determine if missing data points associated with dropouts were missing at random or missing for systematic reasons. Intention-to-treat analysis was performed by using Expectation-Maximization whereby missing data are computed using regression equations. Planned pairwise comparisons were performed examining the difference between baseline and follow-up periods between-groups using the Bonferroni correction at an alpha level of .05.
We dichotomized patients as responders at the 3-month follow-up using a cut score of 2 points improvement for headache intensity as measured by the NPRS. Numbers needed to treat (NNT) and 95 % confidence intervals (CI) were also calculated at the 3 months follow-up period using each of these definitions for a successful outcome. Data analysis was performed using SPSS 21.0.
Results
Two hundred and fifty-one patients with a primary complaint of headaches were screened for possible eligibility. The reasons for ineligibility can be found in Fig. 3, the flow diagram of patient recruitment and retention. Of the 251 patients screened, 110 patients, with a mean age of 35.16 years (SD 11.48) and a mean duration of symptoms of 4.56 years (SD 6.27), satisfied the eligibility criteria, agreed to participate, and were randomized into manipulation (n?=?58) and mobilization and exercise (n?=?52) groups. Baseline variables for each group can be found in Table 1. Twelve therapists from 8 outpatient physical therapy clinics each treated 25, 23, 20, 14, 13, 7, 6 or 2 patients, respectively; furthermore, each of the 12 therapists treated approximately an equal proportion of patients in each group. There was no significant difference (p?=?0.227) between the mean number of completed treatment sessions for the manipulation group (7.17, SD 0.96) and the mobilization and exercise group (6.90, SD 1.35). In addition, the mean number of treatment sessions that targeted the C1-2 articulation was 6.41 (SD 1.63) for the manipulation group and 6.52 (SD 2.01) for the mobilization and exercise group, and this was not significantly different (p?=?0.762). One hundred seven of the 110 patients completed all outcome measures through 3 months (97 % follow-up). Little�s Missing Completely at Random (MCAR) test was not statistically significant (p?=?0.281); therefore, we used the Expectation-Maximization imputation technique to replace missing values with predicted values for the missing 3-month outcomes.
The overall group by time interaction for the primary outcome of headache intensity was statistically significant for the NPRS (F(3,106)?=?11.196; p?<?0.001; partial eta squared?=?0.24). Between-group differences revealed that the manipulation group experienced statistically significant greater improvement in the NPRS at both the 1-week (2.1, 95 % CI: 1.2, 2.9), 4-week (2.3, 95 % CI: 1.5, 3.1) and 3-month (2.1, 95 % CI: 1.2, 3.0) follow-up periods (Table 2). In addition, an independent samples t-test revealed the between-group difference in percentage change in headache intensity (36.58 %, 95 % CI: 22.52, 50.64) from baseline to 3-month follow-up was statistically significant (t(108)?=?5.156; p?<?0.001) in favor of manipulation. See Table 3 for the percentage of subjects gaining 50, 75, and 100 % reduction in headache intensity at 3 months.
For secondary outcomes a significant group by time interaction existed for the NDI (F(3,106)?=?8.57; p?<?0.001; partial eta squared?=?0.20). At each follow-up period the manipulation group had superior outcomes in disability reduction as compared to the mobilization and exercise group. An independent samples t- test revealed the between-group mean percentage change in disability (35.56 %, 95 % CI: 24.95, 46.17) from baseline to 3 months follow-up was statistically significant (t(108)?=?6.646, p?<?0.001); indicating the manipulation group experienced a significantly greater percentage in disability reduction (Table 3).
Mann�Whitney U tests revealed that patients in the upper cervical and upper thoracic manipulation group experienced less frequent headaches at 1 week (p?<?0.001; median 2.0 versus 3.0), 4 weeks (p?<?0.001; median 1.0 versus 3.0) and 3 months (p?<?0.001; median 1.0 versus 2.5) than patients in the mobilization and exercise group. Headache duration was significantly lower at 1 week (p?=?0.005; median 2.0 versus 3.0, 4 weeks (p?<?0.001; median 1.0 versus 2.0) and 3 months (p?<?0.001; median 1.0 versus 2.0) in the manipulation group. Additionally, patient perceived improvement as measured by the GRC was significantly greater at 1 week (p?<?0.001, 4.0 versus 1.0), 4 weeks (p?<?0.001, 6.0 versus 3.0) and 3 months (p?<?0.001, 6.0 versus 3.0) than patients in the mobilization and exercise group. At 3 months, patients receiving upper cervical and upper thoracic manipulation experienced significantly (p?<?0.001) greater reductions in medication intake as compared to the mobilization and exercise group. Based on the cutoff score of 2 points on the NPRS, the NNT was 4.0 (95 % CI: 2.3, 7.7) in favor of the manipulation group at 3-month follow-up.
We did not collect any data on the occurrence of �minor� adverse events [48, 49] (transient neurological symptoms, increased stiffness, radiating pain, fatigue or other); however, no �major� adverse events [48, 49] (stroke or permanent neurological deficits) were reported for either group.
Discussion
Statement of Principal Findings
To our knowledge, this study is the first randomized clinical trial to directly compare the effectiveness of both cervical and thoracic manipulation to mobilization and exercise in patients with CH. The results suggest 6�8 sessions of manipulation over 4 weeks, directed mainly to both the upper cervical (C1-2) and upper thoracic (T1-2) spines, resulted in greater improvements in headache intensity, disability, headache frequency, headache duration, and medication intake than mobilization combined with exercises. The point estimates for between-group changes in headache intensity (2.1 points) and disability (6.0 points or 12.0 %) exceeded the reported MCIDs for both measures. Although the MCID for the NDI in patients with CH has not yet been investigated, it should however be noted that the lower bound estimate of the 95 % CI for disability (3.5 points) was slightly below (or approximated in two cases) the MCID that has been found to be 3.5 [65], 5 [66], and 7.5 [45] points in patients with mechanical neck pain, 8.5 [33] points in patients with cervical radiculopathy, and 3.5 [44] points in patients with mixed, non-specific neck pain. However, it should be recognized that both groups made clinical improvement. In addition, the NNT suggests for every four patients treated with manipulation, rather than mobilization, one additional patient achieves clinically important pain reduction at 3 months follow-up.
Strengths and Weaknesses of the Study
The inclusion of 12 treating physical therapists from 8 private clinics in 6 different geographical states enhances the overall generalizability of our findings. Although significant differences were recognized up to 3 months, it is not known if these benefits would have been sustained at long-term. In addition, we used high-velocity, low-amplitude manipulation techniques that employed bidirectional thrusts into rotation and translation simultaneously and Maitland based grade IV PA mobilization techniques; thus, we cannot be certain that these results are generalizable to other kinds of manual therapy techniques. Some might argue that the comparison group might have not received adequate intervention. We sought to balance internal and external validity so standardized treatment for both groups and provided a very explicit description of the techniques used which will also allow for replication. Furthermore, we did not measure minor adverse events and only asked about two potential major adverse events. Another limitation is that we included multiple secondary outcomes. Therapist preferences as to which technique they thought would be superior was not collected and potentially could impact the results.
Strengths and Weaknesses in Relation to Other Studies: Important Differences in Results
Jull et al. [11] demonstrated treatment efficacy for manipulative therapy and exercise in the management of CH; however, this treatment package included both mobilization and manipulation. The current study may provide evidence that the management of patients with CH should include some form of manipulation despite the fact it is often suggested that cervical manipulation should be avoided because of the risk of serious adverse events [67, 68]. Furthermore, it has been shown that individuals receiving spinal manipulation for neck pain and headaches are no more likely to experience a vertebrobasilar stroke than if they received treatment by their medical physician [69]. Additionally, after reviewing 134 case reports, Puentedura et al. concluded that with appropriate selection of patients by careful screening of red flags and contraindications, the majority of adverse events associated with cervical manipulation could have been prevented [70].
Meaning of the Study: Possible Explanations and Implications for Clinicians and Policymakers
Based on the results of the current study clinicians should consider incorporating spinal manipulation for individuals with CH. A recent systematic review found both mobilization and manipulation to be effective for the management of patients with CH but was unable to determine which technique was superior [8]. Additionally, clinical guidelines reported that manipulation, mobilization and exercise were all effective for the management of patients with CH; however, the guideline made no suggestions regarding the superiority of either technique. [71] The current results may assist authors of future systematic reviews and clinical guidelines in providing more specific recommendations about the use of spinal manipulation in this population.
Unanswered Questions and Future Research
The underlying mechanisms as to why manipulation may have resulted in greater improvements remains to be elucidated. It has been suggested that high-velocity displacement of vertebrae with impulse durations of less than 200 ms may alter afferent discharge rates [72] by stimulating mechanoreceptors and proprioceptors, thereby changing alpha motorneuron excitability levels and subsequent muscle activity [72�74]. Manipulation might also stimulate receptors in the deep paraspinal musculature, and mobilization might be more likely to facilitate receptors in the superficial muscles [75]. Biomechanical [76, 77], spinal or segmental [78, 79] and central descending inhibitory pain pathway [80�83] models are plausible explanations for the hypoalgesic effects observed following manipulation. Recently, the biomechanical effects of manipulation have been under scientific scrutiny [84], and it is plausible that the clinical benefits found in our study are associated with a neurophysiological response involving temporal sensory summation at the dorsal horn of the spinal cord [78]; however, this proposed model is currently supported only on findings from transient, experimentally induced pain in healthy subjects [85, 86], not patients with CH. Future studies should examine different manual therapy techniques with varying dosages and include a 1-year follow-up. Furthermore, future studies examining the neurophysiological effects of both manipulation and mobilization will be important for determining why there may or may not be a difference in clinical effects between these two treatments.
Conclusion
The results of the current study demonstrated that patients with CH who received cervical and thoracic manipulation experienced significantly greater reductions in headache intensity, disability, headache frequency, headache duration, and medication intake as compared to the group that received mobilization and exercise; furthermore, the effects were maintained at 3 months follow-up. Future studies should examine the effectiveness of different types and dosages of manipulation and include a long-term follow-up.
Acknowledgements
None of the authors received any funding for this study. The authors wish to thank all the participants of the study.
Footnotes
Competing interests: Dr. James Dunning is the President of the American Academy of Manipulative Therapy (AAMT). AAMT provides postgraduate training programs in spinal manipulation, spinal mobilization, dry needling, extremity manipulation, extremity mobilization, instrument-assisted soft-tissue mobilization and therapeutic exercise to licensed physical therapists, osteopaths and medical doctors. Drs. James Dunning, Raymond Butts, Thomas Perreault, and Firas Mourad are senior instructors for AAMT. The other authors declare that they have no competing interests.
Authors� contributions: JRD participated in the conception, design, data acquisition, statistical analyses and drafting of the manuscript. RB and IY participated in the design, data collection, statistical analyses and revision of the manuscript. FM participated in the design, statistical analyses, data interpretation and revision of the manuscript. MH participated in the conception, design and revision of the manuscript. CF and JC were involved in the statistical analyses, interpretation of data, and critical revision of the manuscript for important intellectual content. TS, JD, DB, and TH were involved in data collection and revision of the manuscript. All authors read and approved the final manuscript.
In conclusion,�head pain caused by secondary headache due to a health issue along the surrounding structures of the cervical spine, or neck, can cause painful and debilitating symptoms which can affect the patient’s quality of life. Spinal manipulation and mobilization can be safely and effectively utilized to help improve cervicogenic headache symptoms. 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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