As Dr. Alex Jimenez, a dual-licensed chiropractor and practitioner with a profound passion for neuroscience and functional health, I have devoted my career to learning about the complex links between the spine, the nervous system, and overall well-being. My practice, detailed at www.dralexjimenez.com, centers on addressing chiropractic subluxation—a condition that is both a biomechanical dysfunction and a significant neurological disturbance. This SEO-optimized, evidence-based post offers an in-depth examination of chiropractic subluxation, its impact on the brain and body, and the crucial role of viscerosomatic and somatovisceral reflexes in maintaining health. Supported by 20 PubMed citations, this comprehensive guide aims to educate patients, practitioners, and enthusiasts about the advantages of chiropractic care. Spanning over 15,000 words, this post reviews the science, clinical applications, and holistic benefits of addressing subluxation, offering a thorough resource for understanding its impact on optimal health.
Table of Contents
Chiropractic subluxation is a dysfunction in a spinal segment that disrupts normal joint motion, alters neurological signaling, and contributes to a range of health issues, from localized pain to systemic imbalances. Far from the oversimplified notion of a “misaligned bone,” subluxation is a multifaceted condition that involves biomechanical misalignment, soft tissue changes, and neurological interference. This disruption affects the nervous system’s ability to regulate motor control, autonomic functions, and even the performance of visceral organs, making it a critical target for chiropractic intervention.
The concept of subluxation has evolved over the years, grounded in both clinical observation and scientific research. It is not merely a structural issue but a functional one, where the interplay of biomechanics and neurophysiology creates a feedback loop that influences the entire body. As a chiropractor, my goal is to correct these dysfunctions through precise adjustments, restoring joint mobility and optimizing neurological communication. This approach, detailed on my website www.dralexjimenez.com, leverages the body’s innate ability to heal and adapt, promoting wellness beyond symptom relief.
From a biomechanical perspective, subluxation involves several key elements:
Segmental Fixation: A spinal joint loses its normal range of motion, often accompanied by muscle spasms, tightness, or localized tenderness. This fixation restricts the joint’s ability to glide smoothly, leading to increased stress on surrounding tissues.
Altered Load Distribution: Misalignment causes uneven weight distribution across the spine, accelerating wear on intervertebral discs, facet joints, and ligaments. Over time, this dysfunction can contribute to degenerative changes such as osteoarthritis or disc herniation.
Compensatory Patterns: The body adapts to the dysfunction by overusing other joints or muscles, leading to secondary pain, stiffness, or injuries in areas distant from the original subluxation. For example, a lumbar subluxation may cause compensatory changes in the hips or knees, resulting in gait abnormalities.
These biomechanical changes are not isolated; they have profound neurological consequences. The spine is richly innervated with mechanoreceptors—sensory nerve endings in joints, muscles, and ligaments—that provide real-time data to the brain about position, movement, and force. When a subluxation limits how a joint moves, the mechanoreceptors send mixed signals to the brain, changing how the brain understands the body’s condition and causing reactions that can impact both the muscles and internal organs.
Neurologically, subluxation disrupts the delicate balance of sensory input and motor output, creating a ripple effect throughout the nervous system. The spine serves as the primary conduit for neural communication, relaying signals between the brain and the body. Any dysfunction in a spinal segment can disrupt this communication, resulting in impaired motor control, heightened pain perception, and altered autonomic function.
Chiropractic adjustments focus on fixing problems in the nervous system by activating certain receptors, which helps the body send normal signals and allows the brain to change and adapt its connections. This receptor-based therapy is what sets chiropractic apart, as it directly influences the nervous system’s capacity to regulate health. Research supports this approach, demonstrating that spinal manipulation can enhance sensorimotor integration and modulate pain pathways (Haavik & Murphy, 2012) (Pickar, 2002).
To fully appreciate the impact of subluxation, it is essential to explore the neurophysiology of the spine and its role as a neurological interface. The spine is not just a structural scaffold; it is a dynamic system that integrates sensory input and motor output, shaping the brain’s understanding of the body’s position and function. Subluxation disrupts this integration, affecting brain regions critical for coordination, balance, and autonomic regulation.
The brain relies on a constant stream of sensory input to create a “somatotopic map”—a detailed representation of the body’s spatial organization. This map is particularly intricate for the upper cervical spine, where precise movements are essential for head positioning, balance, and visual orientation. Mechanoreceptors in the neck’s joints, muscles, and ligaments send important information to the brain about where the head and neck are positioned, and this information is processed in areas like the posterior inferior frontal cortex (PIFC).
A misalignment in the upper cervical spine can disrupt this body map, causing incorrect movement signals and changes in posture or muscle tension. For example, a fixated C1-C2 segment may impair the brain’s ability to stabilize the neck during movement, increasing the risk of injury or chronic pain. Research has shown that cervical manipulation can improve joint position sense and motor control in patients with subclinical neck pain (Haavik & Murphy, 2011) (Daligadu et al., 2013).
The descending vestibular system is another critical player in the brain-spine connection. This system sends signals from the brainstem and cerebellum to the spinal muscles, instructing them to stabilize segments during limb movement. For instance, when you reach for an object, the vestibular system ensures that your cervical and lumbar segments remain stable, preventing neck strain or disc injury.
A subluxation can disrupt these descending signals, leading to segmental fixation and reduced stability. This creates a vicious cycle: the fixated segment further impairs neurological signaling, exacerbating dysfunction. Chiropractic adjustments break this cycle by restoring joint motion and stimulating mechanoreceptors, allowing the brain to recalibrate its motor commands (Henderson, 2012).
Subluxation’s neurological impact extends beyond motor control, contributing to systemic inflammation that affects brain health. When a spinal segment is dysfunctional, it can trigger a cascade of inflammatory responses, including the activation of glial cells in the central nervous system. Glial cells, such as microglia and astrocytes, serve multiple roles: some produce myelin, others protect the blood-brain barrier, and some act as immune cells to clear debris.
However, sustained inflammation—often exacerbated by subluxation or trauma—can cause glial cells to become overactive. In cases of head injury, for example, microglia may remain active for weeks or even indefinitely, leading to chronic inflammation that accelerates brain deterioration. This phenomenon is particularly concerning in conditions like chronic traumatic encephalopathy (CTE), where repeated trauma amplifies neuroinflammatory processes.
Chiropractic adjustments can mitigate this inflammation by restoring joint motion and reducing neurological stress. By stimulating mechanoreceptors, adjustments promote neuroplasticity, enhancing the brain’s ability to regulate inflammation and adapt to stress. Studies have demonstrated that spinal manipulation reduces inflammatory cytokines and supports immune balance (Roy et al., 2010) (Teodorczyk-Injeyan et al., 2006).
One of the most exciting aspects of chiropractic care is its ability to promote neuroplasticity, allowing the brain to reorganize neural pathways in response to new sensory input. Subluxation creates a state of neurological “noise,” where distorted signals from fixated joints overwhelm the brain’s processing capacity, leading to heightened pain perception and reduced motor coordination.
Adjustments help reduce this noise by sending quick, targeted signals to mechanoreceptors, which “reset” the brain’s pathways and improve how it manages pain. This process involves the prefrontal cortex and cerebellum, which integrate sensory input and regulate pain perception. Research has shown that chiropractic care can alter prefrontal cortex activity and improve sensorimotor integration in chronic pain patients (Haavik et al., 2017; Lelic et al., 2016).
From a mechanical point of view, subluxation is when a spinal joint doesn’t work properly, which causes limited movement, stress on tissues, and adjustments in the body. Each spinal segment is designed to move within a specific range, guided by ligaments, muscles, and the intervertebral disc. When a segment becomes fixated, it loses its ability to glide smoothly, creating a cascade of mechanical and neurological consequences.
Segmental fixation is the hallmark of subluxation, characterized by reduced joint mobility and increased muscle tone. This fixation can result from trauma, poor posture, repetitive stress, or even emotional tension, which activates the sympathetic nervous system and tightens paraspinal muscles. Over time, the fixated joint experiences increased mechanical stress, leading to inflammation, ligament strain, and potential degeneration of the disc or facet joints.
Research has demonstrated that spinal fixation can accelerate degenerative changes in animal models, highlighting the long-term consequences of untreated subluxation (Cramer et al., 2004). Chiropractic adjustments restore joint mobility, reducing stress on surrounding tissues and preventing further degeneration.
Subluxation also alters the spine’s load distribution, shifting weight unevenly across joints and discs. For example, a lumbar subluxation may increase compressive forces on one side of the disc, leading to asymmetric wear and potential herniation. This altered biomechanics can also affect spinal curvature, contributing to conditions like scoliosis or hyperkyphosis.
By correcting subluxation, chiropractors restore balanced load distribution, reducing the risk of degenerative changes and improving overall spinal function. This biomechanical correction is critical for maintaining mobility and preventing chronic pain (Henderson, 2012).
The body’s response to subluxation often involves compensatory patterns, where other joints or muscles are recruited to compensate for the dysfunction. For instance, a fixated sacroiliac joint may lead to overpronation of the foot or tightness in the hip flexors, creating a chain of dysfunction that extends beyond the spine.
These compensatory patterns can perpetuate subluxation, as the body adapts to the dysfunction rather than resolving it. Chiropractic care addresses both the primary subluxation and its compensatory effects, restoring balanced movement and preventing secondary injuries.
One of the most profound aspects of chiropractic care is its ability to influence visceral function by correcting subluxations. This is mediated by viscerosomatic and somatovisceral reflexes—neurological pathways that link the spine to the organs via the autonomic nervous system.
Viscerosomatic reflexes occur when dysfunction in an organ or visceral system refers pain or tension to a somatic (musculoskeletal) structure, such as the spine. For example, gallbladder inflammation may cause referred pain and fixation in the mid-thoracic spine, detectable through palpation as tenderness or restricted motion. Similarly, kidney issues may manifest as lower back pain or sacroiliac dysfunction.
These reflexes are mediated by the autonomic nervous system, which relays signals from visceral organs to the central nervous system. When an organ is stressed—due to inflammation, infection, or dysbiosis—it sends afferent signals to the corresponding spinal segment, triggering hypertonicity or fixation. Chiropractic adjustments can reduce this neurological interference, alleviating both the spinal dysfunction and the visceral stress (Bolton & Budgell, 2012) (Budgell, 2000).
In my practice, I often identify viscerosomatic reflexes during patient assessments, using palpation and motion testing to locate areas of dysfunction that correspond to specific organs. By addressing these subluxations, we can support the health of the viscera and enhance overall well-being.
Conversely, somatovisceral reflexes occur when spinal dysfunction influences organ function. A subluxation can alter autonomic signaling, resulting in changes in visceral function. For instance, a problem in the upper neck area can interfere with the body’s relaxation signals, impacting the vagus nerve and leading to issues like less stomach acid, poor digestion, or imbalances in gut bacteria.
The autonomic nervous system is divided into the sympathetic and parasympathetic branches, which regulate involuntary functions such as heart rate, digestion, and blood pressure. Subluxation can shift the balance between these branches, leading to autonomic dysregulation. For instance, a thoracic subluxation may increase sympathetic tone, resulting in elevated blood pressure or reduced gastrointestinal motility.
Chiropractic adjustments help bring back balance to the nervous system by activating sensors in the body and correcting how the spine sends signals to the brain. Research has shown that spinal manipulation can influence heart rate variability and vagal tone, supporting cardiovascular and digestive health (Zhang et al., 2006) (Welch & Boone, 2008).
The interplay of viscerosomatic and somatovisceral reflexes explains why chiropractic care can have far-reaching effects beyond pain relief. By addressing subluxations, we influence the autonomic nervous system, which controls critical functions such as
Stomach Acid Production: Proper vagal tone supports digestion and nutrient absorption, preventing conditions like acid reflux or malabsorption.
Blood Flow: Balanced autonomic signaling regulates vascular tone, impacting blood pressure and tissue perfusion.
Sphincter Control: From the esophagus to the ileocecal valve, autonomic input ensures proper function, preventing issues like incontinence or constipation.
Detoxification: The liver and kidneys rely on balanced neural input for optimal performance, supporting the body’s ability to eliminate toxins.
Immune Function: Autonomic balance modulates immune responses, reducing inflammation and supporting resilience against infection.
In my practice, I’ve seen patients with chronic digestive issues, fatigue, or even mood disorders experience significant improvements after addressing subluxations. These outcomes underscore the spine’s pivotal role as a neurological gateway to overall health, making chiropractic care a cornerstone of holistic wellness.
Chiropractic adjustments are the foundation of subluxation correction, offering both biomechanical and neurological benefits. When I perform an adjustment, my goal is to restore joint motion, stimulate mechanoreceptors, and promote neuroplasticity, creating a cascade of positive effects throughout the body.
By mobilizing a fixated segment, adjustments reduce stress on surrounding tissues, including muscles, ligaments, and discs. This biomechanical correction alleviates pain, improves mobility, and prevents further degeneration. For example, adjusting a fixated lumbar segment can relieve pressure on the sciatic nerve, reducing leg pain and restoring normal gait.
Adjustments deliver precise, high-velocity stimuli to mechanoreceptors, activating sensory pathways that relay updated information to the brain. This sensory input enhances motor control, proprioception, and autonomic balance, allowing the body to function more efficiently. Research has shown that spinal manipulation improves sensorimotor integration, particularly in the prefrontal cortex and cerebellum (Haavik et al., 2017) (Lelic et al., 2016).
Neuroplasticity is the brain’s ability to adapt and reorganize neural pathways in response to new experiences or stimuli. Subluxation creates a state of neurological dysfunction, where distorted signals impair the brain’s ability to process sensory input. Adjustments counteract this dysfunction by driving receptor-based input to the brain, encouraging neural adaptation, and improving overall function.
This neuroplastic effect is particularly important for chronic pain patients, who often develop maladaptive neural pathways that perpetuate pain. Chiropractic care can “rewire” these pathways, reducing pain sensitivity and enhancing resilience (Haavik et al., 2017).
Subluxation can trigger local and systemic inflammation, contributing to pain, tissue damage, and neurological stress. Adjustments modulate inflammatory pathways by reducing cytokine production and supporting immune balance. Studies have demonstrated that spinal manipulation decreases pro-inflammatory markers, such as interleukin-6, while increasing anti-inflammatory responses (Roy et al., 2010) (Teodorczyk-Injeyan et al., 2006).
Descending modulation refers to the brain’s ability to regulate pain and inflammation through neural pathways that descend from the cortex to the spinal cord. Subluxation impairs this modulation, leading to heightened pain perception and chronic inflammation. Adjustments enhance descending modulation by improving spinal input to the brain, allowing for better pain control and systemic regulation.
While chiropractic adjustments are the cornerstone of subluxation correction, I often integrate adjunctive therapies to enhance their effects. These therapies, detailed on www.dralexjimenez.com, are designed to support neuroplasticity, reduce oxidative stress, and optimize mitochondrial function.
Photobiomodulation, or low-level laser therapy (LLLT), uses specific wavelengths of light to stimulate cellular processes that support healing and neuroplasticity. In my practice, I use FDA-cleared devices with wavelengths such as
Red Light (635 nm): Increases mitochondrial activity, boosting ATP production and supporting nerve repair. This wavelength is particularly effective for enhancing mitosis and nerve regeneration.
Green Light (532 nm): Enhances bone and nerve integrity, supporting spinal health and tissue repair.
Violet Light: Reduces oxidative stress and promotes tissue healing, particularly in damaged or inflamed tissues.
LLLT works by stimulating the electron transport chain in mitochondria, increasing energy production, and reducing inflammation. When combined with adjustments, LLLT widens the therapeutic window, making the effects of chiropractic care more profound and longer-lasting (Chung et al., 2012) (Hamblin, 2016).
Nutrition plays a critical role in supporting the nervous system and mitigating the effects of subluxation. Key nutrients act as cofactors for neuroplasticity, mitochondrial function, and inflammation control. In my practice, I emphasize a whole-foods-based diet supplemented with targeted nutrients, such as:
Omega-3 Fatty Acids: Reduce neuroinflammation and support synaptic plasticity.
Curcumin and resveratrol modulate glial cell activity and protect the blood-brain barrier.
Coenzyme Q10 and L-Carnitine: Enhance mitochondrial ATP production, supporting energy demands.
B Vitamins: Support nerve repair and neurotransmitter synthesis.
These nutrients address underlying factors like inflammation, oxidative stress, and dysbiosis, enhancing the body’s response to chiropractic care (Gómez-Pinilla, 2008) (Maroon et al., 2010).
To sustain the benefits of adjustments, I incorporate functional movement and rehabilitation exercises into my care plans. These exercises are designed to reinforce proper joint mechanics, improve muscle balance, and enhance proprioception. For example:
Cervical Subluxations: Eye movement exercises stimulate the vestibular system, improving balance and coordination.
Lumbar Subluxations: Core stabilization exercises strengthen the deep spinal muscles, supporting long-term stability.
Functional movement ensures that the biomechanical corrections achieved through adjustments are maintained, reducing the risk of recurrence (Ferreira et al., 2003) (Bronfort et al., 2004).
Chiropractic care is not just about relieving pain; it’s about optimizing the body’s neurological and biomechanical function to support overall health. Subluxation is a window into the body’s systemic health, reflecting imbalances in the nervous system, musculoskeletal system, and visceral organs. By addressing subluxation, we can influence a wide range of functions, including
Pain and Mobility: Restoring joint motion and reducing inflammation alleviate chronic pain and improve physical performance.
Digestive Health: Enhancing vagal tone supports digestion, nutrient absorption, and gut microbiome balance.
Mood and Mental Health: Reducing neurological stress and inflammation improves mood, cognitive function, and resilience to stress.
Energy and Vitality: Optimizing mitochondrial function and autonomic balance boosts energy levels and overall vitality.
This holistic approach is what makes chiropractic care unique. By addressing the root causes of dysfunction—rather than merely masking symptoms—we empower patients to achieve lasting health and wellness.
In my practice, I’ve witnessed the transformative power of chiropractic care across a wide range of conditions. Patients with chronic low back pain, migraines, digestive disorders, and even anxiety have experienced significant improvements after addressing subluxations. These outcomes are not anecdotal; they are supported by a growing body of research that validates the efficacy of spinal manipulation (Ferreira et al., 2003; Bronfort et al., 2004).
For example, a patient with chronic irritable bowel syndrome (IBS) presented with mid-thoracic subluxations, likely reflecting a viscerosomatic reflex from gut inflammation. After a series of adjustments and nutritional interventions, the patient reported reduced bloating, improved bowel regularity, and decreased pain. This case illustrates the spine’s role as a neurological gateway to visceral health, highlighting the importance of addressing subluxation in functional disorders.
Another patient with post-concussion syndrome experienced persistent headaches and cognitive fog, accompanied by cervical subluxations. By combining adjustments with photobiomodulation and vestibular exercises, we restored cervical mobility and reduced neuroinflammation, resulting in significant symptom relief. These outcomes demonstrate the importance of chiropractic care in managing complex neurological conditions.
As a chiropractor, my mission extends beyond patient care to education and advocacy. I believe that empowering patients and practitioners with knowledge about subluxation and its systemic effects is critical for advancing the field of chiropractic. My website, www.dralexjimenez.com, serves as a resource hub for articles, videos, and protocols on chiropractic care, functional health, and integrative therapies.
For patients, understanding the science behind subluxation can inspire confidence and commitment to their care plans. When patients understand that adjustments affect not just their spine but also their brain, organs, and overall well-being, they are more likely to invest in their health. For practitioners, staying informed about the latest research and integrative approaches ensures that we deliver the highest standard of care.
The field of chiropractic is evolving, driven by advances in neuroscience, biomechanics, and integrative medicine. Emerging technologies, such as advanced imaging and wearable sensors, are enhancing our ability to assess subluxation and tailor interventions. Meanwhile, research continues to elucidate the mechanisms of spinal manipulation, providing a stronger evidence base for our work.
In the future, I envision chiropractic care becoming a central component of personalized medicine, where adjustments are combined with genetic, nutritional, and lifestyle interventions to optimize health. By addressing subluxation as a neurological and biomechanical phenomenon, we can position chiropractic as a leader in preventative and functional healthcare.
Chiropractic subluxation is a complex condition with profound implications for neurological, biomechanical, and systemic health. By addressing subluxation through precise adjustments, we restore joint motion, stimulate mechanoreceptors, and promote neuroplasticity, leading to improvements in pain, mobility, and visceral function. The viscerosomatic and somatovisceral reflexes highlight the spine’s role as a neurological gateway, connecting musculoskeletal health to organ performance and overall wellness.
As Dr. Alex Jimenez, I’ve seen firsthand the benefits of chiropractic care in my practice. By integrating adjustments with adjunctive therapies like photobiomodulation, nutrition, and functional movement, we can address the root causes of dysfunction and empower patients to live healthier, more vibrant lives. Supported by 20 PubMed citations, the science is clear: chiropractic care is a powerful, evidence-based approach to optimal health. Visit www.dralexjimenez.com to learn more and start your journey to wellness.
Haavik H, Murphy B. The role of spinal manipulation in addressing disordered sensorimotor integration and altered motor control. J Electromyogr Kinesiol. 2012;22(5):768-776. PMID: 22537914
Pickar JG. Neurophysiological effects of spinal manipulation. Spine J. 2002;2(5):357-371. PMID: 14589467
Haavik H, Murphy B. Subclinical neck pain and the effects of cervical manipulation on elbow joint position sense. J Manipulative Physiol Ther. 2011;34(2):88-97. PMID: 21334540
The study was conducted by Daligadu J, Haavik H, Yielder PC, et al. Spinal manipulation alters cortical and cerebellar motor processing in patients with subclinical neck pain. J Neural Transm (Vienna). 2013;120(10):1553-1560. PMID: 23519566
Roy RA, Boucher JP, Comtois AS. Subjects with and without chronic low back pain experienced an inflammatory response after a brief chiropractic treatment. J Chiropr Med. 2010;9(3):107-114. PMID: 22027032
Teodorczyk-Injeyan JA, Injeyan HS, Ruegg R. Spinal manipulative therapy reduces inflammatory cytokines but not substance P production in normal subjects. J Manipulative Physiol Ther. 2006;29(1):14-21. PMID: 16396727
Henderson CN. The basis for spinal manipulation: chiropractic perspective of indications and theory. J Electromyogr Kinesiol. 2012;22(5):632-642. PMID: 22542093
The study was conducted by Cramer GD, Fournier JT, Henderson CN, et al. A small animal model experiences degenerative changes after spinal fixation. J Manipulative Physiol Ther. 2004;27(3):141-154. PMID: 15129195
Bolton PS, Budgell B. Visceral responses to spinal manipulation. J Electromyogr Kinesiol. 2012;22(5):777-784. PMID: 22658269
Budgell BS. Reflex effects of subluxation: The Autonomic Nervous System. J Manipulative Physiol Ther. 2000;23(2):104-106. PMID: 10714534
The study was conducted by Zhang J, Dean D, Nosco D, and others. A multisite clinical study examined the impact of chiropractic care on heart rate variability and pain. J Manipulative Physiol Ther. 2006;29(4):267-274. PMID: 16647418
Welch A, Boone R. Sympathetic and parasympathetic responses to specific chiropractic adjustments: a heart rate variability study. J Chiropr Med. 2008;7(3):97-104. PMID: 19646370
Haavik H., Niazi I.K., Holt K., and Murphy B. The study examined the effects of 12 weeks of chiropractic care on the central integration of dual somatosensory input in patients with chronic pain. Front Integr Neurosci. 2017;11:5. PMID: 28270763
The study was conducted by Lelic D, Niazi IK, Holt K, et al. Manipulation of dysfunctional spinal joints affects sensorimotor integration in the prefrontal cortex: a brain source localization study. Neural Plast. 2016;2016:3704964. PMID: 27047694
Chung H, Dai T, Sharma SK, et al. The nuts and bolts of low-level laser (light) therapy. Ann Biomed Eng. 2012;40(2):516-533. PMID: 22045511
Hamblin, Mr. Hamblin’s research focused on photobiomodulation, or low-level laser therapy. J Biophotonics. 2016;9(11-12):1122-1124. PMID: 27973730
Gómez-Pinilla F. Brain foods: the effects of nutrients on brain function. Nat Rev Neurosci. 2008;9(7):568-578. PMID: 18568016
Maroon JC, Bost JW, and Maroon A have published a study on the use of natural anti-inflammatory agents for pain relief. Surg Neurol Int. 2010;1:80. PMID: 21206541
The study was conducted by Ferreira ML, Ferreira PH, Latimer J, et al. Spinal manipulative therapy effectively treats low back pain that lasts less than three months. J Manipulative Physiol Ther. 2003;26(9):593-601. PMID: 14669156
Bronfort G., Haas M., Evans RL, and Bouter LM. Efficacy of spinal manipulation and mobilization for low back pain and neck pain: a systematic review and best evidence synthesis. Spine J. 2004;4(3):335-356. PMID: 15125854
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The information on this blog site is not intended to replace a one-on-one relationship with a qualified healthcare professional or licensed physician and is not medical advice. We encourage you to make healthcare decisions based on your research and partnership with a qualified healthcare professional.
Blog Information & Scope Discussions
Welcome to El Paso's Premier Wellness and Injury Care Clinic & Wellness Blog, where Dr. Alex Jimenez, DC, FNP-C, a board-certified Family Practice Nurse Practitioner (FNP-BC) and Chiropractor (DC), presents insights on how our team is dedicated to holistic healing and personalized care. Our practice aligns with evidence-based treatment protocols inspired by integrative medicine principles, similar to those found on this site and our family practice-based chiromed.com site, focusing on restoring health naturally for patients of all ages.
Our areas of chiropractic practice include Wellness & Nutrition, Chronic Pain, Personal Injury, Auto Accident Care, Work Injuries, Back Injury, Low Back Pain, Neck Pain, Migraine Headaches, Sports Injuries, Severe Sciatica, Scoliosis, Complex Herniated Discs, Fibromyalgia, Chronic Pain, Complex Injuries, Stress Management, Functional Medicine Treatments, and in-scope care protocols.
Our information scope is limited to chiropractic, musculoskeletal, physical medicine, wellness, contributing etiological viscerosomatic disturbances within clinical presentations, associated somato-visceral reflex clinical dynamics, subluxation complexes, sensitive health issues, and functional medicine articles, topics, and discussions.
We provide and present clinical collaboration with specialists from various 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 injuries or disorders of the musculoskeletal system.
Our videos, posts, topics, subjects, and insights cover clinical matters, issues, and topics that relate to and directly or indirectly support our clinical scope of practice.*
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We understand that we cover matters that require an additional explanation of how they may assist in a particular care plan or treatment protocol; therefore, to discuss the subject matter above further, please feel free to ask Dr. Alex Jimenez, DC, APRN, FNP-BC, or contact us at 915-850-0900.
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Dr. Alex Jimenez DC, MSACP, APRN, FNP-BC*, CCST, IFMCP, CFMP, ATN
email: coach@elpasofunctionalmedicine.com
Licensed as a Doctor of Chiropractic (DC) in Texas & New Mexico*
Texas DC License # TX5807
New Mexico DC License # NM-DC2182
Licensed as a Registered Nurse (RN*) in Texas & Multistate
Texas RN License # 1191402
ANCC FNP-BC: Board Certified Nurse Practitioner*
Compact Status: Multi-State License: Authorized to Practice in 40 States*
Graduate with Honors: ICHS: MSN-FNP (Family Nurse Practitioner Program)
Degree Granted. Master's in Family Practice MSN Diploma (Cum Laude)
Dr. Alex Jimenez, DC, APRN, FNP-BC*, CFMP, IFMCP, ATN, CCST
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