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Spinal adjustment

Spinal adjustment, also known as , is a manual therapeutic technique that involves applying a controlled, high-velocity, low-amplitude to a spinal using the hands or a device, moving it beyond its passive to restore mobility and alleviate dysfunction. Primarily performed by , it is also utilized by osteopathic physicians, physical therapists, and other trained healthcare providers as a non-invasive for musculoskeletal conditions. The procedure aims to correct spinal misalignments, reduce pain, and improve overall function without the use of drugs or . The origins of spinal adjustment trace back to ancient civilizations, with modern chiropractic formalized in 1895 by . During a spinal adjustment, the patient typically lies on a specialized table while the practitioner assesses joint motion and applies targeted force, often producing a characteristic popping sound from the release of gas bubbles in the joint fluid (); sessions may last 10-30 minutes and are often combined with advice on exercise, posture, or lifestyle modifications. It is most commonly used to treat , , headaches, and joint issues such as or , though evidence is strongest for with more limited support for other conditions, with recent evidence from clinical trials and systematic reviews indicating small short-term improvements in pain but likely no difference in function compared to for acute , and modest benefits comparable to other therapies for chronic . While generally safe, with common side effects limited to temporary soreness, stiffness, or headaches, rare serious complications like or can occur, particularly with cervical manipulations, underscoring the importance of qualified practitioners and screening for contraindications such as or recent fractures. Usage has grown significantly, with about 11% of U.S. adults reporting in 2022, reflecting its integration into mainstream healthcare for conservative . By the early 20th century, gained legal recognition, with issuing the first U.S. state license in 1913, and it has since evolved into a regulated healthcare field practiced by approximately 70,000 licensed chiropractors in the United States (with around 57,000 employed as of 2024).

Overview and History

Definition and Principles

Spinal adjustment is defined as a therapeutic involving the application of a controlled force to a specific spinal , primarily aimed at improving , alignment, or function, and is most commonly associated with chiropractic care, though it is also utilized in and . This intervention targets the to address restrictions in motion segments, which consist of two adjacent vertebrae along with their and surrounding ligaments and muscles, thereby facilitating biomechanical restoration. The underlying principles of spinal adjustment are rooted in the subluxation theory, which posits that minor misalignments or biomechanical dysfunctions in the spine—known as vertebral subluxations—can lead to nerve interference, disrupting the nervous system's role in maintaining health and function. Central to this approach is the biomechanics of spinal motion segments, where adjustments seek to restore joint play (the small, accessory movements essential for normal articulation) and enhance proprioceptive feedback, which informs the body's positional awareness and neuromuscular control. The primary goals include alleviating restrictions that may impair segmental motion, promoting self-healing mechanisms without drugs or surgery, and optimizing the spine-nervous system relationship. Key terminology distinguishes spinal adjustment techniques, particularly the high-velocity low-amplitude (HVLA) , which delivers a rapid, controlled force over a very short distance (typically <2–3 mm) with magnitudes of 220–889 N within the joint's anatomical range to engage and release barriers to motion, often producing an audible sound. In contrast, spinal mobilization involves gentler, low-velocity, oscillatory movements that do not employ thrusting, serving as a less aggressive alternative to for similar biomechanical aims. Over time, the principles of spinal adjustment have evolved from vitalistic models, as originally conceptualized by D.D. Palmer in the late 19th century with an emphasis on innate intelligence and universal life forces disrupted by subluxations, to more evidence-based frameworks that prioritize musculoskeletal disorders and integrate scientific validation of biomechanical and neurological effects. This shift reflects ongoing professional debates, with modern practice increasingly focusing on empirical outcomes while retaining core tenets of subluxation correction for holistic health support.

Historical Development

Building on ancient manipulative traditions documented in various cultures, spinal adjustment, as the foundational practice of chiropractic care, originated in 1895 when Daniel David Palmer, a magnetic healer in Davenport, Iowa, performed the first documented adjustment on Harvey Lillard, a janitor who reported restored hearing after the procedure. Palmer coined the term "chiropractic" from Greek words meaning "done by hand," viewing spinal misalignments—later termed subluxations—as the root of various health issues, and he began teaching the technique informally to promote its spread. This event marked the birth of chiropractic as a distinct profession focused on manual spinal manipulation to restore health. In 1897, Palmer formalized education by founding the Palmer School of Chiropractic, the world's first institution dedicated to the field, which trained practitioners in spinal adjustment techniques and . Early 20th-century growth faced significant opposition, including legal challenges from medical authorities; a pivotal case was , filed in 1976 by chiropractors alleging an anticompetitive , which culminated in a 1987 ruling affirming chiropractic's legitimacy and ending organized medicine's efforts to suppress it. Following Palmer's death in 1913, the profession divided into "straight" chiropractors, who adhered to a vitalistic emphasizing innate intelligence and correction, and "mixers," who integrated broader therapeutic approaches; this schism persisted for decades but evolved toward more collaborative practices. Chiropractic also drew influence from , founded by in 1874, whose emphasis on musculoskeletal manipulation for holistic health paralleled Palmer's principles. By the late , chiropractic shifted toward evidence-based integration into multidisciplinary healthcare, particularly post-1990s with growing recognition in systems and collaborative models for . The issued guidelines on basic training and safety in chiropractic in 2001 (with benchmarks updated in 2005), promoting standardized education and ethical practice. Globally, adoption accelerated in , where the first UK clinic opened in the 1920s under practitioners like , leading to statutory regulation by the 1990s; in Asia, chiropractic expanded notably in from the with formal associations such as the Japanese Chiropractic Association established in 1983 and increasing public acceptance despite initial medical dominance.

Techniques and Procedures

Manual Adjustment Techniques

Manual adjustment techniques in spinal care primarily involve hands-on application of controlled forces by trained practitioners to correct vertebral misalignments, known as subluxations, through high-velocity, low-amplitude (HVLA) thrusts. These methods emphasize direct contact with the patient's body, utilizing the practitioner's body mechanics to deliver precise, directional forces that aim to restore joint mobility and alignment without the use of mechanical devices. The most prevalent approach is the diversified technique, which forms the foundation of and is employed by over 95% of practitioners for its versatility across spinal regions. The diversified technique typically positions the patient in side-posture or setups, targeting specific vertebrae with a quick, targeted thrust often accompanied by a cavitation sound from joint gas release. This method addresses the full and extremities, incorporating variations in hand placement—such as using the or —for optimal force vectoring. It is taught as the core procedure in curricula, allowing adaptations for patient comfort and condition severity. Variations of manual adjustments include the Gonstead method, which prioritizes detailed pre-adjustment analysis using five criteria: visualization of posture, static and motion , skin temperature instrumentation, full-spine analysis, and symptom correlation to identify subluxations. Adjustments are delivered via HVLA thrusts in seated or side-posture positions, focusing solely on affected segments to minimize extraneous and emphasize precision in pelvic and spinal corrections. Another variation is the Thompson drop-table technique, which integrates manual thrusts with segmental table drops to enhance adjustment specificity, often beginning with prone leg-length analysis to detect pelvic imbalances. The practitioner applies a firm, controlled force to the targeted area, allowing gravity-assisted drops (typically 1-2 inches) to facilitate gentler HVLA corrections, particularly for and pelvic regions. This method maintains direct manual input while leveraging table mechanics for patient tolerance. Procedural steps for manual spinal adjustments generally commence with patient positioning tailored to the spinal segment—prone for regions, or seated for or thoracic areas—to optimize access and stability. Pre-adjustment assessment involves motion palpation to evaluate restriction and tenderness, guiding the selection of direction, speed (typically under 200 milliseconds), and (low to avoid strain). The is then applied perpendicular to the plane, with the practitioner stabilizing adjacent segments using their body weight for leverage. Training for manual adjustment techniques falls within the scope of practice, requiring a Doctor of Chiropractic (D.C.) degree, which entails four years of following a , including at least 4,200 hours of classroom, laboratory, and clinical training focused on . This contrasts with physical therapists' , which emphasizes broader musculoskeletal rehabilitation over specialized HVLA spinal adjustments. Licensure mandates passing national board exams on technique proficiency and safety. Typical protocols for acute issues recommend 2-3 sessions per week for 2-4 weeks to address and restore function, with frequency tapering as symptoms improve based on reassessment. This dosing supports progressive joint mobilization while monitoring response to prevent over-treatment.

Instrument-Assisted Methods

Instrument-assisted methods in spinal adjustment utilize specialized devices to deliver precise, controlled mechanical impulses to the and , offering an alternative to manual techniques for practitioners seeking consistency and reduced force application. These tools are designed to mimic the therapeutic effects of high-velocity low-amplitude (HVLA) thrusts while minimizing discomfort and practitioner variability. Primary examples include the Activator Adjusting (AAI), a spring-loaded handheld device that generates quick, low-force impulses to targeted spinal segments, and the Impulse Adjusting , an electromechanical tool that provides oscillating thrusts tuned to the 's resonant frequency. Other notable devices encompass the ArthroStim, a vibratory percussion instrument employing rapid repetitive taps for joint mobilization, and (LLLT) devices integrated as adjuncts to enhance tissue response during adjustments. The mechanics of these instruments focus on delivering calibrated forces that restore segmental motion without the need for direct thrusting. The AAI operates via a spring mechanism to produce short-duration impulses (typically 3-5 milliseconds) with peak forces of 116 to 140 Newtons, resulting in delivery of approximately 0.3-0.5 Joules per activation, which is lower in amplitude but faster than traditional HVLA maneuvers. The Impulse Adjusting Instrument uses electronic controls to emit impulses at 6 Hz over a 2-second duration, with three adjustable force settings and interchangeable styluses for single or dual-pulse modes, allowing adaptation for (lighter preload) versus (higher force) targeting. The ArthroStim generates high-velocity, low-amplitude percussions through electromagnetic coils, producing a series of taps that accumulate therapeutic effect without , while LLLT adjuncts employ non-thermal wavelengths (typically 600-1000 ) to stimulate cellular repair alongside impulses. These devices ensure reproducible force profiles, reducing inter-practitioner differences observed in methods. Advantages of instrument-assisted methods include their suitability for vulnerable populations, such as pediatric and elderly patients, due to the gentle, non-invasive nature that avoids high-force risks associated with adjustments; for instance, the AAI has demonstrated benefits in individuals with or those averse to physical contact. Studies have highlighted improved consistency in force delivery compared to manual variability, potentially lowering practitioner during extended sessions. Additionally, these tools facilitate precise targeting of spinal levels, with LLLT integration showing enhanced pain relief when combined with mechanical adjustments in musculoskeletal applications. Protocols for instrument-assisted spinal adjustment emphasize device calibration and integration with clinical assessment. Instruments like the AAI and are classified as FDA Class II devices, requiring 510(k) premarket notification for and , with regular maintenance to ensure preload accuracy and stylus integrity. Practitioners typically combine these with diagnostic or motion to select settings, applying 1-3 activations per segment in sessions of 10-20 minutes, often alternating with techniques for comprehensive care. Training programs, offered through institutions, stress technique-specific proficiency to optimize outcomes.

Physiological Mechanisms

Biomechanical Effects

Spinal adjustments, particularly high-velocity low-amplitude (HVLA) thrusts, induce biomechanical changes primarily through the and gapping of zygapophyseal (facet) . During , the applied force separates the articular surfaces, often resulting in an audible event caused by the collapse of synovial gas bubbles within the space. This gapping is more pronounced when occurs, with studies showing greater separation in manipulated segments compared to non-thrust interventions. Such mechanical disruption restores joint play and enhances segmental mobility, with systematic reviews indicating small but positive increases in spinal , particularly in the region, following . The forces involved in HVLA adjustments typically peak at 200-600 Newtons for lumbar and thoracic applications, delivered over short durations of 50-150 milliseconds, creating rapid preload and thrust phases that target specific force vectors along the spinal axis. These impulses stretch paraspinal muscles and ligaments, promoting tissue relaxation through mechanical loading, while facet joint stiffness is reduced due to the viscoelastic deformation of surrounding structures. Intervertebral discs exhibit brief decreases in intradiscal pressure during the thrust, alongside creep and stress relaxation behaviors that accommodate the applied load without permanent deformation. Post-adjustment often reveals improvements in spinal alignment at affected segments, contributing to enhanced . Finite models of vertebral stress during HVLA demonstrate localized increases in compressive and forces on facet surfaces and endplates, but these remain within physiological limits, validating the technique's safety profile. Short-term effects include immediate enhancements in and extensibility, while repeated sessions yield cumulative improvements in overall and load distribution over time. Recent reviews as of continue to highlight small to moderate biomechanical benefits but note gaps in long-term data.

Neurological and Systemic Impacts

Spinal adjustments stimulate mechanoreceptors in the spinal joints, activating large-diameter A-beta afferent fibers that contribute to pain inhibition through the of pain. This mechanism involves presynaptic inhibition in the dorsal horn of the , where non-noxious input from A-beta fibers reduces the transmission of nociceptive signals from smaller A-delta and C fibers to higher centers. Adjustments to the spine have been shown to modulate the , particularly enhancing parasympathetic tone. In studies involving upper spinal manipulative therapy (), () metrics such as the normalized high-frequency component (nuHF) increased significantly post-intervention, indicating greater parasympathetic dominance in both asymptomatic volunteers and patients with acute . Lower similarly promoted parasympathetic activity in patients, as evidenced by increased standard deviation of normal-to-normal intervals (SDNN) and decreased low-frequency to high-frequency (LF/HF) ratios. However, systematic reviews note low-quality evidence overall for consistent ANS effects, with manipulations potentially influencing high-frequency HRV parameters more reliably than other sites. Systemic hormonal responses to spinal adjustments include elevations in oxytocin and , which may contribute to relief and modulation. A demonstrated significant immediate post-manipulation increases in plasma oxytocin and , alongside a rise in serum , following thoracic or SMT. While some stress-response investigations report reduced levels after repeated adjustments, suggesting adaptive dampening of the hypothalamic-pituitary-adrenal axis, evidence for endorphin release remains limited and inconsistent across studies. Regarding immune function, thoracic spinal adjustments have been associated with reduced production of pro-inflammatory cytokines such as tumor necrosis factor-alpha (TNF-α) and interleukin-6 (IL-6) , potentially indicating an systemic effect. However, no significant changes in natural killer () cell counts or activity were observed immediately post-SMT in these trials. Proprioceptive and sensorimotor enhancements following spinal adjustments arise from stimulation of mechanoreceptors, including Ruffini endings (slowly adapting, contributing to joint position sense) and Pacinian corpuscles (rapidly adapting, detecting ). Clinical trials have reported improved joint position sense accuracy and reduced errors in repositioning tasks after lumbar or manipulations, alongside better balance and coordination in dynamic postural assessments. These effects likely stem from increased afferent input to the , refining sensorimotor integration. Neuroimaging evidence from (fMRI) reveals altered activation in the somatosensory cortex post-SMT, with decreased connectivity in resting-state networks involving the primary somatosensory area and prefrontal regions. One study observed immediate reductions in functional connectivity between the somatosensory cortex and hubs, correlating with subjective relief. Additionally, HRV improvements, such as 13-19% increases in mean RR intervals following diversified adjustments, support enhanced autonomic balance and potential modulation. Despite these findings, neurological and systemic impacts of spinal adjustments are predominantly short-term, lasting from hours to a few days, with effects varying by adjustment site—cervical interventions often yielding more pronounced autonomic shifts than ones. Systematic reviews highlight methodological limitations in existing , including small sample sizes and heterogeneous protocols, underscoring the need for larger, standardized studies to clarify long-term implications.

Clinical Applications and Evidence

Treatment of Musculoskeletal Conditions

Spinal adjustment, a component of and osteopathic care, is commonly applied to musculoskeletal conditions such as and , where it aims to alleviate pain and improve function through targeted joint mobilization or high-velocity thrusts. For acute , a 2017 and of 26 randomized controlled trials (RCTs) involving 2,278 patients found moderate-quality evidence that spinal manipulative therapy (SMT) provides a pooled pain reduction of 9.95 mm on a 100-mm visual analog (VAS) and a standardized difference (SMD) of -0.39 in function at up to 6 weeks, outperforming usual care but showing no significant difference from interventions in limited studies. In chronic , a 2018 of 51 trials, including 9 pooled RCTs with 1,176 patients, reported moderate-quality evidence of pain reduction (SMD -0.28, 95% CI -0.47 to -0.09) and improvement (SMD -0.33, 95% CI -0.63 to -0.03), with manipulation demonstrating larger effects than mobilization when compared to active therapies. The (ACP) 2017 clinical practice guidelines recommend as a first-line nonpharmacologic option for both acute/subacute and chronic , based on low-quality evidence showing small to moderate benefits in and function, particularly when combined with other like exercise. The (WHO) 2023 guidelines for non-surgical management of chronic primary also recommend spinal manipulative alongside education, exercise, , and psychological . Recent updates, such as a 2023 and meta-analysis of 12 RCTs on thrust manipulation for acute to subacute , confirm short-term superiority over controls for relief (SMD -0.53, 95% CI -0.94 to -0.12) while noting equivalence to exercise in longer-term outcomes. For , evidence from 5 RCTs involving 198 patients indicates low-quality support for , with thoracic manipulation yielding a 32.8% (95% CI 29.9-35.8) greater improvement than controls at one week, alongside 12.6% better reduction. Beyond primary spinal conditions, spinal adjustment shows promise for related musculoskeletal issues like and headaches linked to misalignment. In due to lumbar disk herniation, a randomized of 40 patients found that 60% achieved outcomes equivalent to microdiskectomy after , with significant improvements in and function over one year, though 40% required subsequent surgery. For -type headaches attributed to factors (often cervicogenic in origin), a of RCTs supports SMT's role in reducing frequency and intensity short-term, with effects comparable to common pharmacotherapies and superior to (SMD -0.55 for ), though evidence quality is moderate due to heterogeneity. In osteoarthritis of the spine, SMT serves as a conservative option for symptom management, providing small to moderate and functional relief without disease modification, as endorsed by ACP guidelines for non-radicular . Typical protocols for spinal adjustment in these conditions involve 6-18 sessions over 4-6 weeks, with a dose-response relationship observed in chronic : 12 sessions yielded a 7.5-point greater improvement on the modified Von Korff (0-100) at 12 weeks compared to no treatment, while 18 sessions sustained an 8.8-point benefit at 52 weeks. Combination with rehabilitation, such as exercises focusing on directional preference movements, enhances outcomes; RCTs demonstrate that integrating with reduces and more effectively than either alone in , promoting centralization of symptoms and improved mobility. Functional outcomes are commonly measured using scales like the Oswestry Index (ODI), where typically produces 10-20 point improvements (e.g., ~20 points on a 0-100 ) in chronic cases, reflecting clinically meaningful gains in daily activities.

Use in Non-Musculoskeletal Disorders

Spinal adjustment has been explored for treating various non-musculoskeletal disorders, often based on the premise that vertebral interfere with and systemic , a concept originating from D.D. Palmer's foundational claims in the late that subluxation could cause a wide array of diseases beyond the musculoskeletal system. Early chiropractic theory posited that spinal misalignments disrupted impulses, potentially affecting organs and leading to conditions like digestive disorders or respiratory issues, though modern evidence has largely restricted such applications to adjunctive roles. In asthma management, small trials have reported minor improvements in pulmonary function following , such as slight increases in , but a 2021 of s concluded there is no high-quality supporting its efficacy as a primary or adjunctive . Similarly, for infant colic, a 2011 involving 104 infants suggested led to an approximately 20% greater reduction in crying hours per day compared to at two weeks; however, the study's risk of bias and lack of long-term follow-up have sparked debate, and subsequent reviews (including high-quality studies) have found no appreciable benefit, with overall rated as very poor. As of 2024, regulatory bodies such as the Board of Australia have banned for children under two years due to insufficient and safety concerns. Overall, these findings highlight potential short-term symptomatic relief but underscore the need for larger, blinded studies to confirm benefits. Claims regarding have centered on upper cervical adjustments, with a 2007 pilot study of 50 participants showing that atlas realignment reduced systolic by an average of 14 mmHg and diastolic by 8 mmHg, sustained for eight weeks post-intervention. However, subsequent larger trials and systematic reviews, including a 2021 global summit analysis, have failed to replicate these results, attributing any observed effects to or methodological limitations rather than a direct causal mechanism. For digestive issues like (IBS), preliminary research suggests spinal adjustment may enhance , potentially alleviating symptoms through improved regulation, as indicated by case series showing increased bowel movement frequency and reduced after thoracic adjustments. Evidence for these non-musculoskeletal applications is predominantly low-quality, with GRADE assessments rating most studies as low or very low due to small sample sizes, high risk of bias, and prominent placebo responses that complicate interpretation. A 2021 systematic review emphasized that while some patient-reported outcomes suggest subjective benefits, objective measures fail to demonstrate consistent effects across conditions like asthma, colic, and hypertension. In contrast to the moderate-to-high evidence supporting spinal adjustment for musculoskeletal conditions, these exploratory uses lack robust validation. Recent consensus statements from chiropractic and multidisciplinary panels, updated through 2025, discourage routine application outside musculoskeletal disorders, recommending it only as an adjunct with prompt referral to medical specialists for underlying pathologies. Patient selection should prioritize those with mild, refractory symptoms unresponsive to conventional care, ensuring integrated management to mitigate risks of delayed diagnosis.

Safety, Risks, and Regulation

Adverse Effects and Complications

Spinal adjustments, like other manual therapies, are associated with a range of adverse effects, most of which are minor and transient. Common minor effects include soreness or local discomfort in the treated area, affecting 30% to 55% of patients, which typically resolves within 24 to 48 hours. Other frequent mild reactions encompass transient , , and , reported in up to 20% of cases following . A 2023 systematic review confirmed that mild adverse effects like soreness and occur in 20-50% of sessions, with no increased risk compared to control interventions. These effects are generally self-limiting and do not require medical intervention, resembling post-exercise soreness. Serious complications from spinal adjustments are rare but can include vertebrobasilar artery dissection (VAD), particularly with cervical manipulation. Recent studies (2023-2024) have not found a significant association between cervical spinal manipulation and vertebrobasilar artery dissection, with one 2023 cohort reporting cases were 0.17 times as likely to have received manipulation compared to controls; earlier estimates suggested an incidence of 1 in 1 million to 1 in 5 million manipulations. A 2022 cohort study using Medicare claims data found no significant increase in odds of VAD following cervical spinal manipulation compared to evaluation alone, though temporal associations persist in case reports. In the lumbar region, cauda equina syndrome represents a rare but severe complication, primarily linked to disc herniation exacerbation during manipulation. A 2024 retrospective cohort study of over 67,000 adults with low back pain reported a 0.07% incidence of cauda equina syndrome within 90 days following chiropractic spinal manipulation, with no increased risk compared to physical therapy alone. A 2023 retrospective study of 960,140 chiropractic spinal manipulations reported severe adverse events at a rate of 0.21 per 100,000 manipulations (95% CI: 0.00-0.56), with no cases of VAD or cauda equina syndrome observed. Incidence data from large trials, such as the 2004 trial involving over 1,300 participants, indicate that mild adverse effects occur in approximately 50% of sessions, with no serious events reported in the study cohort. Prospective surveys corroborate this, estimating benign reactions in 33% to 50% of sessions across diverse patient populations. Several factors influence the profile of adverse effects. High-velocity, low-amplitude (HVLA) thrust techniques, common in adjustments, carry a theoretically higher of vascular or structural compared to gentler methods due to the rapid application of force, though empirical data show comparable low rates for both. Patient-specific factors, such as , substantially elevate the of compression fractures during manipulation, as weakened predisposes to iatrogenic even with standard forces. Adverse event reporting in chiropractic care faces challenges from underreporting, with studies estimating that only a fraction of incidents are documented due to reliance on passive systems and patient reluctance to report minor issues. Active protocols, implemented in some clinics and trials, aim to improve detection similar to pharmacovigilance systems like VAERS, capturing more comprehensive data on both mild and severe outcomes. A June 2025 study by Clinical Compass reviewed guidance on U.S. state regulator websites, finding significant variations and lack of detailed content requirements in most jurisdictions, and recommended standardized processes including explicit disclosure of risks to improve .

Contraindications and Professional Guidelines

Spinal adjustments, also known as spinal manipulative therapy, carry specific absolute contraindications where the procedure is deemed inappropriate due to the high risk of harm to the patient. These include acute fractures, dislocations, severe (typically defined as a T-score of -2.5 or lower with one or more fragility fractures on ), acute injuries, ligamentous instability, and conditions such as or active inflammatory spondyloarthropathies during flare-ups, as these can lead to catastrophic complications like vascular rupture or neurological damage. Relative contraindications involve situations where spinal adjustment may still be considered but requires modification of technique, close monitoring, or multidisciplinary consultation to mitigate risks. Examples encompass anticoagulant therapy (such as , which elevates bleeding risk), recent spinal surgery (within the prior six months), moderate , articular hypermobility, and undiagnosed neurological deficits like or cauda equina syndrome symptoms, necessitating careful risk-benefit assessment. Screening protocols are essential prior to performing spinal adjustments to identify potential contraindications and ensure . These typically involve pre-adjustment questionnaires assessing red flags such as unexplained , bowel or bladder dysfunction indicative of , or vertebrobasilar insufficiency symptoms like and ; physical examinations including pre-manipulative holds to monitor for adverse responses; and referrals for such as MRI when spinal or neurological involvement is suspected. Professional regulations for spinal adjustment practice are governed by state-level licensure in the United States, where all 50 states and of require chiropractors to hold a Doctor of Chiropractic degree from an accredited institution, pass national board examinations, and adhere to scope-of-practice laws that authorize as a . Internationally, the World Federation of Chiropractic (WFC) provides guidelines, including its 2023 update to the 20 Principles of Chiropractic Care, which emphasize evidence-informed practice, patient-centered approaches, and adaptations for cultural and regional contexts to standardize safe delivery of manual therapies like spinal adjustment. Ethical guidelines underscore the importance of and ongoing in spinal adjustment. Practitioners must obtain documented from patients, detailing potential risks, benefits, alternatives, and expected outcomes in clear language, as mandated by state regulations and professional standards to uphold patient autonomy and legal compliance. Additionally, requirements, typically ranging from 12 to 24 hours annually depending on the , focus on safety updates, ethical practice, and emerging to maintain licensure and enhance .