A Systematic Review of Musculoskeletal Mobilization and Manipulation Techniques Used in Veterinary Medicine
Abstract
:Simple Summary
Abstract
1. Introduction
2. Materials and Methods
3. Results
3.1. Clinical Indications
3.1.1. Mobilization
3.1.2. Manipulation
3.2. Dosages
3.2.1. Mobilization
3.2.2. Manipulation
3.3. Outcome Parameters
3.3.1. Observation
3.3.2. Physical Examination
3.3.3. Muscle Tone and Activity
3.3.4. Spinal Reflexes
3.3.5. Mechanical Nociceptive Thresholds
3.3.6. Passive Joint Range of Motion
3.3.7. Thoracolumbar Flexibility
3.3.8. Motion Analysis
3.3.9. Visual Analog Scales
3.3.10. Owner Surveys of Performance
3.3.11. Thermography
3.3.12. Lameness Evaluation
3.4. Clinical Efficacy
3.4.1. Physical Examination
3.4.2. Muscle Tone and Activity
3.4.3. Spinal Reflexes
3.4.4. Mechanical Nociceptive Thresholds
3.4.5. Passive Joint Range of Motion
3.4.6. Thoracolumbar Flexibility
3.4.7. Motion Analysis
3.4.8. Visual Analog Scales
3.4.9. Owner Surveys of Performance
3.4.10. Thermography
3.4.11. Lameness Evaluation
4. Discussion
4.1. Quality
4.2. Treatment Methods
4.3. Clinical Indications
4.4. Dosages
4.5. Outcome Parameters
4.6. Perceived Efficacy
4.7. Limitations
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Indication | Treatment Methods | Species [Citation] |
---|---|---|
Carpal Stiffness | Joint immobilization-remobilization | Canine [19] |
Cervical Pain or stiffness | Osteopathy (with sedation, general anesthesia) | Equine [20,21,22] |
Thoracolumbar | ||
Acute pain | Manipulation | Equine [23] |
Chronic pain | Manipulation, Tail traction | Equine [10,24,25,26] |
Muscle hypertonicity | Manipulation | Equine [27] |
Stiffness | Caudal trunk displacement, Osteopathy (with sedation, general anesthesia), Manipulation | Equine [20,21,22,28,29,30,31] |
Study [Citation] | Study Design | Study Sample | Intervention | Outcome Parameters | Main Results | Study Quality |
---|---|---|---|---|---|---|
Canine Mobilization | ||||||
Olson, 1987 [19] | RCT | Subjects: 10 dogs Inclusion: Unilateral carpal immobilization with splint × 6 weeks Exclusion: NA | Treatment: Carpal flexion, traction and craniocaudal translation (n = 6): 3 sets of 20 oscillations, once daily × 4 weeks Control: No carpal remobilization (n = 4) | Outcomes: Passive carpal joint ROM, motion analysis of carpal joint angle at walk Follow up: 4 weeks Drop out: 2 in control group | Increased carpal passive ROM and flexion-extension joint angles at walk over time (p < 0.05), but no group differences Mobilization: 140° Control: 138° | Moderate |
Equine Mobilization | ||||||
Ahern, 1994 [20] | Cohort, Retrospective | Subjects: 86 horses Inclusion: Axial skeleton pain Exclusion: NA | Treatment: Cervical vertebral mobilization under anesthesia—single treatment session Control: NA | Outcomes: Owner survey Follow up: 6–18 months Drop out: 17 of 103 surveys (17%) | Clinical improvement: 95% within 2 weeks; 5% within 6 weeks Maintained improvement: 88% pain free Unsuccessful: 12% return of clinical signs | Low |
Pusey, 1995 [22] | Cohort, Retrospective | Subjects: 127 horses Inclusion: Axial skeleton stiffness Exclusion: NA | Treatment: Osteopathic treatment under sedation (82%) Mobilization under anesthesia (17%) Control: NA Note: Treatment not described | Outcomes: Owner survey Follow up: >12 months Lost to follow up (2%) | Long-term responses: Improved: 75% No change: 18% Worse: 5% | Low |
Colles, 2014 [21] | Cohort | Subjects: 51 horses Inclusion: Unresponsive chronic lameness or gait abnormality, neck or back stiffness, muscle tone altered, tenderness, thermographic asymmetries (>1.5 °C) Exclusion: NA | Treatment: Osteopathic treatment under sedation every 2–6 weeks (average 6, range 1–14) Mobilization under anesthesia: Single treatment (67%), 2 treatments (22%), 3 treatments (2%) Control: NA | Outcomes: Owner survey Follow up: 6–12 weeks (short term); 6 months to 7 years (long term) Lost to follow up (37%) | Short-term responses (6–12 weeks): Return to work: 90% Improved performance: 20% Reduced performance: 18% Failed to respond: 10% Long-term responses (>6 months): Return to prior level of work: 53% Reduced level of work: 31% Poor response: 16% | Low |
Taylor, 2019 [27,28] | Cohort | Subjects: 13 horses Inclusion: Normal horses Exclusion: Back pain, lameness, analgesics, reduced performance × 6 months | Treatment: Caudal truncal displacement—single treatment session Control: NA | Outcomes: Spinal angles and displacement at 5 thoracolumbar sites Time points: Pre- and post-Tx | Increased thoracolumbar flexion (3.4°) Reduced thoracolumbar lordosis (11 mm) | Moderate |
Long, 2020 [26] | Cohort | Subjects: 11 horses Inclusion: Back pain, lameness score 0–2 (out of 5) Exclusion: NA | Treatment: Caudal tail traction—single treatment session Control: NA | Outcomes: MNTs at 5 bilateral trunk sites (T18-L3 and pelvis) Time points: Pre- and post-Tx | Percent increase in MNT values: Thoracic (83%) Lumbar (50%) Pelvic (52%) | Moderate |
Equine Manipulation | ||||||
Haussler, 2003 [23] | RCT | Subjects: 26 actively ridden English collegiate horses Inclusion: Back stiffness Exclusion: Acute back pain, lameness | Treatment: HVLA (n = 12)—once weekly × 3 weeks Control: No Tx (n = 12) | Outcomes: MNT at 52 axial skeleton sites Time points: Baseline, 7 and 14 days Dropout (N = 2, 8%) | Differences in pooled MNT values between treatment and control groups Inside treatment area (T13-L6) = Increased 11 ± 4% (5 of 7 sites) Outside treatment area = Increased 3 ± 8% (2 of 7 sites) | High |
Wakeling, 2006 [24,27] | RCT | Subjects: 26 collegiate horses Inclusion: Epaxial muscle fasciculations, hypertonicity, pain, informed consent Exclusion: Overt lameness, concurrent therapies, chronic back problems, history of spinal pathology or foot problems | Treatment: HVLA (n = 9), Reflex inhibition (n = 8)—single treatment sessions Control: No Tx (n = 9) | Outcomes: Epaxial muscle tonometry and EMG: T16 bilaterally Time points: Pre- and post-Tx | HVLA: Reduced muscle tone (13%), decreased EMG intensity (21%) Reflex inhibition: Reduced muscle tone (12%), decreased EMG intensity (18%) Control: No change muscle tone (0.3%) or EMG intensity (6%) | High |
Haussler, 2007 [28,30] | RCT: Cross-over design | Subjects: 10 horses Inclusion: Acute back pain model (Steinman pin implantation in spinous processes) Exclusion: NA | Treatment: HVLA + mobilization (n = 10)—single treatment session Control: Mobilization only (n = 10) Note: Insufficient washout period, concurrent use of NSAIDs | Outcomes: Vertical trunk displacements, applied force, stiffness Time points: Baseline, post pin implantation, post-Tx, 7-day washout period | HVLA: Increased vertical displacement (15%), increased applied force (18%) Control: Increased vertical displacement (0%), decreased applied force (2%) | Moderate |
Gomez-Alvarez, 2008 [29] | Cohort | Subjects: 10 Warmblood horses Inclusion: Back pain, asymmetric motion, atrophy Exclusion: Lameness, poor prognosis to applied therapy | Treatment: HVLA—single treatment session Control: NA | Outcomes: Vertebral ROM from neck to pelvis; Limb joint angles; Stride length and duration during walk and trot Time points: Pre-Tx, 1-h post Tx, 3 weeks post Tx | Stride length: No change Neck angle: No change Limb kinematics: Walk—No change Trot—Increased hip flexion (3°), Increased forelimb flexion (3 cm) FE: Walk—No change; Trot—Increased ROM at T13 and T17 1 -hour post Tx but decreased 3 weeks post Tx LB: Walk—Decreased ROM at T13 and T17 3-weeks post-Tx; Trot—Increased ROM at L3 1-h post-Tx AR: Increased pelvic symmetry | Moderate |
Sullivan, 2008 [25,30] | RCT | Subjects: 38 horses Inclusion: No overt back pain Exclusion: Lameness | Treatment: Instrumented HVLA (n = 8)—single treatment session Massage therapy (n = 8)—single treatment session Phenylbutazone (n = 7): 2g PO BID × 7 days Control: Inactive control (n = 7) Active control (n = 8) | Outcomes: MNTs at 7 thoracolumbar and sacral sites (T3-S2) Time points: Baseline, 1, 3 and 7 days post-Tx Note: Owners (21%) refused to allocate horses to HVLA or NSAID groups | Percent increase in MNT values at Day 7: Instrumented HVLA: 27% Massage therapy: 12% Phenylbutazone: 8% Inactive control: 1% Active control: 0% | Moderate |
Haussler, 2010 [25,29] | RCT | Subjects: 24 actively ridden English collegiate horses Inclusion: Normal horses Exclusion: Acute back pain, lameness | Treatment: HVLA + mobilization (n = 12)—once weekly × 3 weeks Control: Mobilization only (n = 12) | Outcomes: Vertical trunk displacements, applied force, stiffness Time points: Pre- and post-Tx | Percent change at 3 weeks: HVLA: Increased vertical displacement (40%), increased applied force (20%), increased stiffness (7%) Control: Increased vertical displacement (19%), decreased applied force (4%), decreased stiffness (15%) | High |
Acutt, 2019 [10] | Cohort | Subjects: 6 show jumping horses Inclusion: Painful response to local palpation Exclusion: Lameness, neck or back pain, pathology | Treatment: HVLA—single treatment session Control: NA | Outcomes: Inertial sensor system, static bioimpedance, dynamic acoustic myography, diagnostic acupuncture examination Time points: Baseline, 24, 48, and 72 h post-Tx | Percent change over time: Local pain response: Absent immediately post-Tx and at 72 h Lameness: No change Static bioimpedance: Altered at 24 and 72 h post-Tx Dynamic acoustic myography: Altered at walk and trot | Moderate |
Haussler, 2020 [31] | RCT | Subjects: 61 Western pleasure horses Inclusion: Back pain, stiffness, muscle hypertonicity, poor performance Exclusion: Lameness >3 (out of 5) | Treatment: 3 treatment sessions over 3–5 days HVLA (n = 12) HVLA + Low level laser therapy (n = 11) Low level laser therapy alone (n = 11) Note: Incomplete randomization, concurrent medications or treatments, lacked a negative control | Outcomes: Visual analog scale, back pain, epaxial muscle tone, trunk stiffness, MNTs Time points: Baseline, 3 sessions over 3–5 days Dropout (44%) | Percent change over time: HVLA: Improved thoracic (28%) and pelvic (28%) reflexes, No significant change pain (13%), hypertonicity (17%), stiffness (18%) HVLA + Laser: Decreased pain (14%), hypertonicity (55%), stiffness (54%) Laser alone: Decreased pain (41%), hypertonicity (20%), stiffness (25%) | Low |
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Haussler, K.K.; Hesbach, A.L.; Romano, L.; Goff, L.; Bergh, A. A Systematic Review of Musculoskeletal Mobilization and Manipulation Techniques Used in Veterinary Medicine. Animals 2021, 11, 2787. https://doi.org/10.3390/ani11102787
Haussler KK, Hesbach AL, Romano L, Goff L, Bergh A. A Systematic Review of Musculoskeletal Mobilization and Manipulation Techniques Used in Veterinary Medicine. Animals. 2021; 11(10):2787. https://doi.org/10.3390/ani11102787
Chicago/Turabian StyleHaussler, Kevin K., Amie L. Hesbach, Laura Romano, Lesley Goff, and Anna Bergh. 2021. "A Systematic Review of Musculoskeletal Mobilization and Manipulation Techniques Used in Veterinary Medicine" Animals 11, no. 10: 2787. https://doi.org/10.3390/ani11102787
APA StyleHaussler, K. K., Hesbach, A. L., Romano, L., Goff, L., & Bergh, A. (2021). A Systematic Review of Musculoskeletal Mobilization and Manipulation Techniques Used in Veterinary Medicine. Animals, 11(10), 2787. https://doi.org/10.3390/ani11102787