Imaging 3 Radiographic and Other ImagingRECOMMENDATIONDiagnostic imaging procedures may be utilized to characterize the biomechanical manifestations of vertebral subluxation, and to determine the presence of conditions which affect the safety and appropriateness of chiropractic care.
Sub-Recommendation
Plain film radiography is indicated: to provide information concerning the structural integrity of the spine, skull and pelvis; the misalignment component of the vertebral subluxation; the foraminal alteration component of the vertebral subluxation; and the postural status of the spinal column. Imaging procedures, including post-adjustment radiography, should be performed only when clinically necessary. It is common for lines of mensuration to be drawn on radiographs to assess subluxation and alignment. These procedures may be done by hand, or the chiropractor may utilize computerized radiographic digitization procedures.
Rating: Established
Evidence: E, L
Commentary
In considering the use of imaging methods employing ionizing radiation as a component of patient assessment, the clinician should determine if the methods of subluxation correction, patient safety, and management require the use of such procedures. The patient should be asked about any conditions which may contraindicate certain imaging procedures.
Reliability studies of several systems of biomechanical analysis, including radiographic marking systems, have been published. Imaging is a necessary component of a number of different chiropractic analyses. The preponderance of evidence supports the reliability of these procedures when properly performed.(1-8, 12, 15-27, 29-32, 36-39, 42-61, 64-68, 70-79, 153)
Moreover, radiographic imaging has revealed statistically significant changes in the direction of atlas positioning following chiropractic adjustment(s).(14, 28, 33-35, 146-148) The effect of chiropractic care on lateral curvature of the cervical spine has been investigated, with significant changes in the cervical curve noted in patients receiving chiropractic care.(9, 62, 63, 69, 149-152, 156-158)
Sub-Recommendation
Imaging procedures employing ionizing radiation should be performed consistent with the principles of obtaining films of high quality with minimal radiation. This may include the use of gonad shielding, compensating filters, and appropriate film-screen combinations.
Rating: Established
Evidence: E, L
A number of dosimetry studies using supplemental filtration and single-speed screens have revealed that in the case of 14 x 36 inch AP full-spine radiographs, the radiation levels were less than sectional films of like-sized subjects. Shielding of radiosensitive structures may be used when it does not obliterate structures of clinical interest. Such shielding results in a reduction of radiation exposure.(10, 11, 13, 160)
Conclusion
The judicious use of spinographic techniques can be valuable in characterizing aspects of the biomechanical manifestations of vertebral subluxation.(146, 154, 155, 187-193) The use of post-adjustment radiographs may also assist the chiropractor in determining effects of chiropractic adjustments on the spine when other less hazardous examination techniques cannot reveal the desired information.
VIDEOFLUOROSCOPY Sub-RecommendationVideofluoroscopy may be employed to provide motion views of the spine when abnormal motion patterns are clinically suspected. Videofluoroscopy may be valuable in detecting and characterizing spinal kinesiopathology associated with vertebral subluxation.
Rating: Established
Evidence: E, L
Commentary
A videofluoroscopic system consists of an x-ray generator capable of operating at low (1/4 to 5) milliamperage settings, an x-ray tube assembly, an image intensifier tube, a television camera, a VCR, and a monitor. The heart of the system is the image intensifier tube. This tube permits imaging at very low radiation levels. It is used instead of intensifying screens and film as a image receptor.
The role of videofluoroscopy in the evaluation of abnormalities of spinal motion has been discussed in textbooks, medical journals, and chiropractic publications.(19, 20, 23, 80-83, 140, 145, 163, 164, 168-170, 172-179, 186, 220) Studies have appeared in the literature comparing the diagnostic yield of fluoroscopic studies versus plain films, as well as reporting abnormalities detected by fluoroscopy which could not be assessed using plain films.(161, 165-167, 171, 180, 183-185)
Reliability has been addressed in a number of studies.(162, 181, 182, 214) Additionally, in a study evaluating the interexaminer reliability of fluoroscopic detection of fixation in the mid-cervical spine, two examiners reviewed 50 videotapes of fluoroscopic examinations of the cervical spine. The examiners achieved 84 percent agreement for the presence of fixation, 96 percent agreement for the absence of fixation, and 93 percent total agreement. The Kappa value was .80 (p .001). The authors concluded, The current data indicate that VF determination of fixation in the cervical spine is a reliable procedure. (181, 214)
Conclusion
Observational and case studies support the use of videofluoroscopy to evaluate vertebral motion when this information cannot be obtained by other means.
Sub-Recommendation
Magnetic Resonance Imaging (MRI) MR imaging may be employed to assess suspected neoplastic, infectious and degenerative conditions of the spine and related tissues as well as the stages of subluxation degeneration. Its use is generally restricted to instances where the desired information cannot be obtained by less costly procedures.Rating: Established
Evidence: E, L
Commentary
Magnetic resonance imaging enables clinicians to obtain clear images of the human body without ionizing radiation.
Literature supports the use of MR imaging for the detection and characterization of numerous manifestations associated with subluxation degeneration.(84-107, 141-143, 194-198, 212) These studies cover a spectrum of phenomena, including:
1. Osseous malalignment
2. Intervertebral disc desiccation and degeneration
3. Osteophytosis
4. Corrugation/hypertrophy of the ligamentum flava
5. Spinal canal stenosis
6. Foraminal stenosis
7. Disc herniation and disc bulging
8. Facet asymmetry
9. Facet degeneration
10. Altered cerebrospinal fluid dynamics
11. Cord compression
12. Gliosis and myelomalacia
13. Spinal cord atrophy
Conclusion
MRI may be employed to disclose manifestations of vertebral subluxation when this information cannot be obtained by more cost-effective means. MRI is also appropriate for evaluating patients with clinical evidence of conditions which may affect the safety and appropriateness of chiropractic procedures.
Sub-Recommendation
Computed Tomography (CT) CT imaging may be employed to assess osseous and soft tissue pathology in the spine and contiguous tissues. Its use is generally restricted to instances where the desired information cannot be obtained by less costly procedures.Rating: Established
Evidence: E, L
Commentary
Computed tomography (also referred to as CT or CAT scanning) is an imaging technique which produces axial (cross sectional) images of body structures using x-radiation. Computer reconstruction methods may be used to depict other planes.
Manifestations of subluxation degeneration which may be demonstrated by CT scanning include disc lesions, spinal canal stenosis due to infolding of the ligamentum flava, osteophytosis, and bony sclerosis.(108-139, 144, 199-201, 210, 211, 213, 220) In addition, CT may be used to evaluate developmental variance and pathologies which could affect the chiropractic management of a case.
Conclusion
CT may be employed to disclose manifestations of vertebral subluxation when this information cannot be obtained by more cost-effective means. CT is also appropriate for evaluating patients with clinical evidence of conditions which may affect the safety and appropriateness of chiropractic procedures, particularly fractures, degenerative changes, and osseous pathology.
Sub-Recommendation
Spinal Ultrasonography Spinal ultrasonography may be used to evaluate the size of the spinal canal, and to detect pathology in the soft tissues surrounding the spine. Its applications in the assessment of the facet inflammation and nerve root inflammation remain investigational at this time.Ratings: Established for determining spinal canal size.
Investigational for facet and nerve root inflammation.
Evidence: E, L
Commentary
Sonographic imaging is a technique which utilizes echoes from ultrasonic waves to produce an image on a cathode ray tube.
Sonographic techniques have been employed to measure the lumbar canal, as well as determining focal stenosis and disc disease.(202-209, 221, 222)
A small study compared sonographic results in patients with back pain previously examined by MRI, x-ray and standard orthopedic examination. The study concluded that the correlation with MRI, x-ray, orthopedic and neurologic examination was approximately 90 percent.(207)
Conclusion
The low cost, availability, ease of application, and noninvasive nature of sonographic imaging make it an attractive addition to the chiropractor's armamentarium. Furthermore, it has the potential to image various components of the vertebral subluxation. However, caution must be exercised in evaluating the claims of promoters of sonographic equipment, particularly those relating to the assessment of nerve root inflammation or facet joint disease. Further research toward the establishment of chiropractic protocols should be undertaken to explore the clinical utility of spinal sonography in chiropractic practice.
Sub-Recommendation
Radioisotope Scanning (Nuclear Medicine Studies) Radioisotope scans performed by qualified medical personnel may be used by a chiropractor to determine the extent and distribution of pathological processes which may affect the safety and appropriateness of chiropractic care when this information cannot be obtained by less invasive means.Rating: Established
Evidence: E, L
Commentary
In this procedure, bone-seeking radioisotopes are injected, and an image is produced demonstrating the degree of uptake of the radioisotopes. The examination is sensitive to regional changes in osseous metabolism, but is not specific. Abnormal bone scans may be due to metastasis, infection, fracture, osteoblastic activity or other pathology.(215-219) No studies or case reports were found linking abnormal bone scans with vertebral subluxation. Bone scans may have limited value in determining the safety and appropriateness of chiropractic procedures.
Conclusion
Radioisotope scans have a limited role in chiropractic practice. Bone scans are a sensitive, but nonspecific indicator of abnormal metabolic activity in bone.
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