Spinal Cord Injuries Clinical Trial
Official title:
Longitudinal Assessment of Spinal Cord Structural Plasticity Using DTI in SCI Patients
This study will apply novel magnetic resonance imaging (MRI) techniques to investigation of spinal cord injury (SCI) to learn how nerve fibers repair and neural cells regain ability to control muscle during the rehabilitation. The information gained will be helpful for physicians to make more accurate diagnosis of SCI, predict injury recovery and movement restoration, and develop more effective treatment plans.
Today, the International Standards for the Neurological Classification of Spinal Cord Injury
(ISNSCI) , which includes tests of motor and cutaneous sensory function, and Spinal Cord
Independence Measure (SCIM) are the gold standards for neurological classification of spinal
cord injury (SCI). These standard measures have very important applications in the
rehabilitation of SCI as primary clinical and outcome measures. Despite the importance and
usefulness of their applications, these standard measures have their limitations. For
example, ISNSCI, intended to be a clinical classification system, is subjective and
relatively insensitive to incremental neurophysiological and functional changes during both
acute and chronic stages of recovery. Moreover, the ISNSCI cannot evaluate the spinal cord
(SC) function bellow the neurological level. For some patients such as children and patients
with concomitant brain injuries, reliable evaluation cannot be completed due to their limited
cognitive engagement in the evaluation process. Magnetic resonance imaging (MRI) has been
proposed as a more objective tool to help clinicians make prognosis. However, recent study
showed that conventional clinical MRI does not correlate well with scores measured with
ISNSCI.
Diffusion Tensor Imaging (DTI) is an advanced MRI tool capable of probing white matter
integrity information through measuring directional diffusion of water molecules, thus
providing more microscopic details than conventional MRI. Recent findings suggest that DTI is
a promising, non-invasive and objective tool for evaluating and monitoring structural changes
within white matter axon pathways after SCI. Our preliminary data showed significant
deviation of DTI indices from normative values of healthy subjects in a SCI patient whose
conventional T2 scans appeared to be normal (see preliminary data section). A likely
explanation for this observed alteration of DTI indices is degeneration and demyelization in
descending axonal pathways. Although DTI has been used in animal models to measure the
evolution of the injury in the SC and showed great promise in detection of pathological
changes in SC, no longitudinal DTI data obtained from human SC are available to indicate
sensitivity of DTI technique in detecting SCI progression or recovery. Is DTI capable of
detecting structural changes taking place in the SC over the course of rehabilitation in
individuals with SCI? Will these measured DTI parameters correlate with ISNSCI-based scores?
The fundamental hypothesis of the current study is that rehabilitation can facilitate SC
fiber tract repair along with spontaneous adaptations following the injury to help reconnect
some of the injured nerve fibers with motoneurons controlling muscles and this will in turn
improve the motoneuron activity to promote muscular function, and all these changes can be
detected by the proposed longitudinal DTI protocols and standard clinical tools for motor
function evaluation. The expected results gained by this longitudinal study would support the
application of DTI in monitoring plastic changes in the injured SC and the DTI-derived
measures could potentially aid clinicians make more objective diagnosis of the injury and
estimate its progression, which are critical in planning targeted therapies. However, it is
out of the scope of this proposal to distinguish contributions to structural changes
occurring in the SC between spontaneous and treatment factors. Because it is unethical to not
treat patients, this limitation cannot be overcome in the current human study. Given the
primary focus of the study being longitudinal tracking of SC structural changes using
neuroimaging rather than determining relative contributions to these changes by spontaneous
recovery and treatment, the limitation should not significantly influence the quality of our
study. To test the hypothesis, the investigators propose the following Specific Aims.
Aim 1: Track SC structural changes in patients with incomplete SCI (iSCI) using DTI. Each
patient in the proposed study will be scanned covering entire cervical region of the SC using
a DTI sequence at baseline, 2 weeks, 1 month, 3 month and 6 month after start of standard
rehabilitation intervention. DTI indices (see methods for details) will be quantified and
compared across all time points. Previous longitudinal brain DTI human and animal studies
suggest that DTI is sensitive to detect brain whiter matter structural changes 24 hours
(animal study) and 3 months (unpublished human DTI results by PI's group) after brain injury,
and 6 month after initial scan in patients with Amyotrophic lateral sclerosis(ALS) (DTI data
were only available 6 months after initial scan in this study). The investigators hypothesize
that the proposed DTI protocol will be able to capture structural changes in SCI during its
recovery course.
Aim 2: Correlate the SC plasticity manifested by changes in DTI indices with clinical
assessments of injury and sensorimotor function. Quantitative DTI indices will be correlated
to clinical diagnoses of SCI and clinical evaluations of upper and lower limb sensorimotor
function of the patients. It is hypothesized that the DTI index of SCI will significantly be
correlated with clinical diagnosis and scores of upper and lower sensorimotor function. The
DTI parameter holds great promise to be a biomarker of SCI and is expected to have prognostic
value in predicting functional outcome of a rehabilitation program.
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