Mechanical Neck Pain Clinical Trial
The purpose of this study was to explore the immediate effects of transversrse vertebral pressures (TVP) to the thoracic spine on cervical range of motion and pain in subjects with neck pain,
Recruitment was by convenience sampling via referrals from local physical therapists and
flyers posted on a university campus. Participants were assigned to either a transverse
vertebral pressures mobilization group or a control group. Inclusion criteria for the
mobilization group were 1) ages 18 to 60, and 2) mechanical neck pain defined as pain
exacerbated by movement. Among the exclusion criteria were unexplained night pain,
unexplained weight loss, numbness and tingling in the arms and/or legs, balance or
coordination problems, morning stiffness lasting greater than one hour, a history of
whiplash injury within six weeks of treatment, diagnosis of osteoporosis, symptoms
suggestive of nerve root compression, prior cervical or thoracic spine surgery, or a pending
legal action. Inclusion criteria for the control group were 1) ages 18 to 60, and 2)
asymptomatic neck and thoracic regions over the previous six years by subject report. The
latter group was labeled "control" in the sense that it allowed blinding of the rater rather
than in the sense of a sham treatment group. The project was approved by the University of
Puget Sound Institutional Review Board, and written informed consent was obtained from all
the subjects.
Outcome Measures Outcomes of interest were active neck motion, pressure pain threshold (PPT)
and report of pain. For active range of motion, a single bubble inclinometer (MIE
Inclinometer, Medical Research Ltd, London, UK) was used to measure flexion, extension, and
side-flexion with the subjects seated. Since measurement of rotation by inclinometer would
introduce a change from the sitting position, a universal goniometer was chosen to measure
rotation. De Koning et al conducted a systematic review of seated inclinometry for
quantifying active cervical ROM. Interrater intraclass correlation coefficients (ICCs) for
flexion, extension and lateral flexion varied from 0.81 to 0.94 for healthy subjects and
from 0.68 to 0.86 for those with neck pain. Among patients with mechanical neck pain, ICCs
for cervical rotation using the universal goniometer in sitting have been reported as 0.77
to the right and 0.57 to the left.12 In order to consider a motion to have changed, we
required statistical significance at ≤ 0.01 and a difference in degrees of ≥5. Before
commencing the study, one researcher participated in a training session followed by
intra-rater reliability testing for all ROM measurements.
PPT, the minimum pressure that induces pain, was measured at the right lateral epicondyle
using a hand-held digital algometer (Model FPX 25, Wagner Instruments, Greenwich CT.) Three
measurements were taken separated by 10 second intervals, and the mean of these trials was
used for analysis. Good to excellent reproducibility, intra-rater and inter-rater
reliabilities for PPT have been reported.13-15 However, Prushansky et al reported a
significant difference between raters which prompted the recommendation that PPT measurement
should be performed by the same rater when utilized as an outcome measure. We followed this
recommendation.
An 11-point numerical pain rating scale (NPRS) was used to assess pain before and after the
intervention. Cleland et al reported the psychometric properties of the NPRS specific to
neck pain in a cohort of 137 patients. Test-retest reliability was moderate (ICC=.76; CI,
.51-.87). The minimum clinically important difference for neck pain in his study was a
change of 1.3 points. In our study, we selected a requirement of a 1.5-point change for
clinical importance.
Study Protocol After determining eligibility, baseline ROM and PPT scores were taken by one
blinded rater, and subjects completed an NPRS. The mobilization group was treated with
non-thrust transverse vertebral pressures as described by Maitland. The patient lay prone
with arms to the side and in a "forehead rest position". Pressures were applied to spinal
levels T1 through T4. The spinous process of T1 was identified by first locating C6 using
the cervical extension method17 and then counting caudally. The researcher stood at the
level of the vertebra to be mobilized on one side of the subject. The pad of the
researcher's non-dominant thumb was placed in contact with the lateral aspect of the spinous
process of T1, while the dominant thumb was placed on the dorsal side of the other thumb.
Pressure was applied to the spinous process to produce small amplitude, low velocity
oscillation into resistance to the end-range of the vertebra (Grades IV to IV+). This
procedure was performed for 30 seconds, then sequentially applied to the next caudal level
through T4. The same pattern of application was used on the subject's contralateral side.
The entire procedure was repeated once again for a total of 8 minutes. This was followed by
a repeat of the outcome measurements. The control group received no treatment. Each control
subject assumed the same prone position for 8 minutes as was used with the mobilization
group and outcome measurements were repeated. The researcher performing the outcome
measurements was blinded to group assignment. All subjects were clothed such that no
localized residual evidence of thoracic manual contact was visible.
Statistical Analyses Data were analyzed with SPSS, Version 14.0 (SPSS, Inc, Chicago IL). We
compared pre-intervention data between the transverse mobilization group and the control
group utilizing independent t-tests for ROM and PPT, and the Mann-Whitney test for NPRS
scores. We compared pre and post session measurements within each group utilizing paired
t-tests for ROM and PPT, and the Wilcoxon signed-ranks test for NPRS scores.
;
Allocation: Non-Randomized, Intervention Model: Single Group Assignment, Masking: Single Blind (Outcomes Assessor), Primary Purpose: Treatment
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