Low Back Pain Clinical Trial
Official title:
What Determines a Positive Outcome of Spinal Manipulation for Persistent Low Back Pain: Stiffness or Pain Sensitivity? A Randomized Trial
Introduction Several treatment methods have been proposed to ease the burden of low back pain
(LBP) but none are clearly superior. Spinal manipulative therapy (SMT) is a guideline
recommended treatment, but the effect is moderate to low. Previous publications suggest that
acute LBP patients with who are more stiff are more likely to improve with SMT. However, as
LBP persists changes in the central nervous system which modulates the pain experience
becomes hypersensitive and possible stiffness is not as important an factor. Experimentally
SMT may have a reversible effect of this sensitization.
Objective The primary objective of this study is, to examine whether SMT is more effective in
regards to short term pain relief when directed at level in the lower back characterized by
spinal stiffness or pain hypersensitivity in persistent LBP.
Methods A double blinded randomized clinical trial of up to 155 participants with persistent
LBP included at a multidisciplinary Spinecenter. spinal stiffness (Global Stiffness Score) is
measured using the VerteTracker, a novel device that can quantify stiffness. Pain sensitivity
is measured as pain threshold, tolerance, temporal summation (TS) and conditioned pain
modulation(CPM).
Participants receive SMT at either "the stiffest" or "the most sensitive" segment, a total of
four times over a 14-day period. The quantitative measures are recorded at baseline, post
treatment and at 4-weeks follow-up along with a numerical pain rating (NRS) and the a
disability index (ODI).
Discussion These novel findings could improve clinical decision rules - specifically at which
level in the lower back to direct SMT. Furthermore, the results will potentially shed light
on the underlying mechanisms of SMT - are treatment effects mediated primarily by changes in
stiffness or central hypersensitivity?
1.0 Background 1.1 Treatment of persistent low back pain Low back pain (LBP) is one of the
leading causes of years lived with disability. In Denmark, many patients are treated
conservatively in private practice via general practitioner, chiropractor and
physiotherapist. It is well known that LBP often is recurrent or chronic condition. Patients
with LBP often report pain relief following spinal manipulation although clinical and
research findings are mixed . There is clear evidence that spinal manipulation is able to
give short term pain relief, increase range of motion and the clinical outcomes are
comparable to other common interventions for persistent LBP. Unfortunately, there are no
reliable means to determine beforehand whether spinal manipulation is likely to provide pain
relief for a given patient and it is common practice to simply try a series of treatments to
assess the effect.
1.2 Segmental dysfunctions Spinal manipulation is directed at spinal mechanical dysfunctions.
However, reliably identifying mechanically dysfunctional segments has proven difficult. In an
attempt to objectively quantify such dysfunctions, a mechanical spinal indentation
apparatus,, the VerteTrack (VT) has been developed and when compared to the generally
unreliable palpation findings of an experienced clinician, no correlation was found.
Without reliable and objective indicators of the presence of spinal dysfunctions, clinical
trials of spinal manipulation are bound to include both patients with and without
biomechanical dysfunction, thus potentially obscuring any effect of spinal manipulation in
the treatment of such dysfunctions. This heterogeneity in the experimental groups could, at
least in part, explain the conflicting evidence.
To address this, a preliminary study has compared quantified spinal stiffness measured by VT
and the outcome of spinal manipulation which reported a positive correlation between
objectively quantified spinal stiffness and clinical improvement following manipulation in a
cohort of acute LBP patients. The study suggests that VT may potentially serve to identify a
subgroup of patients with LBP, who also has a higher probability of a positive response to
manipulative treatment.
1.3 Factors complicating treatment of persistent low-back pain After the onset of low-back
pain, the central neural pathways which conduct, modulate and integrate the pain stimulus
changes over time as pain persists and becomes more excitable: It is evident that the
nociceptive receptors become hyperexcitable, leading to increased transmission of nociceptive
sensory input, which in turn causes central hypersensitive and possibly an attenuation of
descending pain-inhibiting mechanisms. Overall, this results in enhanced local pain responses
(hyperalgesia) and sometimes widespread increased pain sensitivity (generalized
hyperalgesia).
There is evidence that such changes occur in the early stages of LBP and that central
sensitization develops in step with the progression to persistent pain.
In recent decades, Quantitative Sensory Testing (QST) has been used to examine and quantify
the pain experience, including intensity, threshold, tolerance, modulation and more. These
findings combined can illustrate generalized hyperalgesia which are indicative of underlying
central sensitization and has been reported in persistent LBP.
Central sensitization appears to be reversible, at least in non-spinal conditions when the
persistent peripheral actor is resolved. Also, it is predictive of both surgical and
non-surgical (analgesic) treatment outcomes. Others however, report that central
sensitization is not predictive of the clinical course of spinal pain. A recent systematic
review regarding QST as a prognostic tool in LBP concluded that there is a sparsity of
studies, which in general are of limited quality, thus the prognostic value of QST in LBP
remains unclear.
To our knowledge, no studies have been published examining the prognostic or treatment
modifying value of QST in relation to spinal manipulation of persistent LBP.
1.4 Objectives The primary aim of this study is to examine if spinal manipulation is more
effective in regards to short term pain relief when directed at spinal segmental stiffness or
segmental pain sensitivity in persistent LBP
Secondary aims of this study:
1. Does pain sensitivity and spinal stiffness change in the subgroup of patients who
respond to treatment compared to non-responders, i.e. whether pain sensitivity and
mechanical stiffness decrease in response to pain relief from spinal manipulation?
a. Does this possibly occur independent of clinical pain relief?
2. Does central sensitization predict short term pain relief of spinal manipulation in
persistent LBP?
3. Does segmental spinal stiffness correlates with segmental spinal pain sensitivity in a
persistent LBP population?
2.0 Methods 2.1 Design A randomized controlled trial consisting of a maximum of 155
participants with persistent LBP.
2.2 Participants All participants to be included in the cohort will be recruited from a
multidisciplinary Spine Center located in Middelfart, Denmark, after being thoroughly
examined by a clinician, specialized in spine disorders and diagnosed with persistent
Non-specific LBP (NSLBP).
The Spine Center is a hospital department, which handles more than 15.000 new patient cases
each year, about 80% of which are referred with LBP and treated, using both conservative as
well as surgical interventions.
2.3 Technical description of quantitative measures 2.3.1 Spinal stiffness Spinal stiffness
using VT: The participant is placed in the prone position as the device will direct a force
perpendicular from the L1 to L5 level starting at a comfortable level below 5 N and
progresses to a maximal of 60 N as linear displacement will be measured and both force and
displacement will be used to calculate the stiffness. VT has shown to be reliable and may be
possible to use in clinical practice.
As standard with VT, all of the lumbar landmarks will be located by using ultrasonography.
Research have shown that it provides a more accurately identification than manual palpation
and the skill is easy obtainable. The lumbar segments will be clearly marked with a black
marker to ensure that the both SM, QST and VT is directed at the indicated lumbar segment.
2.3.2 Quantitative sensory testing Manual pressure algometry(MPA): PPT will be measured the
spinal process at L1 to L5 level using a pressure algometer (Somedic pressure algometer with
a 1 cm2 probe, model 2, Hørby, Sweden). Pressure will be applied manually with a
near-constant velocity of approximately 50 kilopascal(kPa)/s until the participant indicates
the pressure as becoming painful by pressing an indicator button connected to the algometer.
PPT measurements will be repeated 3 times with approximately 10 second rest intervals. The
head of the algometer will be placed such that repeat applications overlapped partly. If no
pain has been elicited by 1000 kPa, this will be recorded as the PPT. If the first and second
measurements are 1000 kPa, a third will not be performed. MPA is a validated and often-used
method to asses pain sensitivity.
Thermal pain sensitivity (ThPS): ThPS will be measured with a Medoc TSA-II thermode
stimulator at L1 to L5 level as an average of the final 4 measurements of a series of 5
stimulations (baseline 32 celsius, increase 1 celsius/second), with 10 second intervals.
The participant indicates when the stimulation is perceived as pain by pressing an indicator
button, upon which the temperature returns to baseline (decrease 10 celsius/second). When
measured at the spine and in the L5-dermatome ThPS have shown to have good to excellent
reliability.
Central sensitization: will be evaluated using Computer-controlled cuff algometry (CCA) in
combination with MPA and ThPS measured at the upper extremity:
CCA will be used to measure pain threshold (cPPT), pain tolerance (cPTT), temporal pain
summation (TPS), pain intensity at time of termination (PTS) and conditioned pain modulation
(CPM).
CCA directs the pain intensity by inflation of a tourniquet applied around the lower
extremity. This allows for assessment of deep-tissue pain sensitivity as a stimulus-response
curve. When compared with the pressure algometry it reduces the measurement bias as it is
examiner independent. Likewise, CCA has been tested to be both reliable and sensitive as a
manual pressure algometry.
The procedure of CCA includes a 13-cm wide silicone tourniquet cuff (VBM, Sulz, Germany) with
an equal-sized proximal and distal chamber wrapped around the non-dominant and dominant
gastrocnemius muscle 5 cm inferior to the tuberositas tibia. The cuff pressure is able to
increase with a rate of 1 kPa/s in both chambers, the maximum pressure limit is 80 kPa.
Furthermore, a 200-liter external air tank is attached and provides air to avoid loud noises
from the system during the assessment.
Participants indicate the pain on a computerized electronic Visual analog scale(eVas) ("No
pain" = 0 cm to "Worst pain imaginable" = 10 cm) sampled at a frequency of 10 Hz. The
participants will be instructed to continuously rate the induced pain intensity from initial
pain onset. The pressure at which the stimulus is first described as painful, will be noted
as cPPT. Participants are instructed to terminate the test, by pressing an indicator button,
when the pain becomes intolerable. This resets the cuff and the pressure is noted as cPTT.
The pain intensity at time of termination is the cPTS measure. Next, a series of 4 test
impulses of equal pressure will be applied with 10 second intervals to familiarize
participants with the procedure. Finally, a series of 10 impulses are run with 1 second
intervals, of same pressure intensity in order to measure TPS. All of the above stated will
be measured at the patient's dominant lower leg.
CPM will be measured as the difference between the original cPPT and a new measure during a
continuing pain impulse simultaneously at the non-dominant leg.
Furthermore CPM will be measured using ThPs at the ventral side of the right forearm, both
before and after CPM stimuli from CCA
3.0 Statistics and data analysis 3.1 Power sampling Assuming an alpha-level of 0.05 and a
beta-level of 0.8, a power analysis (t-test) reveals, that a minimum n=62 participants per
group is needed to reveal an expected NRS difference between groups at 1.0 and with a
standard deviation of 1.96. These figures are based on estimates from a previous study on a
similar patient group Thus, for two groups, a maximum of 155 participants is needed, when
factoring in a dropout rate of around 25%.
3.2 Data analysis: The data is continuous and the primary outcome will be analyzed via
regression models. All secondary outcomes will be dichotomized into responders/non-responders
depending on the change in NRS.
In a secondary analysis we will look at "time" and "segment treated" as possible factors that
may contribute to statistical interaction relative to the primary outcome.
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