Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT05068908 |
| Other study ID # |
DENT-2020-29282 |
| Secondary ID |
|
| Status |
Recruiting |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
March 2, 2022 |
| Est. completion date |
August 2024 |
Study information
| Verified date |
April 2024 |
| Source |
University of Minnesota |
| Contact |
Estephan J Moana-Filho, DDS, MS, PhD |
| Phone |
(612) 624-3338 |
| Email |
brainsensestudy[@]umn.edu |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
This study addresses the timely problem of painful temporomandibular disorders (TMD), the
most common cause of orofacial pain second only to tooth pain. Findings from previous studies
suggest that dysregulation of connectivity within specific brain circuits is part of chronic
pain pathophysiology. This study will identify connectivity patterns within those brain
circuits as potential signatures for pain- related disability in chronic TMD pain
participants. New knowledge regarding these brain connectivity patterns is expected to be
significant because it will support improved phenotyping of this heterogeneous participant
population. It is also expected that this finding can potentially be extrapolated to other
chronic pain conditions, such as back pain, migraine headache, and fibromyalgia that are
frequently comorbid conditions in chronic TMD participants.
Description:
Evidence of dysregulation of brain circuits in chronic pain in general and in chronic
temporomandibular disorder (TMD) pain specifically is well documented. Among putative brain
circuits involved in chronic pain pathophysiology are thalamocortical brain pathways, which
transmit nociceptive signals centrally from peripheral tissues. Pathways between the medial
prefrontal cortex (mPFC) and the periaqueductal gray (PAG) are considered part of an
antinociceptive brain circuit, since they are necessary to engage endogenous pain modulation.
Dysfunction of endogenous pain modulation has been systematically reported in chronic pain
patients, and a meta-analysis of clinical studies of TMD patients done by the Principal
investigator and others showed increased pain facilitation and impaired pain inhibition in
patients relative to pain-free controls.
Endogenous pain modulation can be assessed by psychophysical methods. For instance, pain
facilitation can be assessed with temporal summation of pain (TSP) using brief noxious
stimuli presented repeatedly over peripheral tissues at >0.3 Hz. Pain inhibition can be
assessed with conditioned pain modulation (CPM) by presenting noxious stimuli over a body
site during concurrent noxious stimuli elsewhere to induce pain inhibition. Neuroimaging
studies in pain-free controls showed that functional connectivity within thalamocortical and
antinociceptive brain circuits are related to increased TSP and reduced CPM responses,
respectively. It is unknown if connectivity patterns within the thalamocortical and
antinociceptive brain circuits are altered in chronic TMD patients, reflecting endogenous
pain modulation dysfunction. Corticolimbic pathways connecting the mPFC, amygdala and nucleus
accumbens are thought to play a key role in chronic pain and specifically, in emotion-driven
modulation of nociceptive signals. Recently a longitudinal study showed that functional and
structural connectivity patterns determined from neuroimaging data between these regions
predict transition from acute to chronic back pain. A population study of TMD pain patients
showed that approximately 64% of these patients also present with comorbid low back pain,
thus it is possible that chronic TMD pain patients may display brain connectivity patterns
that are similar to those identified in persistent back pain patients.
Functional brain connectivity is usually assessed from resting-state functional magnetic
resonance imaging (fMRI), where participants lay at rest during fMRI scans to measure
intrinsic functional connectivity (FC). Connectivity patterns within the thalamocortical,
corticolimbic and antinociceptive circuits described above were determined using this
traditional approach for FC assessment. Recent studies departed from this traditional
approach and assessed FC during presentation of noxious stimuli during fMRI data acquisition
and identified evoked FC changes. These studies' results suggest that noxious stimuli affect
connectivity patterns in brain circuits involved in pain processing in pain-free participants
and in fibromyalgia patients. Thus, it is reasonable that psychophysical testing for pain
facilitation (e.g., TSP) and pain inhibition (e.g., CPM) could reflect changes in
connectivity patterns within brain circuits associated with pain modulation. If confirmed,
these evoked connectivity patterns identified from engaging endogenous pain modulation could
serve as a "signature" for pain modulation in individuals, similar to a "functional
connectome fingerprinting" demonstrated to predict fluid intelligence in healthy participants
using data from the Human Connectome Project (HCP).
Taken together these results suggest new approaches to investigate dysregulation of brain
circuits in chronic TMD pain with a focus on brain connectivity, that can serve as unique
chronic pain "signatures" related to endogenous pain modulation function. There is a critical
need to determine the potential of brain circuits' connectivity patterns to serve as
signatures for pain- related disability. Addressing this critical need will provide novel
ways to identify subgroups of chronic TMD pain patients who respond poorly to treatment.
Closing this gap in our knowledge has reasonable potential to provide the opportunity for
development of precise and valid brain imaging methods supporting refined phenotyping of
chronic TMD pain patients leading to early identification of patients with poor prognosis.
Chronic pain causes suffering to more Americans than heart disease, diabetes and cancer
combined, and TMD is the second most commonly occurring musculoskeletal condition resulting
in pain and disability after chronic back pain. TMD affects approximately 5-12% of the
population, with annual estimates of economic impact ranging between $4 billion per the NIDCR
and $32 billion according to a study sponsored by the Agency for Healthcare Research and
Quality . Pain-related disability significantly impacts patient's quality of life, and a
subgroup of chronic TMD pain patients present with high pain-related disability, as
identified by the Graded Chronic Pain Scale (GCPS), and these patients have poor prognoses -
even with treatment - and greater health care costs.
About half to two-thirds of individuals with TMD seek treatment, and of those approximately
15% will develop chronic pain. Chronic TMD pain patients present with pain persisting ≥6
months, and it is well accepted that chronic TMD pain pathophysiology includes dysregulation
of brain circuits. Recent evidence suggests that brain functional and anatomical
characteristics, namely connectivity patterns within specific brain circuits, are related to
processing, modulation and persistence of pain. Brain connectivity patterns within the
thalamocortical circuit are associated with expression of endogenous pain facilitation, while
connectivity patterns between prefrontal cortex and brainstem nuclei, an antinociceptive
circuit, are related to endogenous pain inhibition. In addition, brain connectivity patterns
within corticolimbic pathways involved in the emotion-driven modulation of nociceptive
signals predict transition from acute to chronic back pain. These connectivity patterns
within thalamocortical, antinociceptive, and corticolimbic brain circuits have not been
described in chronic TMD patients, and it is unknown if connectivity patterns within these
brain circuits can distinguish chronic TMD patients based on pain-related disability.
