Trials / Unknown
UnknownNCT04742790
QSPainRelief-patientCNS : Clinical Biomarkers of Nociception, Sedation and Cognition
Clinical Calibration and Evaluation of the QSPainRelief Platform in Patients With Disabling Pain Using Functional Biomarkers of Nociception, Sedation and Cognition
- Status
- Unknown
- Phase
- N/A
- Study type
- Interventional
- Enrollment
- 180 (estimated)
- Sponsor
- Université Catholique de Louvain · Academic / Other
- Sex
- All
- Age
- 18 Years – 75 Years
- Healthy volunteers
- Not accepted
Summary
QSPainRelief-patientCNS is a monocentric prospective longitudinal study conducted in patients suffering from disabling post-surgical pain for which the treating physician is about to prescribe a given drug combination for the treatment of their pain with the aim of identifying measures of drug-induced effects on CNS activity that could be used as biomarkers of real-life clinical outcome, both in terms of desired treatment effects (treatment-induced pain relief) but also in terms of undesired treatment effects (treatment-induced sedation and treatment-induced cognitive dysfunction).
Detailed description
QSPainRelief-patientCNS is one of three clinical studies that will be conducted as part of the QSPainRelief project funded by the European Union's Horizon 2020 research and innovation program (grant agreement 848068; http://qspainrelief.eu). Chronic pain is a complex disease affecting about 20% of Europeans, and up to 60% of patients with chronic pain do not experience adequate pain relief from currently available analgesic combinational therapies and/or suffer confounding adverse effects. Of the many conceivable combinations, only a few have been studied in formal clinical trials. Thus, physicians have to rely on clinical experience when treating chronic pain patients. The vision of the QSPainRelief project is that alternative novel drug combinations with improved analgesic and reduced adverse effects can be identified and assessed by mechanism-based Quantitative Systems Pharmacology (QSP) in silico modelling. The QSPainRelief consortium will setup, calibrate and validate an in silico QSPainRelief platform which integrates recently developed (1) physiologically based pharmacokinetic models to quantitate and adequately predict drug pharmacokinetics in human CNS, (2) target-binding kinetic models; (3) cellular signaling models and (4) a proprietary neural circuit model to quantitate the drug effects on the activity of relevant brain neuronal networks, that also adequately predicts clinical outcome. Calibration of the QSPainRelief platform modelling the biological processes and neuronal circuits underlying the pain relief and adverse effects induced by drug combinations requires patient data on how different drug combinations affect the central processing of nociceptive input, the central processes underlying pain modulation, as well as the central nervous system (CNS) networks underlying drug-induced adverse effects. After calibration of the QSPainRelief platform, additional patient data is required to evaluate the ability of the platform to actually predict CNS effects of drug combinations in patients. Finally, real-world evidence is needed to relate the effects of drug combinations on CNS activity with the therapeutic and adverse effects self-reported by the patients. The aims of the QSPainRelief-patientCNS study are thus two-fold. The first aim is to obtain data from a first set of 60 patients to calibrate the QSPainRelief platform, and from a second set of 120 patients to evaluate the ability of the QSPainRelief platform to predict therapeutic and adverse effects of drug combinations. It will focus on pain relief and its impact on daily life activities as therapeutic effects, and on drug-induced sedation, drug-induced cognitive dysfunction (memory and attention) and pain medication misuse as adverse effects. These adverse effects have been chosen because (1) CNS biomarkers sensitive to drug-induced sedation and drug-induced cognitive dysfunction can be readily obtained using non-invasive measurements of the electroencephalogram (EEG) and (2) the chosen adverse effects can be assessed in patients after a short treatment period using validated patient-reported outcome measures (PROMs). The second aim is to identify measures of drug-induced effects on CNS activity that could be used as biomarkers of real-life clinical outcome, both in terms of desired treatment effects (treatment-induced pain relief) but also in terms of undesired treatment effects (treatment-induced sedation and treatment-induced cognitive dysfunction).
Conditions
Interventions
| Type | Name | Description |
|---|---|---|
| DIAGNOSTIC_TEST | Scalp electroencephalography (EEG) | Resting EEG will be recorded before initiation of the combination treatment (visit 1) and 7-10 days after treatment (visit 2). Drug-induced sedation-related changes in the EEG frequency spectrum. Five minutes of resting EEG eyes-open will be recorded in a quiet room while participants are asked to focus on an image displayed on a wall. Then, they will be asked to close their eyes for an additional 2 minutes. The alpha power ratio eyes open/eyes closed will be computed (alpha attenuation coefficient; Kaida et al., 2006). Changes in this coefficient will be used as a measure of drug-induced sedation. |
| DIAGNOSTIC_TEST | Laser-evoked potentials (LEPs) | Laser-evoked potentials (LEPs) will be recorded before (visit 1) and 7-10 after (visit 2) initiating the combination treatment. Short pulses (50-100 ms) of radiant heat generated by a C02 laser stimulator will be applied to the skin of the left or right hand dorm to briefly and selectively activate heat-sensitive pain receptors. A concomitant EEG recordings will be used to measure the amplitude and latency of the elicited laser-evoked potentials. Changes in LEP amplitude (expressed as percentage of change) will be used as a measure of drug-induced effects on the state of the thermonociceptive system. |
| DIAGNOSTIC_TEST | Cognitive auditory-evoked potentials (P300) | Cognitive auditory-evoked potentials will be recorded before (visit 1) and 7-10 after (visit 2) initiating the combination treatment. Short-lasting auditory tones will be delivered using a three-stimulus oddball paradigm combining standard tones (90% of stimuli), slightly different target tones that the subject must attend and detect (10% of stimuli), and strongly different distractor non-target tones (10% of stimuli). The stimuli will be delivered binaurally using headphones. Participants will be instructed to press a button when they detect a target tone, and to ignore the standard and distractor non-target tones. The EEG recordings will be used to measure the amplitude and latency of the cognitive P3a and P3b potentials (Komerchero \& Polich 1999). Changes in P3a/P3b amplitude will be used as a measure of drug-induced effects on cognition (expressed as percentage of change). |
| DIAGNOSTIC_TEST | Cervical somatosensory-evoked potentials | Cervical spinal-cord evoked potentials will be recorded before (visit 1) and 7-10 after (visit 2) initiating the combination treatment. The responses will be elicited by transcutaneous electrical stimulation of the median nerve. The N13 component of this response is mediated by large myelinated non-nociceptive fibers and reflects a segmental postsynaptic response of dorsal horn interneurons at the level of lumbar spinal cord (Cruccu et al., 2008). Changes in magnitude of the N13 will be used as a measure of drug-induced effects on spinal cord function (expressed as percentage of change). |
| DIAGNOSTIC_TEST | Pupillometry | Pupillometry measurements will be performed before (visit 1) and 7-10 after (visit 2) initiating the combination treatment. Pupillometry has been proposed as a method to assess opioid pharmacodynamics. The extent of pupil dilatation can provide an index of nociceptive input via autonomic innervation of the iris muscles, while the extent of the attenuation of this pupillary response during exposure to opioid analgesics could provide an index of pharmacological effects reflecting the extent of opioid receptor occupancy in the CNS. Pupillometry (static pupil diameter, variability of pupil diameter \[variation coefficient of pupillary dilation, VCPD, Charier et al. 2017\]), light-evoked speed of pupil constriction \[maximum pupil constriction velocity, PCV, Connely et al., 2014\]) will be measured using a handheld pupillometry device routinely used for clinical evaluations. |
| DIAGNOSTIC_TEST | Saccadic Peak Velocity | The saccadic peak velocity (SPV; m/s) will be measured before before (visit 1) and 7-10 after (visit 2) initiating the combination treatment. Saccadic peak velocity is one of the most sensitive parameters for sedation. Recording of eye movements will be performed in a quiet room with dimmed lightning. Average values of saccadic peak velocity (expressed as degrees/second) of all correct saccades will be measured. |
| DIAGNOSTIC_TEST | Adaptive tracking test | The test will be performed before (visit 1) and 7-10 after (visit 2) initiating the combination treatment. Adaptive tracking is a pursuit-tracking task sensitive to impairment of eye-hand coordination by drugs. It has been proven useful for measuring CNS effects of alcohol, various other psychoactive drugs, and sleep deprivation. |
| DIAGNOSTIC_TEST | Body Sway Test | Body sway will be assessed before (visit 1) and 7-10 after (visit 2) initiating the combination treatment, using a body sway meter and with eyes closed. The body sway meter allows measurement of body movements in a single plane, providing a measure of postural stability. The method has been used to demonstrate effects of sleep deprivation, ethanol and psychoactive drugs. All body movements over a 2-min period are integrated and expressed as millimeters of sway. |
| DIAGNOSTIC_TEST | N-back working memory test | Working memory performance will be assessed before (visit 1) and 7-10 after (visit 2) initiating the combination treatment. In this test, a series of letters are shown to the participant on a computer screen. The test includes three conditions with increased working memory load. The "0-back" condition simply requires to indicate whether the presented letter is the letter "X" or another letter. In the "1-back" condition, participants are requested to indicate whether the displayed letter is identical to the preceding letter. In the "2-back" condition, participants are required indicate whether the letter is repeated with one other letter in between (e.g., B … C … B). |
| OTHER | Patient-reported outcomes | Before (visit 1) and 7-10 after (visit 2) initiating the combination treatment, but also daily between the two visits, 14 days, 1 month, 3 months and 6 months after treatment initiation, patient-reported outcomes will be collected to assess clinical effects and side-effects of the combination treatmen These include the short form of the Brief Pain Inventory (BPI), the PROMIS PQ-NEURO score for neuropathic pain, the Stanford Sleepiness Scale (SSS), and the PROMIS Neuro-QOL self-assessment of cognitive functioning. |
Timeline
- Start date
- 2021-03-15
- Primary completion
- 2024-09-30
- Completion
- 2024-09-30
- First posted
- 2021-02-08
- Last updated
- 2021-02-08
Locations
1 site across 1 country: Belgium
Source: ClinicalTrials.gov record NCT04742790. Inclusion in this directory is not an endorsement.