Mental Representation Techniques for the Treatment of Parkinson´s Disease-related Pain

Study Description

Brief Summary

Pain is an under-reported but prevalent symptom in Parkinson´s Disease (PD), impacting patients' quality of life. Both pain and PD conditions cause cortical excitability reduction, but mental representations techniques are thought to be able to counteract it, resulting also effective in chronic pain conditions. The investigators of the present project aim to evaluate the efficacy of a novel mental representation protocol in the management of pain in PD patients during the ON state. The investigators hypothesize that Action Observation (AO) and Motor Imagery (MI) training through a Brain-Computer Interface (BCI) using Virtual Reality (AO+MI-BCI) can improve clinical pain and its central processing features.

Detailed Description

Parkinson´s Disease (PD) affects between 4.1 and 4.6 million people in the world. The diagnosis of PD is currently clinical and based on its motor manifestations (bradykinesia, rest tremor, and rigidity). However, non-motor symptoms such as pain, fatigue, and neuropsychiatric manifestations are present in more than 70% of subjects. Pain affects about 85% of patients but is paradoxically under-reported and consequently under-treated in PD patients with a great impact on their quality of life. Levodopa, which is the election treatment in PD, has shown controversial results regarding pain sensitivity and has been shown ineffective for enhancing the endogenous pain modulation system. Furthermore, there is a lack of management protocols and nonpharmacologic treatments for pain in PD. Several syndromes are hypothesized to be involved in PD pain generation. Generally, PD patients suffer from alterations in peripheral transmission, sensitive-discriminative processing, pain perception, and pain interpretation in multiple levels, due to neurodegenerative changes in dopaminergic pathways and non-dopaminergic pain-related structures. Therefore, central mechanisms are proposed to be crucial for the development and establishment of pain in PD patients. Regarding pain processing features, PD patients have reduced pain thresholds, an augmented Temporal Summation (TS) after repetitive nociceptive stimulus, and the impairment of their Conditioned Pain Modulation (CPM) is correlated with greater severity and premature onset of the disease. Cortical excitability reduction is common in patients with pain. Therefore, diverse therapies are being developed to counteract this cortical excitability reduction and obtaining, consequently, effective pain relief. In consonance with these findings, in PD condition, especially in off state, there is also evidence of cortical excitability decrease but, to the best of investigators´ knowledge, there are no studies targeting cortical excitability to treat pain in PD. Thus, the present study proposes mental representation techniques for the treatment of PD-related pain. The mental representation techniques included in the protocol will be Action Observation (AO) and Motor Imagery (MI). The combination of AO and MI has shown to synergically increase cortical excitability, influencing the activation of cortical areas such as M1 and DLPFC. Specifically in PD, AO and MI have also demonstrated to produce corticomotor facilitation. In addition, mental representation training can produce neurophysiological activity similar to actual exercise training, which has shown to decrease the intensity and severity of pain in PD patients. The main aim of this study is to conduct an independent parallel randomized controlled trials based on AO+MI-BCI targeting changes in 1. validated general and specific PD related pain scales and 2. psychophysical measurements of pain modulation mechanisms. The investigators´ main hypothesis is that AO+MI-BCI will be superior to their respective control placebo intervention.

Study Design

Outcome Measures

Primary Outcome Measures

1. Change in King´s Parkinson´s Disease Pain Scale score [From Baseline at 2 weeks]

   Parkinson´s Disease specific scale that evaluates the localization, frequency, and intensity of pain. It has 14 items distributed in 7 domains: 1. Musculoskeletal Pain; 2. Chronic Pain; 3. Fluctuation-related Pain; 4. Nocturnal Pain; 5. Oro-facial Pain; 6. Discoloration, Oedema/Swelling Pain; 7. Radicular Pain. Each item is scored by severity (0, none to 3, very severe) multiplied by frequency (0, never to 4, all the time) resulting in a subscore of 0 to 12, the sum of which gives the total score with a theoretical range from 0 to 168, with higher scores indicating more severity and frequency of pain.

2. Change in King´s Parkinson´s Disease Pain Scale score [From Baseline at 1 month]

   Parkinson´s Disease specific scale that evaluates the localization, frequency, and intensity of pain. It has 14 items distributed in 7 domains: 1. Musculoskeletal Pain; 2. Chronic Pain; 3. Fluctuation-related Pain; 4. Nocturnal Pain; 5. Oro-facial Pain; 6. Discoloration, Oedema/Swelling Pain; 7. Radicular Pain. Each item is scored by severity (0, none to 3, very severe) multiplied by frequency (0, never to 4, all the time) resulting in a subscore of 0 to 12, the sum of which gives the total score with a theoretical range from 0 to 168, with higher scores indicating more severity and frequency of pain.

3. Change in Brief Pain Inventory score [From Baseline at 2 weeks]

   It contains 15 items, including 2 multi-item scales to measure the intensity of pain and its impact on the function and welfare of patients. It also presents open questions to assess the localization of pain and the treatment used for its management, just as its effectiveness. Scores oscillate from 0 to 110, with higher scores indicating more pain and more impact on function and welfare of patients.

4. Change in Brief Pain Inventory score [From Baseline at 1 month]

   It contains 15 items, including 2 multi-item scales to measure the intensity of pain and its impact on the function and welfare of patients. It also presents open questions to assess the localization of pain and the treatment used for its management, just as its effectiveness. Scores oscillate from 0 to 110, with higher scores indicating more pain and more impact on function and welfare of patients.

5. Change in Conditioned Pain Modulation [From Baseline at 2 weeks]

   Assesses the descending pain modulatory system. The Pain Pressure Threshold will be assessed in the middle of the distal phalanx of the thumb with ta handheld algometer, corresponding to the first test stimulus. Afterward, the patient will immerse the contrary hand up to the wrist into stirred ice-cold water (0-4º) maintaining it for 3 minutes, corresponding to the conditioning stimulus. If the pain is unbearable before the 3 minutes, the patient will be able to remove his/her hand. Immediately after removing the hand, a second Pain Pressure Threshold measure will be performed in the same place as the first one, corresponding to the second test stimulus. After 1-minute rest, a third Pain Pressure Threshold will be measured to assess the Conditioned Pain Modulation residual functioning.

6. Change in Conditioned Pain Modulation [From Baseline at 1 month]

   Assesses the descending pain modulatory system. The Pain Pressure Threshold will be assessed in the middle of the distal phalanx of the thumb with ta handheld algometer, corresponding to the first test stimulus. Afterward, the patient will immerse the contrary hand up to the wrist into stirred ice-cold water (0-4º) maintaining it for 3 minutes, corresponding to the conditioning stimulus. If the pain is unbearable before the 3 minutes, the patient will be able to remove his/her hand. Immediately after removing the hand, a second Pain Pressure Threshold measure will be performed in the same place as the first one, corresponding to the second test stimulus. After 1-minute rest, a third Pain Pressure Threshold will be measured to assess the Conditioned Pain Modulation residual functioning.

7. Change in Temporal Summation [From Baseline at 2 weeks]

   Represents excitatory modulation processes. It will be generated through the application of 10 pulses of the handheld pressure algometer over the middle of the distal phalanx of the thumb with the intensity of the Pain Pressure Threshold, previously calculated. In each pulse, pressure intensity will be increasing at a rate of 2 kg/s over the previously determined Pain Pressure Threshold intensity, leaving an interstimulus interval of one second according to the optimal method reported for inducing Temporal Summation with pressure pain. Before the first pressure pulse, subjects were taught to use a verbal numeric pain rating scale to rate the pain intensity of the first, fifth, and 10th pressure pulses. The verbal numeric pain rating scale ranged from 0 ("no pain") to 10 ("the worst possible pain").

8. Change in Temporal Summation [From Baseline at 1 month]

   Represents excitatory modulation processes. It will be generated through the application of 10 pulses of the handheld pressure algometer over the middle of the distal phalanx of the thumb with the intensity of the Pain Pressure Threshold, previously calculated. In each pulse, pressure intensity will be increasing at a rate of 2 kg/s over the previously determined Pain Pressure Threshold intensity, leaving an interstimulus interval of one second according to the optimal method reported for inducing Temporal Summation with pressure pain. Before the first pressure pulse, subjects were taught to use a verbal numeric pain rating scale to rate the pain intensity of the first, fifth, and 10th pressure pulses. The verbal numeric pain rating scale ranged from 0 ("no pain") to 10 ("the worst possible pain").

9. Changes in Pain Pressure Threshold [From Baseline at 2 weeks]

   Two Pain Pressure Thresholds will be measured by a handheld algometer, one over the most painful area (peripheric hyperalgesia) and the other one over the middle of the distal phalanx of the thumb (central hyperalgesia). The Pain Pressure Threshold will be applied with the algometer perpendicular to the skin increasing at a rate of 1 kg/s until the first sensation of pain. 3 measures with 30-seconds rest between them will be performed, taking the average as Pain Pressure Threshold.

10. Changes in Pain Pressure Threshold [From Baseline at 1 month]

    Two Pain Pressure Thresholds will be measured by a handheld algometer, one over the most painful area (peripheric hyperalgesia) and the other one over the middle of the distal phalanx of the thumb (central hyperalgesia). The Pain Pressure Threshold will be applied with the algometer perpendicular to the skin increasing at a rate of 1 kg/s until the first sensation of pain. 3 measures with 30-seconds rest between them will be performed, taking the average as Pain Pressure Threshold.

Secondary Outcome Measures

1. Beck Depression Inventory [Baseline]

   Measures depressive symptoms. Scores range from 0 to 63 leading to 6 groups: 0-10, normal; 11-16, mild mood disturbance; 17-20, borderline clinical depression; 21-30, moderate depression; 31-40, severe depression; and over 40, extreme depression.

2. Beck Depression Inventory [At 2 weeks from Baseline]

   Measures depressive symptoms. Scores range from 0 to 63 leading to 6 groups: 0-10, normal; 11-16, mild mood disturbance; 17-20, borderline clinical depression; 21-30, moderate depression; 31-40, severe depression; and over 40, extreme depression.

3. Beck Depression Inventory [At 1 month from Baseline]

   Measures depressive symptoms. Scores range from 0 to 63 leading to 6 groups: 0-10, normal; 11-16, mild mood disturbance; 17-20, borderline clinical depression; 21-30, moderate depression; 31-40, severe depression; and over 40, extreme depression.

4. State-Trait Anxiety Inventory [Baseline]

   Measures anxious states and anxious traits. It has 20 items for assessing trait anxiety and 20 for state anxiety. All items are rated on a 4-point scale (e.g., from "Almost Never" to "Almost Always"). Higher scores indicate greater anxiety.

5. State-Trait Anxiety Inventory [At 2 weeks from Baseline]

   Measures anxious states and anxious traits. It has 20 items for assessing trait anxiety and 20 for state anxiety. All items are rated on a 4-point scale (e.g., from "Almost Never" to "Almost Always"). Higher scores indicate greater anxiety.

6. State-Trait Anxiety Inventory [At 1 month from Baseline]

   Measures anxious states and anxious traits. It has 20 items for assessing trait anxiety and 20 for state anxiety. All items are rated on a 4-point scale (e.g., from "Almost Never" to "Almost Always"). Higher scores indicate greater anxiety.

7. Tampa Scale of Kinesiophobia [Baseline]

   Measures fear of movement-related pain. Its scores range from 11-44 points with higher scores indicating greater fear of pain, movement, and injury.

8. Tampa Scale of Kinesiophobia [At 2 weeks from Baseline]

   Measures fear of movement-related pain. Its scores range from 11-44 points with higher scores indicating greater fear of pain, movement, and injury.

9. Tampa Scale of Kinesiophobia [At 1 month from Baseline]

   Measures fear of movement-related pain. Its scores range from 11-44 points with higher scores indicating greater fear of pain, movement, and injury.

10. Pain Catastrophizing Scale [Baseline]

    Measures catastrophizing thinking. Its total score range from 0-52, along with three subscale scores assessing rumination, magnification and helplessness, with higher scores indicating higher level of catastrophizing.

11. Pain Catastrophizing Scale [At 2 weeks from Baseline]

    Measures catastrophizing thinking. Its total score range from 0-52, along with three subscale scores assessing rumination, magnification and helplessness, with higher scores indicating higher level of catastrophizing.

12. Pain Catastrophizing Scale [At 1 month from Baseline]

    Measures catastrophizing thinking. Its total score range from 0-52, along with three subscale scores assessing rumination, magnification and helplessness, with higher scores indicating higher level of catastrophizing.

13. Unified Parkinson´s Disease Rating Scale [Baseline]

    Measures disability in Parkinson´s Disease patients. The scale itself has four components: Part I, Mentation, Behavior and Mood; Part II, Activities of Daily Living; Part III, Motor aspects; Part IV, Associated Complications. Scores range from 0 to 159 with higher scores indicating more severity.

14. Unified Parkinson´s Disease Rating Scale [At 2 weeks from Baseline]

    Measures disability in Parkinson´s Disease patients. The scale itself has four components: Part I, Mentation, Behavior and Mood; Part II, Activities of Daily Living; Part III, Motor aspects; Part IV, Associated Complications. Scores range from 0 to 159 with higher scores indicating more severity.

15. Unified Parkinson´s Disease Rating Scale [At 1 month from Baseline]

    Measures disability in Parkinson´s Disease patients. The scale itself has four components: Part I, Mentation, Behavior and Mood; Part II, Activities of Daily Living; Part III, Motor aspects; Part IV, Associated Complications. Scores range from 0 to 159 with higher scores indicating more severity.

16. Reaction Times [Baseline]

    Performed through 2 related subtasks. Finger Taping task, where the participants will be instructed to press the space bar on the keyboard as fast as possible and repeatedly with the index finger, to measure motor function. And Simple Reaction Time task, where participants will be instructed to press the left mouse button as fast as possible when the stimulus "+" appears in the center of the screen at a size of 2 cm x 2 cm, to measure simple perception and sustained alertness.

17. Reaction Times [At 2 weeks from Baseline]

    Performed through 2 related subtasks. Finger Taping task, where the participants will be instructed to press the space bar on the keyboard as fast as possible and repeatedly with the index finger, to measure motor function. And Simple Reaction Time task, where participants will be instructed to press the left mouse button as fast as possible when the stimulus "+" appears in the center of the screen at a size of 2 cm x 2 cm, to measure simple perception and sustained alertness.

18. Reaction Times [At 1 month from Baseline]

    Performed through 2 related subtasks. Finger Taping task, where the participants will be instructed to press the space bar on the keyboard as fast as possible and repeatedly with the index finger, to measure motor function. And Simple Reaction Time task, where participants will be instructed to press the left mouse button as fast as possible when the stimulus "+" appears in the center of the screen at a size of 2 cm x 2 cm, to measure simple perception and sustained alertness.

19. Transcranial Magnetic Stimulation [Baseline]

    Action Motor Threshold in millivolts

20. Transcranial Magnetic Stimulation [At 2 weeks from Baseline]

    Action Motor Threshold in millivolts

21. Transcranial Magnetic Stimulation [At 1 month from Baseline]

    Action Motor Threshold in millivolts

Eligibility Criteria

Criteria

Inclusion Criteria:

• Neuroimaging study without previous pathologies.

• Score > 5 in transfers (bed to chair and back) item in Barthel Index.

• Score = or > 24 in Mini-Mental State Examination.

• Able to provide informed consent to participate in the study.

Exclusion Criteria:

• History of neurologic disease different from PD.

• Presence of non-related to PD pain.

• Dermatologic problems, wounds, or ulcers in the electrode's application area.

• Significative difficulties in language.

• History of alcohol or drugs abuse.

• Non-controlled medical problems.

• Pregnancy.

Contacts and Locations

Locations

Sponsors and Collaborators

• Universidad Francisco de Vitoria
• Hospital Beata María Ana
• Universidad Rey Juan Carlos

Investigators

• Principal Investigator: Juan Pablo Romero Muñoz, MD PhD, Universidad Francisco de Vitoria, Facultad de Ciencias Experimentales
• Principal Investigator: Josue Fernández Carnero, PT PhD, Universidad Rey Juan Carlos

Study Documents (Full-Text)

More Information

Publications

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• Vourvopoulos A, Ferreira A, Bermúdez i Badia S. NeuRow: An Immersive VR Environment for Motor-Imagery Training with the Use of Brain-Computer Interfaces and Vibrotactile Feedback. 2016.
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• Wright DJ, Williams J, Holmes PS. Combined action observation and imagery facilitates corticospinal excitability. Front Hum Neurosci. 2014 Nov 27;8:951. doi: 10.3389/fnhum.2014.00951. eCollection 2014.