View clinical trials related to Phantom Limb Pain.
Filter by:Stump and phantom pain after amputation are common, but the responsible mechanisms are still not clarified. It has been suggested that phantom limb pain can be reduced by regional anaesthesia and in several recent studies, pain was reduced following intrathecal and intraforaminal blocks. In this study, the investigators want to investigate if spontaneous and evoked pain in amputees will be relieved by regional nerve blocks involving the damaged nerves.
AIM: To provide initial information on the efficacy (pain reduction) and safety of focused ultrasound surgery for the ablation of stump neuromas in amputees with chronic neuropathic pain. PARTICIPANTS: The study will include 10 amputees (men/women age >18 years old) with chronic (>3 months) phantom/residual limb pain (NPS ≥ 4). DESIGN: Patients potentially qualifying for the study will be offered an Informed Consent to sign prior to further evaluation. Those who accept will sign the informed consent, complete study questionnaires and be evaluated in terms of inclusion/exclusion criteria. Specifically, a complete medical history will be obtained to determine the patient's general health status, current symptoms, frequency and dosage of their current analgesic intake etc. Baseline pain scores will be established. If not performed within six months prior to the evaluation, a contrast MRI of the stump will be performed. Patients not meeting the study criteria will be exited from the study as screen failures and not be included in analyses. All qualifying patients will complete a baseline MRI exam on treatment day. Any patient not meeting study criteria at Imaging will be exited as screen failures. After completion of the MRI exam, qualifying patients will proceed to the ExAblate treatment. These patients will then be followed for 6-months post-ExAblate treatment; the patients will complete study follow-up questionnaires at 1, 3 days, 1 and 2 weeks, and 1, 3 and 6 months after treatments. Follow-up visits will take place 1 week and 1, 3 and 6 months after treatment to assess their pain status, their quality of life and safety. Data regarding dosage and frequency of analgesic intake for the management of post amputation NP will be collected. Relevant cost data will be collected in order to enable an assessment of the total cost of the procedure.
Investigating how neuropathic limb pain, including phantom limb pain or complex regional pain syndrome, is affected by virtual reality. While several studies have looked into virtual reality for treating this type of pain, few have used the latest immersive virtual reality hardware combined with motion control for an engaging virtual mirror therapy experience. The investigators are interested in studying the use of virtual reality as an alternative treatment option for these conditions.
This international, multi-center, double-blind, randomized, controlled clinical trial aims to evaluate the efficacy of Phantom Motor Execution (PME) and Phantom Motor Imagery (PMI) as treatments of Phantom Limb Pain (PLP). In PME, myoelectric pattern recognition (MPR) is used to predict motor volition and then use the decoded movements to control virtual and augmented reality environments (VR/AR), along with serious gaming (SG). The same device and VR/AR environments are used in PMI with the difference that subjects will imagine rather than execute phantom movements. Electromyography is used to monitor for no muscular activity in PMI.
Neuropathic pain is often a result of direct diseases of peripheral or central nervous system with an estimated prevalence of 8% of adults and this pain is associated with significant consequences because of longer symptom duration and severity than many of the other pain syndromes. Functional brain imaging has revealed that many regions of the brain are engaged by painful events, but specific areas such as the thalamus have been markedly implicated. The purpose of this study is to determine the feasibility and safety of MRI-guided focused ultrasound treatment using the ExAblate Transcranial System in patients suffering from Neuropathic pain. This treatment modality offers non-invasive precise treatment potential for these patients.
The goal of this pilot study is to assess the effectiveness of an electrical stimulation therapy option for the treatment of chronic phantom limb pain in upper or lower limb amputees. This therapy has been previously used for sports and joint injuries and is marketed for relaxation of muscle spasms, re-education of muscle action, prevention of disuse atrophy, increased local blood circulation, and maintaining or increasing range of motion. The investigators would like to explore the idea that physically exercising the muscles of the residual limb and increasing blood flow to the site of amputation through the promotion of motor contraction using electrical stimulation decreases chronic phantom limb pain.
Deep brain stimulation (DBS) holds promise as a new option for patients suffering from treatment-resistant chronic pain, but current technology is unable to reliably achieve long-term pain symptom relief. A "one-size-fits-all" approach of continuous, 24/7 brain stimulation has helped patients with some movement disorders, but the key to reducing pain may be the activation of stimulation only when needed, as this may help keep the brain from adapting to stimulation effects. By expanding the technological capabilities of an investigative brain stimulation device, the investigators will enable the delivery of stimulation only when pain signals in the brain are high, and then test whether this more personalized stimulation leads to reliable symptom relief for chronic pain patients over extended periods of time.
The goals of this study are to provide sensory information to amputees and reduce phantom limb pain via electrical stimulation of the lumbar spinal cord and spinal nerves. The spinal nerves convey sensory information from peripheral nerves to higher order centers in the brain. These structures still remain intact after amputation and electrical stimulation of the dorsal spinal nerves in individuals with intact limbs and amputees has been demonstrated to generate paresthetic sensory percepts referred to portions of the distal limb. Further, there is recent evidence that careful modulation of stimulation parameters can convert paresthetic sensations to more naturalistic ones when stimulating peripheral nerves in amputees. However, it is currently unclear whether it is possible to achieve this same conversion when stimulating the spinal nerves, and if those naturalistic sensations can have positive effects on phantom limb pain. As a first step towards those goals, in this study, the investigators will quantify the sensations generated by electrical stimulation of the spinal nerves, study the relationship between stimulation parameters and the quality of those sensations, measure changes in control of a prosthesis with sensory stimulation, and quantify the effects of that stimulation on the perception of the phantom limb and any associated pain.
A randomized controlled clinical to examine the effect of mirror therapy on phantom pain and residual limb pain in patients with traumatic transtibial amputations in Cambodia. The study will be conducted with a semi-crossover design using self-rated pain and function as the main result variables.
Phantom limb pain (PLP) is a frequent consequence of amputation, and it is notoriously difficult to treat. Amputation usually follows traumatic injuries or surgery following vascular diseases, diabetes, osteomyelitis or tumours in cases where the loss of the limb is required for the survival of the patient. The loss of a limb or other body parts is usually followed by the sensation that the lost body part is still present and can be felt. These phenomena are called, respectively, phantom awareness and phantom sensation. In 50-80% of amputees neuropathic pain develops in the lost limb also referred to as phantom limb pain (PLP). PLP can be related to a certain position or movement of the phantom limb, and might be elicited or worsened by a range of physical factors (e.g. changes in the weather or pressure on the residual limb) and psychological factors (e.g. emotional stress). It is well known that most treatments available for PLP today, such as pharmacological, surgical, anaesthetic, psychological and other, are ineffective. Today it is believed that phantom limb pain may be related to changes in the cortex of the brain. There is evidence that these changes may be modulated - or even reversed - by providing sensory input to the stump or amputation zone. For example, cortical reorganization and alleviation of phantom limb pain has been observed in amputees following intense use of a hand prosthesis. However, there is no consistent knowledge on which type of peripheral sensory feedback may be effective in affecting the cortical plasticity or on how to best apply the sensory feedback. The aim of the proposed research is to create natural, meaningful sensations through providing invasive sensory feedback (i.e. electrical stimulation through intraneural implantation of electrodes) and the effectiveness to alleviate phantom limb pain and restore the cortical neuroplastic changes.