10 Clinical Trials for Various Conditions
Shoulder pain is extremely common after stroke and occurs in 30-70% of patients. The pain may begin as early as one week after stroke, although peak onset and severity occurs around four months, and persists into the chronic stage. Chronic post stroke shoulder pain (PSSP) interferes with motor recovery, decreases quality of life, and contributes to depression. PSSP is thought to be caused mainly by damage to the myofascial tissues around the shoulder joint. Interestingly, an MRI study in patients with PSSP showed that the degree of structural damage to the muscles did not correlate with the degree of pain. Thus, the pathophysiology of myofascial dysfunction and pain in PSSP has not been elucidated leading to missed opportunities for early diagnosis and variable success with pain management. The accumulation of hyaluronic acid (HA) in muscle and its fascia can cause myofascial dysfunction. HA is a glycosaminoglycan (GAG) consisting of long-chain polymers of disaccharide units of glucuronic acid and N-acetylglucosamine and is a chief constituent of the extracellular matrix of muscle. In physiologic quantities, HA functions as a lubricant and a viscoelastic shock absorber, enabling force transmission during contraction and stretch. Reduced joint mobility and spasticity result in focal accumulation and alteration of HA in muscle. This can lead to the development of stiff areas and taut bands, dysfunctional gliding of deep fascia and muscle layers, reduced range of motion (ROM), and pain. However, the association of muscle HA accumulation with PSSP has not been established. The investigators have quantified the concentration of HA in muscle using T1rho (T1ρ) MRI and found that T1ρ relaxation time is increased in post stroke shoulder pain and stiffness. Furthermore, dynamic US imaging using shear strain mapping can quantify dysfunctional gliding of muscle that may generate pain during ROM. Myofascial dysfunction can result in non-painful reduction in ROM (latent PSSP), which may become painful due to episodic overuse injury producing greater shear dysfunction (active PSSP). Hence, shear strain mapping may differentiate between latent versus active PSSP. Thus, quantitative Motor Recovery (MR) and US imaging may serve as useful biomarkers to elucidate the pathophysiology of myofascial dysfunction.
The purpose of this study is to quantify the extent of GlycosAminoGlycan/Hyaluronic Acid (GAG/HA) accumulation using T1rho (T1ρ) MRI in the paretic versus non-paretic shoulder rotator muscles, and correlate the T1ρ Magnetic Resonance Imaging (MRI) measurements with US echo texture measurements to develop a clinic-friendly tool to infer the extent of HA accumulation; and to distinguish between latent versus active Post Stroke Shoulder Pain (PSSP) using ultrasound (US) shear strain mapping of the same muscles on the paretic side compared with the non-paretic side.
Brief Summary: The goal of this clinical trial is to determine the efficacy of myofascial release in altering the parameters of muscle tone, stiffness, and viscoelasticity in young adults. The main questions it aims to answer are: What is the efficacy of myofascial release in altering muscle tone, stiffness, and viscoelasticity? What is the efficacy of light hands-on sham as a control? Are there differences in these parameters between men and women? What is the reliability of MyotonPro use in young adults? Researchers will randomly allocate and compare the treatment group, which receives osteopathic manipulative medicine (OMM) in the form of 30 seconds of indirect myofascial release followed by 30 seconds of direct myofascial release, to the control group, which receives 1 minute of light hands-on traps placebo, to see if there are differences in muscle tone, stiffness, and viscoelasticity.
This study will examine pelvic pain associated with endometriosis and explore better approaches to treatment. In women with endometriosis, uterine tissue grows outside the uterus. Standard treatments - altering hormone levels to prevent endometrial tissue growth or surgically removing endometrial tissue - treat pelvic pain only temporarily. This study will investigate the role of sex hormones, immune chemicals, stress hormones, and genes in pelvic pain and determine how the nerve, muscle, and skeletal systems are involved in this pain. Women between 18 and 50 years of age who: 1. have endometriosis and chronic pelvic pain, and 2. have chronic pelvic pain without endometriosis, and 3. have neither endometriosis nor chronic pelvic pain and are willing to have a tubal ligation (Healthy Volunteer group), may be eligible for this study. Candidates are screened with a questionnaire to obtain information about their pain and previous treatments and related medical or social issues. Participants will undergo the following tests and procedures: 1. Medical history and physical examination, including pelvic exam, blood tests, urinalysis, and diaphragm fitting. 2. Questionnaires about pain, quality of life, sexuality, psychological attitudes, spiritual experiences, and history of headache and depression. 3. At-home monitoring for 4 to 6 weeks of pain symptoms, menstruation and spotting, medicines taken, and urine collections to test for "LH" surge. LH is the hormone that causes the ovary to release a mature egg. 4. Pre-laparoscopy evaluation to include: * Examination of menstrual blood collected in a diaphragm for 4 hours. * Blood sampling to measure adrenal and pituitary hormones. For this test, corticotrophin-releasing hormone (CRH) is injected through an IV needle. Up to five blood samples are drawn, starting before the injection until 45 minutes after it. Blood is also collected at this time for genetic analysis. * In-depth pain assessment to identify trigger points in muscles associated with pelvic pain, regions of skin sensitivity, and bone pain. Some women will undergo microdialysis, which uses an acupuncture-type needle to collect chemicals from two different muscles. * Blood sampling twice a week for 1 month to measure changes in blood substances during the menstrual cycle. * Blood sampling after the LH surge to measure progesterone levels. * Cervicovaginal lavage (washing of the cervix with saline and collecting the fluid) to obtain secretions for research. * Ultrasound of the ovaries and uterus. This examination uses a probe inserted into the vagina that emits sound waves that are used to form pictures of the internal structures. A small piece of uterine lining is also obtained for examination and research purposes. * A visit with the members of the Pain and Palliative care service to evaluate the pain in anticipation of offering other treatments for pain after surgery. * Surgery: CPP + Endo or CPP only: Laparoscopy to look for and remove endometrial tissue. This procedure is done under general anesthetic. A viewing instrument called a laparoscope is passed through an incision in the belly button to look for endometriosis. If it is found, two or more incisions are made in the abdomen for other instruments to remove the tissue. A small piece of uterine lining is also obtained for examination and research purposes. Healthy Volunteers: Laparoscopy to perform the tubal ligation. A tubal ligation, commonly known as "getting your tubes tied," is a surgical procedure for women to sterilize them. This procedure closes the fallopian tubes, stopping the egg from traveling from the ovary to the uterus and preventing sperm from reaching the fallopian tube to fertilize an egg. In a tubal ligation, fallopian tubes are cut, burned, or blocked with rings, bands or clips. The surgery is effective immediately. Tubal ligations are 99.5% effective as birth control. This procedure is done under general anesthetic. A viewing instrument called a laparoscope is passed through an incision in the belly button to perform a tubal ligation. Two or more incisions are made in the abdomen for other instruments to perform the procedure. During the laparoscopy, we will look for and remove endometrial tissue. A small piece of uterine lining is also obtained for examination and research purposes. -Follow-up evaluations. Two weeks after surgery, patients return to NIH to discuss the surgical findings and treatment options. Follow-up visits are then scheduled at 1, 3, and 6 months after surgery to complete questionnaires and determine if the treatment is working. Blood samples are drawn at each visit....
Hypothesis: Myofascial temporomandibular joint disorder and related symptoms are associated with mandibular condyle and temporal fossa overloading secondary to temporalis and masseter muscle hyperactivity and spasm This study will examine the use of onabotulinumtoxinA (Botox) to treat myofascial pain disorder in patients with bruxism who frequently exhibit signs of temporomandibular joint disorder (TMD) in a double blind cross-over randomized clinical trial by injecting 50 units Botox in temporalis and masseter muscles in 32 patients with 6 months follow up. The objective of the proposed study will be to establish the safety and efficacy of botox in treating TMD associated with bruxism. By the time patients reach the specialists office, most have failed maximal conservative therapies, including non-chew diet, night guard, oral analgesics, muscle relaxants, physical therapy, and a portion have even undergone more invasive procedures, such as manipulation under anesthesia, arthroscopy, and arthroplasty surgeries with limited improvement or recurrence. Primary outcome of the study will be 50% reduction in pain. Secondary outcomes will be 50% reduction in surgical therapy, 25% increase in maximal inter-incisal opening (MIO). The investigators look forward to working with you on the proposed study
Temporomandibular Disorder (TMD) is a widespread chronic pain condition. Successful psychosocial treatments for TMD have been developed, but the mechanisms by which these treatments achieve their effects are not well known. The goal of this project is to evaluate the possible mechanisms responsible for treatment gains in TMD treatment.
Participants will be 18-59 years old who are recruited through a convenience sample from the UMHB/Belton community. There will be a randomized control trial consisting of three groups. Each participant will be assigned based on their order of entry to the study group assignment and then randomly organized via computer generation into 3 groups of 20 participants including a control group, a dry needling group (DN), and a dry needling E-stim group (DN-ES), resulting in approximately 60 total participants. Participants in the DN and DN-ES groups will be treated four times; at weeks 0, 2, 4 and 6 of the study. Data will be collected at weeks 4, 6 and 12 in all groups.
This study will use microdialysis to investigate myofascial pain. This pain is characterized by "trigger points" (exquisitely tender spots) in a group of tense muscle fibers that extend from the trigger point to the muscle attachments. Trigger points in the trapezius, a large muscle lying between the neck and shoulder, are typically caused by emotional stress, postures such as hunching shoulders, certain activities like using a telephone receiver without elbow support, or by wearing certain articles such as a heavy coat or heavy purse. Microdialysis uses a very thin needle probe (about the size and shape of an acupuncture needle) to collect and measure chemicals directly from soft tissue. Analysis of these chemicals will show whether changes in the tissue around a muscle with trigger points are confined to that muscle, or if these changes also occur in more distant muscles. The study will examine two types of trigger points. An "active" trigger point causes pain or other abnormal symptoms and often causes problems with movement. A "latent" trigger point often causes movement problems without causing pain. Many healthy adults have latent trigger points. People between 21 and 65 years of age with the following characteristics may be eligible for this study: 1) no neck pain or trigger points in either upper trapezius muscle; 2) no neck pain but a latent trigger point in at least one upper trapezius muscle; or 3) neck pain of less than 3 months' duration and an active trigger point in at least one upper trapezius muscle. Participants undergo the following procedures: * Physical examination of the muscles of the neck and shoulder area, testing strength and range of motion, and response to palpation to find trigger points. * Pain inventory. Subjects complete a questionnaire for measuring pain and its intensity, location, quality, causes, relievers, and associated symptoms. The questionnaire is filled in before and after each microdialysis procedure. * Microdialysis in upper trapezius muscle. An electrode patch is placed on either side of the site for insertion of the microdialysis probe and another electrode is placed on the outer edge of the shoulder. The electrodes are used to measure any electrical activity that occurs with insertion or movement of the probe. The subject lies face down and the probe is inserted in the upper trapezius muscle. It remains in place for 5 minutes while chemical substances are collected from the muscle. It is then advanced about 1.5 cm deeper into the muscle until a twitch response is obtained and remains in place for 10 more minutes while substances are collected. * Microdialysis in the gastrocnemius muscle (large muscle of the calf). The same procedure for the upper trapezius muscle is done in the calf muscle.
Evaluate erenumab- aooe efficacy as a therapeutic approach, for the management of painful chronic temporomandibular disorders (TMD). The study will be a randomized, double blind, placebo-controlled trial comparing erenumab-aooe vs Placebo. A total of 60 patients (30 per each arm) aged 18-65 years old of either sex, and any race or ethnicity presenting chronic temporomandibular disorders (TMD), (meeting the Diagnostic Criteria for Temporomandibular Disorders (DC/TMD) for Clinical and Research Applications of chronic TMD (myalgia +/- arthralgia) will be randomly assigned in a 1:1 parallel, double-blind clinical trial, to receive either erenumab-aooe or placebo. Participants will attend 6 clinic visits (Visit 0-Visit 5) over a period of 21 weeks (20 +/- 1 weeks). Changes in pain intensity and other pain outcomes related to TMD will be assessed. Blood samples will be collected, and participants will need to keep a daily symptom diary and answer some other questionnaires.
The goal of this clinical trial is to learn if Autonomic Recalibration works to reduce sympathetic dominance to alleviate dysfunctional myofascial pain. The main questions it aims to answer are: How is the Autonomic Nervous System (ANS) affected during Autonomic Recalibration Treatment (ART)? How are myofascial tissue properties impacted from ART? Participants will: Have 2 treatments of ART on consecutive days. Wear sensors to track HRV (heart rate variability) and GSR to verify autonomic recalibration. Measure changes in range of motion by wearing a Rokoko motion capture suit. Measure changes in muscle stiffness through shear wave elastography.