7 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.
StimRouter Neuromodulation System includes an implanted lead which provides peripheral nerve stimulation for chronic pain. Post-stroke shoulder pain patients will be the focus of this study. After meeting inclusion/exclusion criteria, approximately 50 enrolled patients will participate in the study through 6 months of follow-up. Various measures will be used to assess patient response to use of the device.
The purpose of this study is to determine if electrical stimulation (small levels of electricity) reduces post-stroke shoulder pain. This study involves a device called the Smartpatch System. The Smartpatch System delivers mild electrical stimulation to the muscles in the shoulder. The Smartpatch System includes a small wire (called a "Lead") that is placed through the skin into the muscle of the shoulder. It also includes a device worn on the body that delivers stimulation (called the Smartpatch Stimulator).
Post-stroke shoulder pain is defined as pain in the shoulder area that starts after a person has had a stroke. The SPR System is an investigational device that is being studied for the relief of post-stroke shoulder pain. The SPR System uses electrical stimulation and includes a Trial Stage (where a temporary system is used to see if the subject may benefit from this type of therapy) and may include an Implant Stage (where a small device is implanted under the skin in the chest). The SPR System delivers mild electrical stimulation to the shoulder where the subject feels pain. This research study will evaluate the effect of electrical stimulation on shoulder pain. Individuals who are over the age of 21, who had a stroke at least six months ago, who experience shoulder pain, and have tried other therapies for their shoulder pain, may be eligible to participate in the first stage of the SPR System. Subjects meeting the specified success criteria at the conclusion of the SPR Trial Stage who experience a return of pain within 6 months of completion of the Trial Stage may be eligible for the second stage (SPR Implant Stage). This research study lasts a little over 3 years and may include 17 visits to the study doctor and at least 8 telephone calls from study staff.
The purpose of this study is to evaluate whether botulinum toxin type A injected into muscles around the shoulder is effective in treating shoulder pain and improving function in patients with shoulder pain and involuntary muscle tightness after a stroke.
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.
The goal of this research study is to investigate safety and gather initial effectiveness data for a new implanted device designed to treat chronic shoulder pain in chronic post-stroke subjects. The BBPM weighs less than 0.03 ounces and measures 1" x 0.1". It is implanted into the shoulder to stimulate the axillary nerve. Stimulation of this nerve may reduce shoulder pain, reduce shoulder subluxation, improve motion, improve function, and possibly decrease use of pain medication. CAUTION--Investigational device. Limited by Federal law to investigational use.