View clinical trials related to Sciatic Nerve.
Filter by:Low back pain (LBP) is a common symptom that can be a health problem in worldwide. Studies have shown that 70% to 80% of all people are affected at least once in their lives. Although it is common, the cause of the pain has often not been determined and is referred to as non-specific LBP. The lumbar range of motion decreases, trunk flexion is limited, postural control and muscular stiffness are affected in individuals with LBP. Recent studies have shown that people with LBP have altered nerve properties in the sciatic nerve. It was observed that the cross-sectional area of the sciatic nerve decreased and its stiffness increased. Peripheral nerve tissues are faced with great tension and compressive forces that occur in daily life activities and sports activities. To maintain the normal function of the nervous system, it must have the ability to resistance to tension, easy to slide in the environment it is in and withstand compressive forces. In case of not being able to resist the pressure exerted by surrounding tissues such as bone, tendon, muscle, fascia, there may be distortions in the shapes of neural structures. Neuromobilization, one of the manual therapy techniques, is used in impingement syndromes of peripheral nerves and neuropathies. Neuromobilization aims to regain the normal mechanical properties of the nerve by using limb movements, motion and position of the joint. There are two methods of neuromobilization techniques; sliding and tension. Sliding involves combinations of movements that lengthen the nerve bed in one joint and reduce the length of the nerve bed in the next joint, while tension is done by stretching both ends of the nerve bed. Neuromobilization structures the balance between the relative movements of the neural tissues and the surrounding mechanical interface, allows the reduction of internal pressure in the neural tissue, and thus optimum physiological functions are regulated. The mechanism of action of neuromobilization is thought to be to increase intraneural circulation, improve axoplasmic flow and connective tissue viscoelasticity, and reduce hypersensitive areas. Neuromobilization techniques are extensively used in clinical settings during the therapy of patients with sciatica, with favorable effects on pain and impairment. However, the mechanical implications of neuromobilization in human nerves are poorly understood. Two investigations that used SWE to measure sciatic nerve stiffness in healthy adults following prolonged slump positions came up with conflicting conclusions. It has been determined that there are different opinions on the effects of slump neuromobilizations in sciatic nerves. Considering that slump neuromobilization techniques are frequently used for therapeutic, it should be appropriate to determine their effects on the sciatic nerve.
The purpose of this research study is to see if there is a relationship between the tightness of the hamstring muscles (muscles on the back of the thighs), reported sensations related to stretch of the nerves of the lower extremity, and different positions of participants' backs. We will investigate the qualitative differences as provided verbally by participants (sensation felt at maximum knee extension angle) and quantitative differences as provided by surface electromyographic (EMG) measurements of hamstring activity and inclinometer measures of the knee angle.
The project consists of studying the differences between neural gliding techniques of the sciatic nerve and passive stretching of the hamstring muscles in football players.
In modern anesthesiology, peripheral nerve blocks are performed using ultrasound control and electrical stimulation of peripheral nerves (PEN), or only ultrasound control or only EPN. The most effective methods are with the use of ultrasound control. Until now, the effectiveness of the sciatic nerve blockade by the subgluteal approach, performed only under ultrasound control without EPN, in comparison with the blockade of the sciatic nerve performed under ultrasound control with EPN, has not been established. There is no data on how the effectiveness of the blockade of the sciatic nerve with small doses of lidocaine is influenced by the method of performing the blockade: under ultrasound control versus ultrasound control with electrostimulation of the nerve. Research hypothesis: the blockade of the sciatic nerve by the subgluteal approach (12.5 ml 1%lidocaine -Minimum Effective Dose - previously established ) performed only under ultrasound control has the same effectiveness as the blockade performed under the ultrasound control with EPN.
In modern anesthesiology, peripheral nerve blocks are performed using ultrasound control and electrical stimulation of peripheral nerves (PEN), or only ultrasound control or only PEN. The most effective methods are with the use of ultrasound control. Until now, the effectiveness of the sciatic nerve blockade by the subgluteal approach, performed only under ultrasound control without ESP, in comparison with the blockade of the sciatic nerve performed under ultrasound control with ESP, has not been established. Research hypothesis: the blockade of the sciatic nerve by the subgluteal approach performed only under ultrasound control has the same effectiveness as the blockade performed under the ultrasound control with EPN.
The primary purpose of this study is to determine whether the leg positioning or distal tourniquet used during the injection of local anesthetic may decrease the onset time and prolong the duration of analgesia of ultrasound-guided Sciatic Nerve Block (SNB) with popliteal approach. Patients will be divided randomly into three groups: group 1 will receive sciatic nerve block, with leg kept in a neutral position after anesthesia (control group); group 2 will receive the same anesthesia, with leg raised 30° by placing the back of the foot over a support placed on the OR table and maintained in that position for 15 min; and patients in group 3 will receive the same anesthesia, and distal tourniquet placed on the lower part of the leg (upper part of the tourniquet being about 4-6 inches from the ankle) with the leg in a neutral position