55 Clinical Trials for Various Conditions
The purpose of this investigator-initiated study is to assess the use of liposomal bupivacaine in major extremity amputation and its effects on post-operative opioid narcotic use, length of stay, and in-hospital costs. Liposomal bupivacaine is an encapsulated, injectable amide anesthetic intended for use in long-acting local anesthesia. It has been shown in randomized trials to be effective in reducing post-operative pain while reducing opioid narcotic use and length of hospital stay following several surgical procedures, particularly after total knee arthroplasty. Extremity amputation is a painful operation often performed in seriously ill or debilitated patients, often related to infection, trauma or malignancy. Application of liposomal bupivacaine in extremity amputation is not well described. The investigators intend to enroll adults greater than age 18 years of age who are to undergo major extremity amputation. Patients will receive targeted injections of liposomal bupivacaine during their procedure. Patient pain scores, total opioid use, and length of hospital stay will be tracked. Patients receiving liposomal bupivicaine will be compared to similarly matched subjects who received standard anesthesia regimens without liposomal bupivicaine. The investigators hypothesize that liposomal bupivicaine used during major amputation decreases opioid use, hospital stay, and in-hospital costs.
This is a non-randomized prospective study of 30 patients scheduled to undergo lower extremity amputation (below the knee, through the knee or above the knee) evaluating bone perfusion and viability using indocyanine green (ICG) fluorescence imaging at several steps during surgical procedure.
The hypothesis of this research protocol is that the investigators will be able to redesign the manner in which upper limb amputations are performed so as to enable volitional control of next generation prosthetic devices and restore sensation and proprioception to the amputated limb. The investigators will test this hypothesis by performing modified above elbow or below elbow amputations in ten intervention patients, and compare their outcomes to ten control patients who have undergone tradition amputations at similar levels. The specific aims of the project are: 1. To define a standardized approach to the performance of a novel operative procedure for both below elbow (BEA) and above elbow amputations (AEA) 2. To measure the degree of volitional motor activation and excursion achievable in the residual limb constructs, and to determine the optimal configuration and design of such constructs 3. To describe the extent of proprioceptive feedback achievable through the employment of these modified surgical techniques 4. To validate the functional and somatosensory superiority of the proposed amputation technique over standard approaches to BEA and AEA 5. To develop a modified acute postoperative rehabilitation strategy suited to this new surgical approach This will be a phase I/pilot clinical trial to be performed over a three-year period as a collaborative initiative involving Brigham \& Women's Hospital/Brigham \& Women's Faulkner Hospital (BWH/BWFH), Walter Reed National Military Medical Center (WRNMMC), and the Massachusetts Institute of Technology (MIT). The investigators will plan to perform 6 of the 10 amputations at BWH/BWFH, and 4 of the amputations at WRNMMC.
This study is a prospective, multi-center, two-arm, unblinded, and randomized controlled trial with a goal of evaluating the impact of a closed incision negative pressure dressing (PREVENA) on incidence of post-operative wound complications and medical costs in patients undergoing lower extremity amputation.
The LEAP protocol is a prospective cohort study of dysvascular patients designed to determine whether implementation of a multi-disciplinary lower extremity amputation protocol in the peri-operative period can shorten post-operative length of stay in patients undergoing trans-tibial or trans-femoral amputations. A consecutive sample of patients diagnosed with peripheral vascular disease and/or diabetes requiring major lower extremity amputation will be enrolled in the study and compared to retrospective controls.
The hypothesis of this research protocol is that we will be able to redesign the manner in which lower limb amputations are performed so as to include biological actuators that will enable the successful employment of next generation lower extremity prostheses. The specific aims of the project are as follows: 1. To define a standardized approach to the performance of a novel operative procedure for both below knee (BKA) and above knee (AKA) amputations 2. To measure the degree of volitional motor activation and excursion achievable in the residual limb constructs, and to determine the optimal configuration and design of such constructs 3. To describe the extent of proprioceptive and other sensory feedback achievable through the employment of these modified surgical techniques 4. To validate the functional and somatosensory superiority of the proposed amputation technique over standard approaches to BKA and AKA 5. To develop a modified acute postoperative rehabilitation strategy suited to this new surgical approach
This study will be a double-blinded randomized controlled trial analyzing all patients who will undergo major lower extremity amputations by the vascular surgery service at University of California, San Francisco (UCSF) Fresno between July 2017 and June 2018 to determine if regional nerve blocks (sciatic and femoral) have any effect on postoperative pain control, narcotic requirements, and length of stay compared with standard post-operative narcotic regimens.
The purpose of this study is to pilot test a program to help overweight and obese individuals with a lower extremity amputation (LEA) lose weight and become more physically active. The investigators will randomize approximately 30 individuals to either a self-directed weight loss program (n=15) or a coached weight loss program (n=15). The primary purpose of this pilot study is to determine if a home-based weight loss/physical activity (PA) intervention is feasible in individuals with a LEA. MOVE-LEAP is a 20-week program that involves 11 phone calls from a health coach and a single home visit by a physical therapist. This pilot study aims to: 1. test the feasibility of recruiting overweight/obese individuals with LEA into a randomized trial; 2. assess whether the intervention can be delivered with high fidelity, and 3. evaluate whether the intervention is acceptable to and safe as determined by participant feedback, participation and retention for outcome measures.
Limb transplantation surgery is the transfer of one or more limbs from a deceased human donor to a patient with single or multiple limb amputation. Hand transplantation is an innovative reconstructive procedure that has the potential to significantly improve the lives of hand amputees. The purpose of this study is to develop the best practices for multiple limb transplantation that will improve the outcomes of future limb transplant recipients.
To assess the carryover effect of an innovative new gait training program on physiological and functional gait performance in persons with a traumatic lower extremity amputation. A second objective is to clarify the relationship between gait biomechanics (joint and sgment kinematics and energy cost.
Phantom limb pain (pain originating from where an amputated limb once was) is a common occurrence after lower extremity amputations, with some sources noting incidence to be as high as 60-80% six months after surgery. This pain can eventually subside, however, cases have been reported of incidence 10 years after surgery. This pain is not only physically detrimental, but can also be psychologically detrimental after a difficult to accept change in the body. Prior studies have been performed using regional anesthetic techniques (including spinals and epidurals) and different medications to attempt to reduce the incidence of phantom limb pain, however, the data have been mostly inconclusive. Of interest, prior studies have not addressed peripheral nerve blocks, a method of anesthesia/analgesia more commonly employed for amputations recently. The purpose of our retrospective study is to look at the incidence of phantom limb pain at our institution over a two year period to determine if peripheral nerve blocks result in a significantly reduced incidence compared to other techniques (spinal, epidural, general anesthesia only). In addition, there is little data on relation of reason for amputation and presence of preoperative neuropathy and incidence of phantom pain. As secondary endpoints, the investigators wish to investigate if certain reasons for amputation (trauma, peripheral vascular disease, diabetes, and others) and/or neuropathy lead to a higher incidence of phantom limb pain. The results of this study could impact future management of patients who are to receive amputations and may lead to further prospective studies on the topics involved.
The agonist-antagonist myoneural interface (AMI) construct, known as the Ewing amputation at the trans-tibial level, has been shown to create a bi-directional neural communication platform as a means of controlling and interpreting proprioceptive feedback from a prosthetic joint. In AMI constructs, agonist-antagonist muscles are mechanically coupled within the residual limb, and volitional contraction of an agonist passively stretches that muscle's antagonist. The natural neural responses from muscle spindles within both muscles are then interpreted by the central nervous system as sensations of joint position and speed, associated with movement of the prosthesis. The aim of this research protocol is to evaluate the electromyographic and kinematic patterns of participants who have undergone unilateral lower extremity Ewing Amputation in order to determine how similar their residual limb data is when compared to their intact limb data. A secondary aim of this research may include comparison of the Ewing participant cohort's biomechanical patterns to a similar cohort of participants who have undergone standard amputation. The investigators hypothesize that the affected limb of patients with the Ewing procedure will demonstrate a pattern of electromyographic activation of their AMI constructs and kinematic data that recapitulates the pattern seen in their intact limb. The investigators secondarily hypothesize that the kinematic assessment of Ewing Amputation patients will demonstrate patterns that are significantly more physiologic than those witnessed in similar assessments of standard amputees.
When the prosthetic socket of a Veteran with a lower limb amputation no longer fits or is damaged beyond repair, a new prosthetic socket is warranted. The provision of a new socket requires multiple clinical visits which can place a high travel burden and potential pandemic exposure stress on Veterans who live in rural communities far from VA Medical Centers or alternative prosthetic clinics. This research seeks to determine if one of the in-person visits traditionally needed to obtain a well-fitting prosthesis can be performed remotely with the assistance of a helper. The investigators seek to discover if an untrained individual (a helper) can wield inexpensive, easy to use, digital technology to capture the shape of a residual limb to see if it can be used to fabricate a prosthetic socket that fits at least as well as one fabricated by a prosthetist using traditional, hand casting methods in the clinic. The expected result of this research is an evidence-based prosthetic fabrication process that reduces Veteran travel burden while providing a prosthesis that fits at least as well as the current standard-of-care. The upshot is a clear improvement in prosthetic provision for Veterans, particularly for those who live in rural communities. To make this determination, the investigators will perform a between-subject experiment with two specific aims. To determine differences in goodness of fit between the two study sockets, the investigators will use both patient reported outcomes, and measurements of the pressure applied to the distal end of the residual limb. Specific Aim 1: Determine if patient reported outcomes, by subjects wearing a prosthetic socket whose shape was captured with study helper assistance, are at least as good as those reported by subjects wearing a socket whose shape was captured by a prosthetist. The investigators propose to recruit Veterans with a below knee amputation and their study helpers to participate in a human subject experiment. Participants will be randomly assigned and fit with either a prosthesis made with study helper assistance and digital methods, or one made wholly by a prosthetist using traditional methods. Patient reported outcome metrics will be collected while the subject is still wearing their as-prescribed socket at the beginning of the study (baseline), and again after wearing the study prosthesis for two weeks. Specific Aim 2: Determine if distal end residual limb pressure, measured from a group of individuals fit with a prosthetic socket whose shape was captured with study helper assistance using digital methods, are no worse than those measured from a group of individuals fit with a prosthetic socket whose shape was captured by a prosthetist using traditional methods. Concurrent with the human subject procedures briefly described above, the investigators propose to fabricate duplicates (copies) of the two prosthetic sockets used by each subject in Specific Aim 1. A novel sensor will be embedded in these duplicate sockets which can measure the pressure applied to the distal end of the residual limb. Measurements of distal end residual limb pressure while standing and walking for both the as-prescribed and study sockets will be collected at the beginning of the study (baseline), and again after two weeks. The data from the investigators' experiments will be used to determine if residual limb shape capture by a helper using digital technologies can be used to make prosthetic sockets that fit at least as well as those made by a prosthetist using traditional, hand casting techniques. One third of all Veterans live in rural communities far from VA Medical Centers. When Veterans with a lower limb amputation need a new prosthetic socket, attending in-person clinical visits can be a challenge. If the hypotheses are supported, this research will provide evidence to support the use of digital technology as part of clinical practice, enabling a remote, study helper enabled alternative to one of the in-person clinical visits needed to fabricate a well-fitting prosthesis.
Individuals with lower limb amputation often complain about uncomfortable residual limb skin temperatures and the accumulation of sweat inside their prostheses. It doesn't take long before the presence of sweat on the residual limb leads to a lack of confidence in the security of their prosthetic suspension. Some circumstances allow the wearer to doff the prosthesis before it falls off, wipe it and the residual limb dry, and then don it again. Another option is to simply reduce the intensity of activities before sweat becomes a problem. However, the Warfighter amputee may not be afforded such accommodations. For these service personnel, inadequate moisture management can significantly limit or inhibit their mobility. The objective of the proposed research is to provide lower limb amputees who work in demanding environments with a prosthesis that remains secure despite profuse residual limb sweating without compromising residual limb health and comfort. The aim of this research is to compare three different, lower limb prosthetic suspension systems and identify which is most effective at maintaining a secure adherence when worn in conditions that result in profuse sweating. The investigators also aim to compare how the three study prostheses effect residual limb skin health and comfort when participants pursue their usual activities in the home, work, and community environments. To achieve these aims, the investigators will to recruit 25 below-knee amputees. Each subject will be asked to be asked to wear: (1) their as-prescribed prosthesis, (2) a prosthesis with a perforated elastomeric liner that allows sweat to flow away from the skin, and (3) a prosthesis that has a battery and body-weight activated pump to flow air between the prosthesis and the residual limb skin, allowing expulsion of any accumulated sweat. Subjects will wear each of these prostheses in the home, work, and community environments for two weeks, after which the investigators will measure their residual limb health and comfort. Subjects will then walk on a treadmill in a room whose climate will be set to Middle East-like conditions: 35 °C (95 °F) and 50% relative humidity. After 30 minutes, the investigators will measure any slippage of their prosthesis relative to their limb and how much sweat is expelled. The investigators hypothesize there will be differences in the amount of slippage, residual limb health, and comfort between the three prostheses.
The purpose of the study is to obtain performance measurements and participant feedback about use of an investigational prosthetic foot compared to the participant's usual prosthetic foot. To accomplish this, the study will use a combination of laboratory motion analysis, functional tests, and community mobility trials where participants complete questionnaires and interviews about use of an investigational prosthetic foot compared to the participant's usual prosthetic foot. Individuals with amputations that participate in the (optional) motion analysis sub-study at the University of Washington will complete forward walking, side-step, and across river rock with usual foot (session 1), and also with the investigational foot locked and unlocked (session 2) after an accommodation period of between 1-4 weeks. The participants will rate their experiences using socket comfort score and the socket pressure score. Control participants recruited at the University of Washington to provide information about performance for people without amputation will go through the consenting process, then will be asked to complete forward walking, Figure-of-8 Walk Test, Narrowing Beam Walking Test, side-step, and walking across river rock surface. These tests will be conducted at a single session.
When prescribing a prosthetic foot, clinicians face a dizzying array of choices as more than 200 different prosthetic feet are available. While these conventional prosthetic feet primarily function in the sagittal plane, the intact foot and ankle comprise a complex set of joints that allow rotation in multiple planes of motion. Some of these motions are coupled, meaning rotation in one plane induces motion in another. One such coupling is between the sagittal and transverse planes. For every step, plantar- and dorsi-flexion motion in the sagittal plane is coupled with external and internal rotation of the shank relative to the foot in the transverse plane. There is no prosthetic foot available for prescription that mimics this natural coupling. To investigate the need for this coupling, the investigators have built a torsionally adaptive prosthesis where the coupling ratio between the transverse- and sagittal-planes can be independently controlled with a motor. This research has one specific aim: to identify the optimal coupling ratio between transverse- and sagittal-plane motions using a novel, torsionally adaptive prosthesis for individuals with lower limb amputation. The investigators will conduct a human subject experiment wearing the motor-driven and computer controlled torsionally adaptive prosthesis. Individuals with lower limb amputation will be asked to walk in a straight line and in both directions around a circle while the coupling ratio between transverse- and sagittal-plane motions is varied between trials. Participants will be blinded to the coupling ratio. The investigators hypothesize that: (1) a coupling ratio exists that minimizes undesirable transverse-plane socket torque and (2) there will be a coupling ratio that individuals with lower limb amputation prefer.
The purpose of the study is to evaluate the use of the SPY Elite System to assess real-time tissue perfusion of lower extremity amputation sites and to develop parameters to predict healing of amputations at the time of surgery. This is a pilot study to see if the Spy Elite System is capable of recording accurate measurements on amputation sites to allow some correlation to healing. If this study shows promise for the device, the investigators would plan a larger study in which the data would be assessed in the operating room at time of acquisition and revision performed if needed based on the findings.
People with lower extremity amputation (LEA) have persistent problems with balance, falls, residual limb pain, functional mobility, cognitive attention during gait, and satisfaction with participation in daily activities, despite using prostheses. The purpose of this randomized clinical trial is to advance understanding of how dynamic foot design features may help people with LEA This study will include people with above-knee amputations, or with bilateral amputations, or with below-knee amputations and lower levels of mobility. The main study questions/goals are: 1a) To determine if frontal plane adaptation in a foot prosthesis impacts performance, comfort, activities of daily living, and community mobility in the study populations. To answer this question, we will compare a locked and unlocked version of the novel prosthesis. 1b) To determine how the unlocked investigational foot condition compares to the person's usual foot using the outcomes listed above. 2) To examine the participants' lived experience during community activities. The study will use performance tests, questionnaires, logbooks, and interviews to monitor person-centered outcomes and perceptions of personal functioning during the use of the investigational foot (locked and unlocked) compared to the person's usual foot.
The purpose of this study is to examine the effect of targeted muscle reinnervation on the outcomes of amputees at a level 1 trauma center. The investigators propose to randomize all patients requiring amputation with and without targeted muscle reinnervation. This study will help delineate the efficacy of targeted muscle reinnervation in the general population.
Individuals with lower extremity amputation are often challenged by complications that arise from poor prosthetic fit, including movement of the residual limb in the socket, known as pistoning. Pistoning can lead to gait instability, skin problems, and pain. Different prosthetic suspension systems have been developed to decrease this motion, including elevated vacuum suspension, which utilizes a pump to draw air from the socket. However, scientific analyses to understand the movement between the limb and socket have yet to be performed with a high level of accuracy. This study will use a state-of-the art imaging technique, known as dynamic stereo x-ray, to quantify the 3D movement of the residual limb in the socket. It is hypothesized that dynamic stereo x-ray will be a sensitive method to measure differences in residual limb movement between 2 different socket suspension techniques: suction and elevated vacuum suspension. This information is critical for advancing prosthetic treatments to reduce secondary conditions and degenerative changes that result from poor prosthetic fit.
The proportion of US Veterans who are women is currently at its highest point in history and is projected to continue increasing. Nonetheless, the literature regarding prosthetic and functional outcomes in women Veterans with lower extremity amputation (LEA) is nearly non-existent. Research in other healthcare systems indicates the presence of concerning gender differences in both prosthetic outcomes and functional mobility, with women being less likely to be prescribed a prosthesis, less likely to use it, and more likely to be dissatisfied than men. This mixed-methods study will use VA administrative data, qualitative interviews, and a patient survey to characterize women Veterans' outcomes as well as compare them to those of male Veterans, resulting in the largest study to date on women Veterans with LEA. Data from this rigorous evaluation will inform clinical care by identifying intervention targets to improve prosthetic and functional outcomes for this understudied population.
The Southern Illinois University (SIU) Hand Transplant Program is a multidisciplinary research effort with the goal of restoring form and function to unilateral or bilateral upper extremity amputees by vascularized composite allotransplantation of the hand/upper extremity (hand transplantation). Hand transplantation includes transferring upper extremities/hands from deceased human donors to patients with single or bilateral hand or arm amputation. The purpose of the trial is to study functional, psychological, and immunological outcomes of human upper extremity allotransplantation.
The purpose of this study is to evaluate a new prosthetic socket construction technique in order to improve the quality of care to lower extremity amputees.
When a limb is amputated, pain perceived in the part of the body that no longer exists often develops, called "phantom limb" pain. The exact reason that phantom limb pain occurs is unclear, but when a nerve is cut-as happens with an amputation-changes occur in the brain and spinal cord that are associated with persistent pain. The negative feedback-loop between the injured limb and the brain can be stopped by putting local anesthetic-called a "nerve block"-on the injured nerve, effectively keeping any "bad signals" from reaching the brain. A "continuous peripheral nerve block" (CPNB) is a technique providing pain relief that involves inserting a tiny tube-smaller than a piece of spaghetti-through the skin and next to the target nerve. Local anesthetic is then introduced through the tiny tube, which bathes the nerve in the numbing medicine. This provides a multiple-day block that provides opioid-free pain control with no systemic side effects, and may prevent the destructive feedback loop that results in phantom limb pain following an amputation. We propose a multicenter, randomized, triple-masked (investigators, subjects, statisticians), placebo-controlled, parallel arm, human-subjects clinical trial to determine if a prolonged, high-concentration (dense), perioperative CPNB improves post-amputation physical and emotional functioning while decreasing opioid consumption, primarily by preventing chronic phantom limb pain.
The purpose of this study is to identify the best treatment sequence and combination of acupuncture points for the treatment of phantom limb or residual limb pain in the traumatic/surgical amputee.
The purpose of this study is to investigate the relationship between thigh strength and walking ability and assess if using a blood pressure cuff on the leg improves strength and walking performance.
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.
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.
The purpose of this study is to demonstrate the efficacy of functional electrical stimulation (FES) for trans-tibial amputees. The investigators aim to demonstrate that providing three months of FES intervention will increase knee extension strength, increase volume of the residual limb and decrease chronic and phantom pain.
The aims of this study address an exploratory endpoint in the Major Extremity Trauma Research Consortium (METRC) Transtibial Amputation Outcomes Study (TAOS; NCT01821976) that is investigating prosthesis fit, alignment and condition of the residual limb. As there are no validated measures of fit and alignment (factors known to impact comfort, function and performance among amputees) the TAOS study includes a provision in the protocol for acquisition of photographs, video and radiographs in order to help develop uniform assessments of the residual limb. The goal of the ProFit study is to validate and refine the prosthetic assessment tool (ProFit) that was developed by an expert panel of certified orthotist prosthetistis (CPOs) in collaboration with orthopaedic trauma investigators, a measurement scientist and a biomedical engineer from the BADER consortium.