Active clinical trials for "Fractures, Bone"

This registry supports international data collection and research on PPFx treatments after hip and knee arthroplasty. A registry such as this ultimately aims to provide far-reaching benefits to society including reduced morbidity and mortality, improved patient safety, improved quality of care and medical decision-making, reduced medical spending, and advances in orthopaedic science.

Currently, there are approximately 300,000 hip fractures per year in the US with a mortality rate of 20% within 1 year. In Hong Kong, around 6,000 hip fractures occur yearly with costs approximately 52 million USD, and these numbers are projected to double by 2050. The treatment of osteoporotic fractures is a major challenge as bone healing is delayed due to the impaired healing properties with respect to bone formation, angiogenesis and mineralization. Failure to unite results in pain, weakness, reduced mobility and fixation failure, and these complications are most common in elderly patients. Enhancement of osteoporotic fracture healing even after surgical fixation is therefore critical as a major goal in modern fracture management. Low-magnitude high-frequency vibration (LMHFV) is a biophysical intervention that provides non-invasive, systemic mechanical stimulation and we are the first group to study its effect on fracture healing. Our previous animal studies have shown LMHFV to enhance healing from the early inflammation stage to the late phases of remodeling in osteoporotic diaphyseal fracture healing. Using our newly developed clinically relevant metaphyseal fracture model, we further proved the efficacy of LMHFV. Our results show LMHFV significantly enhanced fracture healing in both osteoporotic and normal rats radiologically by X-ray and micro-CT, histologically and biomechanically. Justified with our preclinical studies, we hypothesize LMHFV can accelerate the time to fracture healing and enhance functional recovery. In this study, we propose to study the efficacy of LMHFV in trochanteric hip fracture healing by conducting a randomized double-blinded placebo-controlled clinical trial. Elderly patients aged 65 years or older of either gender, after surgical fixation, will be treated with LMHFV at 35Hz, 0.3g, 20 minutes/day, 5 days/week for 6 months. Results will be evaluated by clinical assessments, radiologically with X-rays, Computed Tomography (CT) and dynamic perfusion Magnetic Resonance Imaging (MRI) for blood circulation evaluation, Dual-energy X-ray absorptiometry (DXA), functional outcomes, and mortality. Positive findings from the study would have huge impact and change clinical practice.

This project aims to improve the global outcome for an aging individual after a traumatic fall, through identifying conditions contributing to a fall and promoting recovery and rehabilitation. Through better understanding 'falling phenotype', the ultimate aim is to prevent future complications, as well as new falls and fractures in the growing older population.

Diseases of bone associated with ageing, including osteoporosis (OP) and osteoarthritis (OA), reduce bone mass, bone strength and joint integrity. Current non-surgical approaches are limited to pharmaceutical agents that are not disease modifying and have poor patient tolerability due to side effect profiles. Developing a fundamental understanding of cellular bone homeostasis, including how key cell types affect tissue health, and offering novel therapeutic targets for prevention of bone disease is therefore essential. This is the focus of OSTEOMICS. A number of factors have been linked to increased risk of bone disease, including genetic predisposition, diet, smoking, ageing, autoimmune disorders and endocrine disorders. In our study, we will recruit patients undergoing elective and non-elective orthopaedic surgery and obtain surgical bone waste for analysis. This will capture a cohort of patients with bone disorders like OP and OA, in addition to patients without overt clinical bone disease. We will study the relationship between the molecular biology of bone cells, bone structure, genetics (DNA) and environmental factors with the aim of identifying and validating novel therapeutic targets. We will leverage modern single cell technologies to understand the diversity of cell types found in bone. These technologies have now led to the characterisation of virtually every tissue in the body, however bone and bone-adjacent tissues are massively underrepresented due to the anatomical location and underlying technical challenges. Early protocols to demineralise bone and perform single cell profiling have now been developed. We will systematically scale up these efforts to observe how genetic variation at the population level leads to alterations in bone structure and quality. Over the next 10 years, we will generate data to comprehensively characterise bone across health and disease, use machine learning to drive analysis, and experimentally validate hypotheses - which will ultimately contribute to developing the next generation of therapeutic agents.

An investigation of the change in inflammation marker levels across hip fracture surgery and an exploration of any association with change in self reported health status and incidence of postoperative delirium

Recent research has demonstrated that a hemiarthroplasty (replacement of half the joint) has lower rates of post-surgical complications than a total hip arthroplasty does. However, surgeons tend to vary in their approach to hemiarthroplasties. The lateral approach, which involves making an incision at the side of the patient's hip, requires surgeons to cut through the muscle to access the hip, which has been associated with greater muscle damage and slower rates of recovery. On the other hand, the direct anterior approach does not require the cutting of the patient's muscle and is therefore associated with minimal muscle damage and faster rates of recovery. This study will aim to assess the impact of the surgical approach (Direct Anterior Approach vs. Lateral approach) during hemiarthroplasty on patients' short-term mobility, quality of life, function, pain, and safety parameters.

To define a serum protein-based diagnostic for the progression and failure of fracture healing, through the identification of a set of serum proteins that appear at early times of biological healing and show a specific correlation with later radiological and functional signs used to define delayed healing and non-union.

Primary objective of this study is to compare fracture related infection (FRI) rates of ZNN Bactiguard Tibia to conventional uncoated titanium-alloy nails 12 months after tibia fracture fixation. The secondary objectives are confirmation of safety, performance and clinical benefits of ZNN Bactiguard implant and related instrumentation12 months after fracture fixation.

Osteoporosis is a disorder of low bone mass and micro-architectural deterioration resulting in decreased mechanical strength and increased susceptibility to fractures even after minimal trauma. These 'minimal trauma fractures' (also known as 'osteoporotic', 'low trauma' or 'fragility' fractures) are the hallmark of a chronic and disabling disease that affects both men and women worldwide. On statistical grounds, more than 50 % of postmenopausal women and 30 % of men over the age of 60 years will suffer at least one minimal trauma fracture during their remaining lifetime. Any osteoporotic fracture predisposes to further fractures, significant morbidity and premature death. Thus, following a first minimal trauma fracture both men and women have a two- to threefold increased risk of subsequent fracture. This study aims to determine feasibility of evaluating different models of care through a structured multidisciplinary path tailored to identify, assess and treat hip fracture patients in an effective timely manner that are at high risk of subsequent fracture (Type A model) and to compare its effectiveness and feasibility with a type B, C & D model as proposed by Ganda et al at the Aga Khan University, with collaboration of the departments of Orthopaedics, Chemical Pathology, Family Medicine and Internal Medicine.

Objective: Prospective study regulation in bone mass, size, architecture, cortical, trabecular bone, soft tissues and risk factors for cardiovascular disease at growth. Determine regulation by environmental factors. Evaluate how training affects the skeleton, soft tissues and cardiovascular risk factors during growth Material/Methods: (i) 500 children in one RCT´s with or without intervention with physical activity (daily scholl physical education) from school start to college. Annual evaluations Importance: The investigators provide increased understanding of the pathophysiology of osteoporosis by determine the mineralization, size- and architecture development during growth and adulthood. Evaluate if intervention program with exercise increase bone strength, muscle mass and reduce fatness and risk factor for cardiovascular disease. Background: Skeletal growth and the age related bone loss determine who will get osteoporosis (and fractures), but not only bone mass, also skeletal architecture and bone quality influence bone strength. Regulation of the traits differs where hormones, genetics and environmental factors continuously influence the development with different effect during different ages. It is thus imperative to determine the regulators of the traits and evaluate if these can be modified during growth. Aim: Study regulation of bone mass, size, architecture, cortical, trabecular, axial and appendicular bone and soft tissue during growth and aging; evaluate risk factors for cardiovascular disease; determine importance of environmental factors and hereditary factors. Study Design/Method Bunkeflo Cohort: Prospective, controlled exercise intervention study annually following skeletal development in 500children from age 7. Importance: By evaluating skeletal mass/architecture separate we will increase the understanding of the pathophysiology of osteoporosis. The intervention study provide Evidence Based Information as regard the importance of physical activity during growth. The presented Strength Index, where we combine bone mass and skeletal architecture, may predict fractures better than only bone mass.