Growth Plate Fracture of the Forearm
Definition
A growth plate fracture of the forearm is a type of injury that occurs in the growth plate, which is the area of developing cartilage tissue near the ends of long bones in children and adolescents. This fracture can result from various causes, such as falls, sports injuries, or accidents, and can affect the normal growth and development of the forearm bones.
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Pediatric Orthopaedics
We provide a comprehensive, multidisciplinary approach to managing the orthopaedic needs of children and teens, while at the same time attending to their social, emotional, and developmental needs. Ours is one of only two such programs in Connecticut. From diagnosis and treatment, to surgery and follow-up care, our team works with other pediatric specialty clinics to care for young patients with a wide spectrum of orthopaedic conditions, including: Bone deformity Cerebral palsy and other neuromuscular conditions Conditions specific to female athletes Disorders of the hip, including hip dysplasia Fractures, dislocations, and other musculoskeletal injuries Hand and arm disorders Femur fracture Foot and ankle disorders, including clubfoot Leg length discrepancy Scoliosis Overuse and traumatic injuries in the growing athlete Skeletal dysplasiaHand & Upper Extremity Surgery
We evaluate injuries and musculoskeletal disorders of the hand and upper extremities. Our team consists of physicians who are board-certified in orthopaedics, hand surgery, and plastic surgery. Our surgeons are experts in their fields, offering patients the latest technological advances and treatments. We are also active in both clinical and basic science research. Our specialties and treatments include: Wrist and hand fractures (including mal-unions and non-unions and percutaneous fixation) Distal radius fractures Scaphoid fractures Wrist and hand instabilities Arthroscopy of the wrist, hand, and elbow Minimally invasive hand and wrist surgery Athletic injury to upper extremities Tendon, vascular, and nerve injuries Joint contractures Arthritis of the wrist, hand, and elbow Tendonitis Trigger finger Nerve compression syndromes Soft tissue reconstruction of the extremities (including skin grafts and flaps) Tumors of the hand3-D Patient-Specific Surgical Correction Program
The orthopaedic surgery team is dedicated to improving function in patients of all ages who have been injured, developed a problem such as arthritis, or who were born with a bone or joint problem. Although there are standard ways of treating some of these problems, our team can more precisely address many orthopaedic issues with the use of 3-D modeling and virtual surgical planning using 3-D printed, patient-specific surgical guides. To find out more about this program, please fill out a brief survey . We have orthopaedic surgical specialists who are currently using 3-D technology to correct spinal deformity, post-traumatic mal-unions of long bones, congenital upper and lower limb deformities, complex joint replacement surgery (for hips, knees, shoulders, and elbows) and mal-alignment of joints and bones. We work closely with engineers, radiologists, and cutting-edge medical companies who assist in deploying this technology for our patients. Patients that have complex orthopaedic problems are evaluated by our specialists. If the problem is amenable to treatment with custom 3-D surgical correction techniques, a specialized high-resolution CT or MRI scan is obtained focusing on just the injured side (if only bone models are needed) or of the injured and non-injured analogous body part if virtual surgical planning and intra-operative patient specific guides are necessary. Using the data in the CT or MRI scan, a unique 3-D model is built on the computer using specialized image processing software. The 3-D models are then used to study the deformity/injury in detail prior to the actual surgery. The planning is completed with the surgeon and biomedical engineer working together to manipulate the images on a computer to plan the necessary cuts or bone excision to correct the deformity. Surgeons are able to make certain that the bones are corrected and straight, joints can bend and extend, and muscles and nerves are properly positioned. Patient specific guides are then printed in 3-D for use in the operating room during surgery, so that the virtual model can be replicated in the surgery for precise correction of each patient’s problem. These techniques have been shown to decrease surgical time and blood loss, as well as provide a more precise correction of the problem.