Genu Valgum
Genu Varum
Surgical Stapling
Tibia
Epiphyses
Bone Malalignment
Corpus Callosum
Bone Diseases, Metabolic
Characterizing multisegment foot kinematics during gait in diabetic foot patients. (1/20)
(+info)Evidence of gender-specific motor templates to resist valgus loading at the knee. (2/20)
(+info)A reciprocating ledge technique in closing wedge osteotomy for genu valgum in adolescents. (3/20)
PURPOSE: To describe a technique that preserves anterior and posterior alternate ledges in a closing wedge osteotomy. METHODS: Five patients aged 14 to 19 years underwent a closing wedge osteotomy for genu valgum in 8 limbs using a reciprocating ledge technique. A unicortical wedge of bone was removed, with the anterior and posterior cortices spared. The anterior cortex at the proximal level and the posterior cortex at the distal level were cut through. With a wobbling action, the osteotomy site was rotated, and the distal fragment externally rotated. Manual force was applied to close the osteotomy site ensuring overlapping of the reciprocal ledges. The distal fragment was translated laterally to prevent club deformity. The osteotomy site was held with one or 2 staples. Stability was tested by flexion and extension of knee. RESULTS: All 8 limbs attained bone union within 12 weeks, and full range of motion within a mean of 13 (range, 12-15) weeks. The mean correction of the tibiofemoral angle was 13 degrees. At a mean follow-up of 12 months, all patients were pain-free and none developed club deformity. CONCLUSION: Sparing reciprocal ledges in a closing wedge osteotomy for genu valgum may increase stability in the flexion-extension axis, enable early range-of-motion exercises, and facilitate early bone union. (+info)Klinefelter's syndrome with renal tubular acidosis: impact on height. (4/20)
A 19-year-old Indian man presented with a history of proximal muscle weakness, knock knees and gynaecomastia. On examination he had features of rickets and bilateral small testes. Karyotyping revealed a chromosomal pattern of 47,XXX, confirming the diagnosis of Klinefelter's syndrome. He was also found to have hyperchloraemic metabolic acidosis with hypokalaemia, hypophosphataemia, phosphaturia and glycosuria, which favoured a diagnosis of proximal renal tubular acidosis. Patients with Klinefelter's syndrome typically have a tall stature due to androgen deficiency, resulting in unfused epiphyses and an additional X chromosome. However, this patient had a short stature due to associated proximal renal tubular acidosis. To the best of our knowledge, this is the second case of Klinefelter's syndrome with short stature due to associated renal tubular acidosis reported in the literature. This report highlights the need to consider other causes when patients with Klinefelter's syndrome present with a short stature. (+info)Varus and valgus alignment and incident and progressive knee osteoarthritis. (5/20)
(+info)Change in effective leg length after angular deformity correction by hemiepiphyseal stapling. (6/20)
(+info)Variations in varus/valgus and internal/external rotational knee laxity and stiffness across the menstrual cycle. (7/20)
(+info)Management of knee osteoarthritis presenting with tibial stress fractures. (8/20)
Stress fractures of the tibia secondary to tibial deformities from osteoarthritis are rare, and may be difficult to manage. We treated two patients with stress fractures of the proximal tibial diaphyses over a period of two years. Both patients had osteoarthritis of the knee; one with genu valgus deformity and the other, genu varus deformity. The former patient also had a distal tibial fracture and had previously undergone open reduction and internal fixation. The stress fractures of both the patients had been treated conservatively by nonoperative means, but their fractures failed to unite. They then underwent a modular total knee prosthesis with a long tibial stem extension, and subsequently, their fractures united. Both patients recovered uneventfully. (+info)"Genu valgum," also known as "knock-knee," is a condition where there is an excessive angle between the thighbone (femur) and the shinbone (tibia), causing the knees to touch or come close together while the ankles remain separated when standing with the feet and knees together. This abnormal alignment can lead to difficulty walking, running, and participating in certain activities, as well as potential long-term complications such as joint pain and osteoarthritis if not properly addressed. Genu valgum is typically diagnosed through physical examination and imaging studies such as X-rays, and treatment may include observation, physical therapy, bracing, or surgery depending on the severity of the condition and the individual's age and overall health.
"Genu Varum" is a term used in orthopedics to describe a condition where the legs bow out at the knees, causing them to touch each other only at the ankles when standing with the feet and knees together. This is also commonly referred to as "bow-legged." It's important to note that this condition can be present from birth (congenital) or can develop later in life due to various reasons such as rickets, Blount's disease, or injuries. In some cases, it may require medical treatment to correct the alignment of the legs and prevent future complications.
Surgical stapling is a medical technique that uses specialized staplers to place linear staple lines to close surgical incisions, connect or remove organs and tissues during surgical procedures. Surgical staples are made of titanium or stainless steel and can be absorbable or non-absorbable. They provide secure, fast, and accurate wound closure, reducing the risk of infection and promoting faster healing compared to traditional suturing methods.
The surgical stapler consists of a handle, an anvil, and a cartridge containing multiple staples. The device is loaded with staple cartridges and used to approximate tissue edges before deploying the staples. Once the staples are placed, the stapler is removed, leaving the staple line in place.
Surgical stapling has various applications, including gastrointestinal anastomosis, lung resection, vascular anastomosis, and skin closure. It is widely used in different types of surgeries, such as open, laparoscopic, and robotic-assisted procedures. The use of surgical stapling requires proper training and expertise to ensure optimal patient outcomes.
The femur is the medical term for the thigh bone, which is the longest and strongest bone in the human body. It connects the hip bone to the knee joint and plays a crucial role in supporting the weight of the body and allowing movement during activities such as walking, running, and jumping. The femur is composed of a rounded head, a long shaft, and two condyles at the lower end that articulate with the tibia and patella to form the knee joint.
The tibia, also known as the shin bone, is the larger of the two bones in the lower leg and part of the knee joint. It supports most of the body's weight and is a major insertion point for muscles that flex the foot and bend the leg. The tibia articulates with the femur at the knee joint and with the fibula and talus bone at the ankle joint. Injuries to the tibia, such as fractures, are common in sports and other activities that put stress on the lower leg.
The knee joint, also known as the tibiofemoral joint, is the largest and one of the most complex joints in the human body. It is a synovial joint that connects the thighbone (femur) to the shinbone (tibia). The patella (kneecap), which is a sesamoid bone, is located in front of the knee joint and helps in the extension of the leg.
The knee joint is made up of three articulations: the femorotibial joint between the femur and tibia, the femoropatellar joint between the femur and patella, and the tibiofibular joint between the tibia and fibula. These articulations are surrounded by a fibrous capsule that encloses the synovial membrane, which secretes synovial fluid to lubricate the joint.
The knee joint is stabilized by several ligaments, including the medial and lateral collateral ligaments, which provide stability to the sides of the joint, and the anterior and posterior cruciate ligaments, which prevent excessive forward and backward movement of the tibia relative to the femur. The menisci, which are C-shaped fibrocartilaginous structures located between the femoral condyles and tibial plateaus, also help to stabilize the joint by absorbing shock and distributing weight evenly across the articular surfaces.
The knee joint allows for flexion, extension, and a small amount of rotation, making it essential for activities such as walking, running, jumping, and sitting.
The epiphyses are the rounded ends of long bones in the body, which articulate with other bones to form joints. They are separated from the main shaft of the bone (diaphysis) by a growth plate called the physis or epiphyseal plate. The epiphyses are made up of spongy bone and covered with articular cartilage, which allows for smooth movement between bones. During growth, the epiphyseal plates produce new bone cells that cause the bone to lengthen until they eventually fuse during adulthood, at which point growth stops.
Bone malalignment is a term used to describe the abnormal alignment or positioning of bones in relation to each other. This condition can occur as a result of injury, deformity, surgery, or disease processes that affect the bones and joints. Bone malalignment can cause pain, stiffness, limited mobility, and an increased risk of further injury. In some cases, bone malalignment may require treatment such as bracing, physical therapy, or surgery to correct the alignment and improve function.
The corpus callosum is the largest collection of white matter in the brain, consisting of approximately 200 million nerve fibers. It is a broad, flat band of tissue that connects the two hemispheres of the brain, allowing them to communicate and coordinate information processing. The corpus callosum plays a crucial role in integrating sensory, motor, and cognitive functions between the two sides of the brain. Damage to the corpus callosum can result in various neurological symptoms, including difficulties with movement, speech, memory, and social behavior.
Metabolic bone diseases are a group of conditions that affect the bones and are caused by disorders in the body's metabolism. These disorders can result in changes to the bone structure, density, and strength, leading to an increased risk of fractures and other complications. Some common examples of metabolic bone diseases include:
1. Osteoporosis: a condition characterized by weak and brittle bones that are more likely to break, often as a result of age-related bone loss or hormonal changes.
2. Paget's disease of bone: a chronic disorder that causes abnormal bone growth and deformities, leading to fragile and enlarged bones.
3. Osteomalacia: a condition caused by a lack of vitamin D or problems with the body's ability to absorb it, resulting in weak and soft bones.
4. Hyperparathyroidism: a hormonal disorder that causes too much parathyroid hormone to be produced, leading to bone loss and other complications.
5. Hypoparathyroidism: a hormonal disorder that results in low levels of parathyroid hormone, causing weak and brittle bones.
6. Renal osteodystrophy: a group of bone disorders that occur as a result of chronic kidney disease, including osteomalacia, osteoporosis, and high turnover bone disease.
Treatment for metabolic bone diseases may include medications to improve bone density and strength, dietary changes, exercise, and lifestyle modifications. In some cases, surgery may be necessary to correct bone deformities or fractures.
Bone diseases is a broad term that refers to various medical conditions that affect the bones. These conditions can be categorized into several groups, including:
1. Developmental and congenital bone diseases: These are conditions that affect bone growth and development before or at birth. Examples include osteogenesis imperfecta (brittle bone disease), achondroplasia (dwarfism), and cleidocranial dysostosis.
2. Metabolic bone diseases: These are conditions that affect the body's ability to maintain healthy bones. They are often caused by hormonal imbalances, vitamin deficiencies, or problems with mineral metabolism. Examples include osteoporosis, osteomalacia, and Paget's disease of bone.
3. Inflammatory bone diseases: These are conditions that cause inflammation in the bones. They can be caused by infections, autoimmune disorders, or other medical conditions. Examples include osteomyelitis, rheumatoid arthritis, and ankylosing spondylitis.
4. Degenerative bone diseases: These are conditions that cause the bones to break down over time. They can be caused by aging, injury, or disease. Examples include osteoarthritis, avascular necrosis, and diffuse idiopathic skeletal hyperostosis (DISH).
5. Tumors and cancers of the bone: These are conditions that involve abnormal growths in the bones. They can be benign or malignant. Examples include osteosarcoma, chondrosarcoma, and Ewing sarcoma.
6. Fractures and injuries: While not strictly a "disease," fractures and injuries are common conditions that affect the bones. They can result from trauma, overuse, or weakened bones. Examples include stress fractures, compound fractures, and dislocations.
Overall, bone diseases can cause a wide range of symptoms, including pain, stiffness, deformity, and decreased mobility. Treatment for these conditions varies depending on the specific diagnosis but may include medication, surgery, physical therapy, or lifestyle changes.