Fracture Healing
Hip Fractures
Fracture Fixation, Internal
Fracture Fixation
Osteoporotic Fractures
Radius Fractures
Fractures, Spontaneous
Fractures, Stress
Femoral Neck Fractures
Fracture Fixation, Intramedullary
Rib Fractures
Skull Fractures
Fractures, Compression
Osteoporosis
Bone Plates
Bone Nails
Orbital Fractures
Colles' Fracture
Bony Callus
Periprosthetic Fractures
Bone Density
Joint anatomy, design, and arthroses: insights of the Utah paradigm. (1/199)
This model of joint design argues 1) that excessive fatigue damage (MDx) in articular cartilage collagen can be the "final cause" of an arthrosis; 2) that known responses of a growing joint's anatomy and geometry, and modeling and maintenance activities, to mechanical loads minimize that cause and thus arthroses; 3) and many biomechanical, biochemical, cell-biologic, genetic and traumatic "first causes" of arthroses could lead to that final cause. The model depends partly on the following facts (marked by a single asterisk) and ideas (marked by a double asterisk). A) During growth a joint's total loads can increase over 20 times without causing an arthrosis, yet in adults an equal loading increase would cause one. B) Fatigue damage (MDx) occurs in joint tissues, larger strains increase it, and minimizing strains reduces it. C) Bone can repair amounts of MDx below an "MDx threshold," but larger amounts can escape repair and accumulate. The model assumes articular cartilage has similar features. D) Bone modeling makes bones strong enough to keep their strains below bone's MDx threshold and minimize MDx. Chondral modeling shapes and sizes joints during growth; that would keep articular cartilage strains below the chondral MDx threshold to minimize chondral MDx and arthroses. Normal chondral modeling nearly stops in adults, which might explain point A above. E) Throughout life maintenance activities preserve optimal physical, chemical and biologic properties of a joint's tissues. To past emphases on the biochemical, genetic, cellular and molecular biologic features of adult joint physiology, this model adds organ-level, tissue-level and vital-biomechanical features of growing joints that invite study and understanding at lower levels of biologic organization. (+info)The oral contraceptive pill: a revolution for sportswomen? (2/199)
OBJECTIVES: To determine the effects of the oral contraceptive pill (OCP) on skeletal health, soft tissue injury, and performance in female athletes. METHODS: A literature review was performed using literature retrieval methods to locate relevant studies. RESULTS: Most female athletes primarily choose to use the OCP for contraceptive purposes, but cycle manipulation and control of premenstrual symptoms are secondary advantages of its use. The effect of the OCP on bone density in normally menstruating women is unclear, with some studies reporting no effect, others a positive effect, and some even a negative effect. The OCP is often prescribed for the treatment of menstrual disturbances in female athletes, and improvements in bone density may result. Whether the OCP influences the risk of stress fracture and soft tissue injuries is not clear from research to date. Effects of the OCP on performance are particularly relevant for elite sportswomen. Although a reduction in Vo2MAX has been reported in some studies, this may not necessarily translate to impaired performance in the field. Moreover, some studies claim that the OCP may well enhance performance by reducing premenstrual symptoms and menstrual blood loss. A fear of weight gain with the use of the OCP is not well founded, as population studies report no effect on weight, particularly with the lower dose pills currently available. CONCLUSIONS: Overall, the advantages of the pill for sportswomen would appear to outweigh any potential disadvantages. Nevertheless, there is individual variation in response to the OCP and these should be taken into account and monitored in the clinical situation. Women should be counselled as to the range of potential benefits and disadvantages in order to make an informed decision based on individual circumstances. (+info)Magnetic resonance imaging in the diagnosis of sacral stress fracture. (3/199)
Low back and buttock pain in athletes can be a source of frustration for the athlete and a diagnostic dilemma for the doctor. Sacral stress fractures have been increasingly recognised as a potential cause of these symptoms. As plain radiographs are often normal and the radiation load of an isotope bone scan is substantial, the alternative use of magnetic resonance imaging in the diagnosis of a sacral stress fracture is highlighted in this case report. (+info)Nonunion of tibial stress fractures in patients with deformed arthritic knees. Treatment using modular total knee arthroplasty. (4/199)
In two years we treated four women with ununited stress fractures of their proximal tibial diaphyses. They all had arthritis and valgus deformity. The stress fractures had been treated elsewhere by non-operative means in three patients and by open reduction and internal fixation in one, but had failed to unite. After treatment with a modular total knee prosthesis with a long tibial stem extension, all the fractures united. A modular total knee prosthesis is suitable for the rare and difficult problem of ununited tibial stress fractures in patients with deformed arthritic knees since it corrects the deformity and the adverse biomechanics at the fracture site, stabilises the fracture and treats the arthritis. (+info)Early diagnosis of stress fracture of the lumbar spine in athletes. (5/199)
Thirty-three athletes complaining of back pain of more than 1 months' duration and with normal radiography of the lower spine were all studied by scintigraphy and in 24 of them with single photon emission computerized tomography. A stress fracture was considered present if localized increased uptake was seen at a vertebral level. Scintigraphy showed increased uptake in 17 of 33 patients and single photon emission computerized tomography in 16 of 24 patients. (+info)Bone imaging in sports medicine. (6/199)
Increased participation in sports by the general public leads to increase in sports induced injuries including stress fractures, shin splints, arthritis and host of musculotendenous maladies. We have studied twenty patients referred from sports clinic for bone scanning to evaluate clinically difficult problems. It showed stress fracture in twelve patients, bilateral shin splint in five patients and normal bone scan in three patients. Present study highlights the utility of bone imaging for the diagnosis of various sports injuries in sports medicine. (+info)Pediatric stress fractures. (7/199)
Stress fractures in children are uncommon. This report describes the findings of 8 cases in 6 children. One patient had 3 stress fractures: 2 consecutive midshaft stress fractures of the same tibia associated with one of the fibula. Signs and symptoms may be misdiagnosed as malignant tumors or osteomyelitis. Serial radiographs and computed tomography scans are the key to the diagnosis, although bone scan and magnetic resonance imaging can be helpful. Biopsy is unnecessary and might even be misleading. (+info)Does pulsed low intensity ultrasound allow early return to normal activities when treating stress fractures? A review of one tarsal navicular and eight tibial stress fractures. (8/199)
We sought to evaluate the efficacy of daily pulsed low intensity ultrasound (LIUS) with early return to activities for the treatment of lower extremity stress fractures. Eight patients (2 males, 6 females) with radiographic and bone scan confirmed tibial stress fractures participated in this study. Additionally, a case report of a tarsal navicular stress fracture is described. All patients except one were involved in athletics. Prior to the study, subjects completed a 5 question, 10 cm visual analog scale (VAS) regarding pain level (10 = extreme pain, 1 = no pain) and were assessed for functional performance. Subjects received 20-minute LIUS treatments 5 times a week for 4 weeks. Subjects maintained all functional activities during the treatment period. Seven patients with posterior-medial stress fractures participated without a brace. Subjects were re-tested after 4 weeks of treatment. Mann-Whitney U tests (VAS data) and paired t-tests (functional tests) assessed statistical significance (p<0.05). Although the intensity of practice was diminished in some instances, no time off from competitive sports was prescribed for the patients with the tibial stress fractures. The patient with the anterior tibial stress fracture underwent tibial intramedullary nailing at the conclusion of a season of play. In this uncontrolled experience, treatment of tibial stress fractures with daily pulsed LIUS was effective in pain relief and early return to vigorous activity without bracing for the patients with posterior-medial stress fractures. (+info)11-Hydroxycorticosteroids are a class of steroid hormones that are produced in the adrenal gland. They are created when cortisol, a type of glucocorticoid hormone, is metabolized by the enzyme 11-beta-hydroxysteroid dehydrogenase type 2 (11-β-HSD2) in the kidneys. This results in the formation of cortisone, which is then converted back to cortisol as needed.
11-Hydroxycorticosteroids are important for regulating a variety of physiological processes, including metabolism, immune response, and stress response. They also have anti-inflammatory effects and are sometimes used in medical treatments to reduce inflammation and suppress the immune system.
Elevated levels of 11-hydroxycorticosteroids can indicate an overactive adrenal gland or a tumor that is producing excess cortisol. Low levels may be seen in conditions such as Addison's disease, which is characterized by underactivity of the adrenal gland.
Medical definitions of 11-hydroxycorticosteroids typically refer to the measurement of these hormones in urine or blood tests, which can help diagnose and monitor various medical conditions.
A bone fracture is a medical condition in which there is a partial or complete break in the continuity of a bone due to external or internal forces. Fractures can occur in any bone in the body and can vary in severity from a small crack to a shattered bone. The symptoms of a bone fracture typically include pain, swelling, bruising, deformity, and difficulty moving the affected limb. Treatment for a bone fracture may involve immobilization with a cast or splint, surgery to realign and stabilize the bone, or medication to manage pain and prevent infection. The specific treatment approach will depend on the location, type, and severity of the fracture.
Fracture healing is the natural process by which a broken bone repairs itself. When a fracture occurs, the body responds by initiating a series of biological and cellular events aimed at restoring the structural integrity of the bone. This process involves the formation of a hematoma (a collection of blood) around the fracture site, followed by the activation of inflammatory cells that help to clean up debris and prepare the area for repair.
Over time, specialized cells called osteoblasts begin to lay down new bone matrix, or osteoid, along the edges of the broken bone ends. This osteoid eventually hardens into new bone tissue, forming a bridge between the fracture fragments. As this process continues, the callus (a mass of newly formed bone and connective tissue) gradually becomes stronger and more compact, eventually remodeling itself into a solid, unbroken bone.
The entire process of fracture healing can take several weeks to several months, depending on factors such as the severity of the injury, the patient's age and overall health, and the location of the fracture. In some cases, medical intervention may be necessary to help promote healing or ensure proper alignment of the bone fragments. This may include the use of casts, braces, or surgical implants such as plates, screws, or rods.
A hip fracture is a medical condition referring to a break in the upper part of the femur (thigh) bone, which forms the hip joint. The majority of hip fractures occur due to falls or direct trauma to the area. They are more common in older adults, particularly those with osteoporosis, a condition that weakens bones and makes them more prone to breaking. Hip fractures can significantly impact mobility and quality of life, often requiring surgical intervention and rehabilitation.
A femoral fracture is a medical term that refers to a break in the thigh bone, which is the longest and strongest bone in the human body. The femur extends from the hip joint to the knee joint and is responsible for supporting the weight of the upper body and allowing movement of the lower extremity. Femoral fractures can occur due to various reasons such as high-energy trauma, low-energy trauma in individuals with weak bones (osteoporosis), or as a result of a direct blow to the thigh.
Femoral fractures can be classified into different types based on their location, pattern, and severity. Some common types of femoral fractures include:
1. Transverse fracture: A break that occurs straight across the bone.
2. Oblique fracture: A break that occurs at an angle across the bone.
3. Spiral fracture: A break that occurs in a helical pattern around the bone.
4. Comminuted fracture: A break that results in multiple fragments of the bone.
5. Open or compound fracture: A break in which the bone pierces through the skin.
6. Closed or simple fracture: A break in which the bone does not pierce through the skin.
Femoral fractures can cause severe pain, swelling, bruising, and difficulty walking or bearing weight on the affected leg. Diagnosis typically involves a physical examination, medical history, and imaging tests such as X-rays or CT scans. Treatment may involve surgical intervention, including the use of metal rods, plates, or screws to stabilize the bone, followed by rehabilitation and physical therapy to restore mobility and strength.
A spinal fracture, also known as a vertebral compression fracture, is a break in one or more bones (vertebrae) of the spine. This type of fracture often occurs due to weakened bones caused by osteoporosis, but it can also result from trauma such as a car accident or a fall.
In a spinal fracture, the front part of the vertebra collapses, causing the height of the vertebra to decrease, while the back part of the vertebra remains intact. This results in a wedge-shaped deformity of the vertebra. Multiple fractures can lead to a hunched forward posture known as kyphosis or dowager's hump.
Spinal fractures can cause pain, numbness, tingling, or weakness in the back, legs, or arms, depending on the location and severity of the fracture. In some cases, spinal cord compression may occur, leading to more severe symptoms such as paralysis or loss of bladder and bowel control.
Fracture fixation, internal, is a surgical procedure where a fractured bone is fixed using metal devices such as plates, screws, or rods that are implanted inside the body. This technique helps to maintain the alignment and stability of the broken bone while it heals. The implants may be temporarily or permanently left inside the body, depending on the nature and severity of the fracture. Internal fixation allows for early mobilization and rehabilitation, which can result in a faster recovery and improved functional outcome.
A comminuted fracture is a type of bone break where the bone is shattered into three or more pieces. This type of fracture typically occurs after high-energy trauma, such as a car accident or a fall from a great height. Commminuted fractures can also occur in bones that are weakened by conditions like osteoporosis or cancer. Because of the severity and complexity of comminuted fractures, they often require extensive treatment, which may include surgery to realign and stabilize the bone fragments using metal screws, plates, or rods.
Fracture fixation is a surgical procedure in orthopedic trauma surgery where a fractured bone is stabilized using various devices and techniques to promote proper healing and alignment. The goal of fracture fixation is to maintain the broken bone ends in correct anatomical position and length, allowing for adequate stability during the healing process.
There are two main types of fracture fixation:
1. Internal fixation: In this method, metal implants like plates, screws, or intramedullary rods are inserted directly into the bone to hold the fragments in place. These implants can be either removed or left in the body once healing is complete, depending on the type and location of the fracture.
2. External fixation: This technique involves placing pins or screws through the skin and into the bone above and below the fracture site. These pins are then connected to an external frame that maintains alignment and stability. External fixators are typically used when there is significant soft tissue damage, infection, or when internal fixation is not possible due to the complexity of the fracture.
The choice between internal and external fixation depends on various factors such as the type and location of the fracture, patient's age and overall health, surgeon's preference, and potential complications. Both methods aim to provide a stable environment for bone healing while minimizing the risk of malunion, nonunion, or deformity.
Osteoporotic fractures are breaks or cracks in bones that occur as a result of osteoporosis, a condition characterized by weak and brittle bones. Osteoporosis causes bones to lose density and strength, making them more susceptible to fractures, even from minor injuries or falls.
The most common types of osteoporotic fractures are:
1. Hip fractures: These occur when the upper part of the thigh bone (femur) breaks, often due to a fall. Hip fractures can be serious and may require surgery and hospitalization.
2. Vertebral compression fractures: These occur when the bones in the spine (vertebrae) collapse, causing height loss, back pain, and deformity. They are often caused by everyday activities, such as bending or lifting.
3. Wrist fractures: These occur when the bones in the wrist break, often due to a fall. Wrist fractures are common in older adults with osteoporosis.
4. Other fractures: Osteoporotic fractures can also occur in other bones, such as the pelvis, ribs, and humerus (upper arm bone).
Prevention is key in managing osteoporosis and reducing the risk of osteoporotic fractures. This includes getting enough calcium and vitamin D, engaging in regular weight-bearing exercise, avoiding smoking and excessive alcohol consumption, and taking medications as prescribed by a healthcare provider.
A radius fracture is a break in the bone that runs from the wrist to the elbow, located on the thumb side of the forearm. Radius fractures can occur as a result of a fall, direct blow to the forearm, or a high-energy collision such as a car accident. There are various types of radius fractures, including:
1. Distal radius fracture: A break at the end of the radius bone, near the wrist joint, which is the most common type of radius fracture.
2. Radial shaft fracture: A break in the middle portion of the radius bone.
3. Radial head and neck fractures: Breaks in the upper part of the radius bone, near the elbow joint.
4. Comminuted fracture: A complex radius fracture where the bone is broken into multiple pieces.
5. Open (compound) fracture: A radius fracture with a wound or laceration in the skin, allowing for communication between the outside environment and the fractured bone.
6. Intra-articular fracture: A radius fracture that extends into the wrist joint or elbow joint.
7. Torus (buckle) fracture: A stable fracture where one side of the bone is compressed, causing it to buckle or bend, but not break completely through.
Symptoms of a radius fracture may include pain, swelling, tenderness, bruising, deformity, limited mobility, and in some cases, numbness or tingling in the fingers. Treatment options depend on the type and severity of the fracture but can range from casting to surgical intervention with implant fixation.
Spontaneous fractures are bone breaks that occur without any identifiable trauma or injury. They are typically caused by underlying medical conditions that weaken the bones, making them more susceptible to breaking under normal stress or weight. The most common cause of spontaneous fractures is osteoporosis, a condition characterized by weak and brittle bones. Other potential causes include various bone diseases, certain cancers, long-term use of corticosteroids, and genetic disorders affecting bone strength.
It's important to note that while the term "spontaneous" implies that the fracture occurred without any apparent cause, it is usually the result of an underlying medical condition. Therefore, if you experience a spontaneous fracture, seeking medical attention is crucial to diagnose and manage the underlying cause to prevent future fractures and related complications.
Stress fractures are defined as small cracks or severe bruising in bones that occur from repetitive stress or overuse. They most commonly occur in weight-bearing bones, such as the legs and feet, but can also occur in the arms, hips, and back. Stress fractures differ from regular fractures because they typically do not result from a single, traumatic event. Instead, they are caused by repeated stress on the bone that results in microscopic damage over time. Athletes, military personnel, and individuals who engage in high-impact activities or have weak bones (osteoporosis) are at increased risk of developing stress fractures. Symptoms may include pain, swelling, tenderness, and difficulty walking or bearing weight on the affected bone.
A femoral neck fracture is a type of hip fracture that occurs in the narrow, vertical section of bone just below the ball of the femur (thigh bone) that connects to the hip socket. This area is called the femoral neck. Femoral neck fractures can be categorized into different types based on their location and the direction of the fractured bone.
These fractures are typically caused by high-energy trauma, such as car accidents or falls from significant heights, in younger individuals. However, in older adults, particularly those with osteoporosis, femoral neck fractures can also result from low-energy trauma, like a simple fall from standing height.
Femoral neck fractures are often serious and require prompt medical attention. Treatment usually involves surgery to realign and stabilize the broken bone fragments, followed by rehabilitation to help regain mobility and strength. Potential complications of femoral neck fractures include avascular necrosis (loss of blood flow to the femoral head), nonunion or malunion (improper healing), and osteoarthritis in the hip joint.
An ulna fracture is a break in the ulna bone, which is one of the two long bones in the forearm. The ulna is located on the pinky finger side of the forearm and functions to support the elbow joint and assist in rotation and movement of the forearm. Ulna fractures can occur at various points along the bone, including the shaft, near the wrist, or at the elbow end of the bone. Symptoms may include pain, swelling, bruising, tenderness, deformity, limited mobility, and in some cases, numbness or tingling in the fingers. Treatment typically involves immobilization with a cast or splint, followed by rehabilitation exercises to restore strength and range of motion. In severe cases, surgery may be required to realign and stabilize the fractured bone.
Intramedullary fracture fixation is a surgical technique used to stabilize and align bone fractures. In this procedure, a metal rod or nail is inserted into the marrow cavity (intramedullary canal) of the affected bone, spanning the length of the fracture. The rod is then secured to the bone using screws or other fixation devices on either side of the fracture. This provides stability and helps maintain proper alignment during the healing process.
The benefits of intramedullary fixation include:
1. Load sharing: The intramedullary rod shares some of the load bearing capacity with the bone, which can help reduce stress on the healing bone.
2. Minimal soft tissue dissection: Since the implant is inserted through the medullary canal, there is less disruption to the surrounding muscles, tendons, and ligaments compared to other fixation methods.
3. Biomechanical stability: Intramedullary fixation provides rotational and bending stiffness, which helps maintain proper alignment of the fracture fragments during healing.
4. Early mobilization: Patients with intramedullary fixation can often begin weight bearing and rehabilitation exercises earlier than those with other types of fixation, leading to faster recovery times.
Common indications for intramedullary fracture fixation include long bone fractures in the femur, tibia, humerus, and fibula, as well as certain pelvic and spinal fractures. However, the choice of fixation method depends on various factors such as patient age, fracture pattern, location, and associated injuries.
Rib fractures are breaks or cracks in the bones that make up the rib cage, which is the protective structure around the lungs and heart. Rib fractures can result from direct trauma to the chest, such as from a fall, motor vehicle accident, or physical assault. They can also occur from indirect forces, such as during coughing fits in people with weakened bones (osteoporosis).
Rib fractures are painful and can make breathing difficult, particularly when taking deep breaths or coughing. In some cases, rib fractures may lead to complications like punctured lungs (pneumothorax) or collapsed lungs (atelectasis), especially if multiple ribs are broken in several places.
It is essential to seek medical attention for suspected rib fractures, as proper diagnosis and management can help prevent further complications and promote healing. Treatment typically involves pain management, breathing exercises, and, in some cases, immobilization or surgery.
A skull fracture is a break in one or more of the bones that form the skull. It can occur from a direct blow to the head, penetrating injuries like gunshot wounds, or from strong rotational forces during an accident. There are several types of skull fractures, including:
1. Linear Skull Fracture: This is the most common type, where there's a simple break in the bone without any splintering, depression, or displacement. It often doesn't require treatment unless it's near a sensitive area like an eye or ear.
2. Depressed Skull Fracture: In this type, a piece of the skull is pushed inward toward the brain. Surgery may be needed to relieve pressure on the brain and repair the fracture.
3. Diastatic Skull Fracture: This occurs along the suture lines (the fibrous joints between the skull bones) that haven't fused yet, often seen in infants and young children.
4. Basilar Skull Fracture: This involves fractures at the base of the skull. It can be serious due to potential injury to the cranial nerves and blood vessels located in this area.
5. Comminuted Skull Fracture: In this severe type, the bone is shattered into many pieces. These fractures usually require extensive surgical repair.
Symptoms of a skull fracture can include pain, swelling, bruising, bleeding (if there's an open wound), and in some cases, clear fluid draining from the ears or nose (cerebrospinal fluid leak). Severe fractures may cause brain injury, leading to symptoms like confusion, loss of consciousness, seizures, or neurological deficits. Immediate medical attention is necessary for any suspected skull fracture.
A mandibular fracture is a break or crack in the lower jaw (mandible) bone. It can occur at any point along the mandible, but common sites include the condyle (the rounded end near the ear), the angle (the curved part of the jaw), and the symphysis (the area where the two halves of the jaw meet in the front). Mandibular fractures are typically caused by trauma, such as a direct blow to the face or a fall. Symptoms may include pain, swelling, bruising, difficulty chewing or speaking, and malocclusion (misalignment) of the teeth. Treatment usually involves immobilization with wires or screws to allow the bone to heal properly.
A tooth fracture is a dental health condition characterized by a break or crack in the tooth structure. It can occur in different parts of the tooth, including the crown (the visible part), root, or filling. Tooth fractures can result from various factors such as trauma, biting or chewing on hard objects, grinding or clenching teeth, and having large, old amalgam fillings that weaken the tooth structure over time. Depending on the severity and location of the fracture, it may cause pain, sensitivity, or affect the tooth's functionality and appearance. Treatment options for tooth fractures vary from simple bonding to root canal treatment or even extraction in severe cases. Regular dental check-ups are essential for early detection and management of tooth fractures.
A compression fracture is a type of bone fracture that occurs when there is a collapse of a vertebra in the spine. This type of fracture is most commonly seen in the thoracic and lumbar regions of the spine. Compression fractures are often caused by weakened bones due to osteoporosis, but they can also result from trauma or tumors that weaken the bone.
In a compression fracture, the front part (anterior) of the vertebra collapses, while the back part (posterior) remains intact, causing the height of the vertebra to decrease. This can lead to pain, deformity, and decreased mobility. In severe cases, multiple compression fractures can result in a condition called kyphosis, which is an abnormal curvature of the spine that leads to a hunchback appearance.
Compression fractures are typically diagnosed through imaging tests such as X-rays, CT scans, or MRI scans. Treatment may include pain medication, bracing, physical therapy, or in some cases, surgery. Preventive measures such as maintaining a healthy diet, getting regular exercise, and taking medications to prevent or treat osteoporosis can help reduce the risk of compression fractures.
An intra-articular fracture is a type of fracture that involves the joint surface or articular cartilage of a bone. These types of fractures can occur in any joint, but they are most commonly seen in the weight-bearing joints such as the knee, ankle, and wrist.
Intra-articular fractures can be caused by high-energy trauma, such as motor vehicle accidents or falls from significant heights, or by low-energy trauma, such as a simple fall in older adults with osteoporosis.
These types of fractures are often complex and may involve displacement or depression of the joint surface, which can increase the risk of developing post-traumatic arthritis. Therefore, prompt diagnosis and appropriate treatment are essential to ensure optimal outcomes and minimize long-term complications. Treatment options for intra-articular fractures may include surgical fixation with plates, screws, or pins, as well as joint replacement in some cases.
Osteoporosis is a systemic skeletal disease characterized by low bone mass, deterioration of bone tissue, and disruption of bone architecture, leading to increased risk of fractures, particularly in the spine, wrist, and hip. It mainly affects older people, especially postmenopausal women, due to hormonal changes that reduce bone density. Osteoporosis can also be caused by certain medications, medical conditions, or lifestyle factors such as smoking, alcohol abuse, and a lack of calcium and vitamin D in the diet. The diagnosis is often made using bone mineral density testing, and treatment may include medication to slow bone loss, promote bone formation, and prevent fractures.
Bone plates are medical devices used in orthopedic surgery to stabilize and hold together fractured or broken bones during the healing process. They are typically made of surgical-grade stainless steel, titanium, or other biocompatible materials. The plate is shaped to fit the contour of the bone and is held in place with screws that are inserted through the plate and into the bone on either side of the fracture. This provides stability and alignment to the broken bones, allowing them to heal properly. Bone plates can be used to treat a variety of fractures, including those that are complex or unstable. After healing is complete, the bone plate may be left in place or removed, depending on the individual's needs and the surgeon's recommendation.
I believe you are referring to "bone pins" or "bone nails" rather than "bone nails." These terms are used in the medical field to describe surgical implants made of metal or biocompatible materials that are used to stabilize and hold together fractured bones during the healing process. They can also be used in spinal fusion surgery to provide stability and promote bone growth between vertebrae.
Bone pins or nails typically have a threaded or smooth shaft, with a small diameter that allows them to be inserted into the medullary canal of long bones such as the femur or tibia. They may also have a head or eyelet on one end that allows for attachment to external fixation devices or other surgical instruments.
The use of bone pins and nails has revolutionized orthopedic surgery, allowing for faster healing times, improved stability, and better functional outcomes for patients with fractures or spinal deformities.
Orbital fractures refer to breaks in the bones that make up the eye socket, also known as the orbit. These bones include the maxilla, zygoma, frontal bone, and palatine bone. Orbital fractures can occur due to trauma, such as a blunt force injury or a penetrating wound.
There are several types of orbital fractures, including:
1. Blowout fracture: This occurs when the thin bone of the orbital floor is broken, often due to a direct blow to the eye. The force of the impact can cause the eyeball to move backward, breaking the bone and sometimes trapping the muscle that moves the eye (the inferior rectus).
2. Blow-in fracture: This type of fracture involves the breakage of the orbital roof, which is the bone that forms the upper boundary of the orbit. It typically occurs due to high-impact trauma, such as a car accident or a fall from a significant height.
3. Direct fracture: A direct fracture happens when there is a break in one or more of the bones that form the walls of the orbit. This type of fracture can result from a variety of traumas, including motor vehicle accidents, sports injuries, and assaults.
4. Indirect fracture: An indirect fracture occurs when the force of an injury is transmitted to the orbit through tissues surrounding it, causing the bone to break. The most common type of indirect orbital fracture is a blowout fracture.
Orbital fractures can cause various symptoms, including pain, swelling, bruising, and double vision. In some cases, the fracture may also lead to enophthalmos (sinking of the eye into the orbit) or telecanthus (increased distance between the inner corners of the eyes). Imaging tests, such as CT scans, are often used to diagnose orbital fractures and determine the best course of treatment. Treatment may include observation, pain management, and in some cases, surgery to repair the fracture and restore normal function.
A Colles' fracture is a specific type of fracture in the distal end of the radius bone in the forearm, which is the larger of the two bones in the lower arm. This type of fracture occurs when the wrist is forcefully bent backward (dorsiflexion), often as a result of falling onto an outstretched hand.
In a Colles' fracture, the distal end of the radius bone breaks and is displaced downward and angulated backward, resulting in a characteristic "dinner fork" deformity. This type of fracture is more common in older individuals, particularly women with osteoporosis, but can also occur in younger people as a result of high-energy trauma.
Colles' fractures are typically treated with immobilization using a cast or splint to hold the bones in proper alignment while they heal. In some cases, surgery may be necessary to realign and stabilize the fracture, particularly if there is significant displacement or instability of the bone fragments.
Bony callus is a medical term that refers to the specialized tissue that forms in response to a bone fracture. It is a crucial part of the natural healing process, as it helps to stabilize and protect the broken bone while it mends.
When a bone is fractured, the body responds by initiating an inflammatory response, which triggers the production of various cells and signaling molecules that promote healing. As part of this process, specialized cells called osteoblasts begin to produce new bone tissue at the site of the fracture. This tissue is initially soft and pliable, allowing it to bridge the gap between the broken ends of the bone.
Over time, this soft callus gradually hardens and calcifies, forming a bony callus that helps to stabilize the fracture and provide additional support as the bone heals. The bony callus is typically composed of a mixture of woven bone (which is less organized than normal bone) and more structured lamellar bone (which is similar in structure to normal bone).
As the bone continues to heal, the bony callus may be gradually remodeled and reshaped by osteoclasts, which are specialized cells that break down and remove excess or unwanted bone tissue. This process helps to restore the bone's original shape and strength, allowing it to function normally again.
It is worth noting that excessive bony callus formation can sometimes lead to complications, such as stiffness, pain, or decreased range of motion in the affected limb. In some cases, surgical intervention may be necessary to remove or reduce the size of the bony callus and promote proper healing.
Periprosthetic fractures are defined as fractures that occur in close proximity to a prosthetic joint, such as those found in total hip or knee replacements. These types of fractures typically occur as a result of low-energy trauma, and can be caused by a variety of factors including osteoporosis, bone weakness, or loosening of the prosthetic implant.
Periprosthetic fractures are classified based on the location of the fracture in relation to the prosthesis, as well as the stability of the implant. Treatment options for periprosthetic fractures may include non-surgical management, such as immobilization with a brace or cast, or surgical intervention, such as open reduction and internal fixation (ORIF) or revision arthroplasty.
The management of periprosthetic fractures can be complex and requires careful consideration of various factors, including the patient's age, overall health status, bone quality, and functional needs. As such, these types of fractures are typically managed by orthopedic surgeons with experience in joint replacement surgery and fracture care.
Bone density refers to the amount of bone mineral content (usually measured in grams) in a given volume of bone (usually measured in cubic centimeters). It is often used as an indicator of bone strength and fracture risk. Bone density is typically measured using dual-energy X-ray absorptiometry (DXA) scans, which provide a T-score that compares the patient's bone density to that of a young adult reference population. A T-score of -1 or above is considered normal, while a T-score between -1 and -2.5 indicates osteopenia (low bone mass), and a T-score below -2.5 indicates osteoporosis (porous bones). Regular exercise, adequate calcium and vitamin D intake, and medication (if necessary) can help maintain or improve bone density and prevent fractures.
Bone screws are medical devices used in orthopedic and trauma surgery to affix bone fracture fragments or to attach bones to other bones or to metal implants such as plates, rods, or artificial joints. They are typically made of stainless steel or titanium alloys and have a threaded shaft that allows for purchase in the bone when tightened. The head of the screw may have a hexagonal or star-shaped design to allow for precise tightening with a screwdriver. Bone screws come in various shapes, sizes, and designs, including fully threaded, partially threaded, cannulated (hollow), and headless types, depending on their intended use and location in the body.
Wrist injuries refer to damages or traumas affecting the structures of the wrist, including bones, ligaments, tendons, muscles, and cartilage. These injuries can occur due to various reasons such as falls, accidents, sports-related impacts, or repetitive stress. Common types of wrist injuries include fractures (such as scaphoid fracture), sprains (like ligament tears), strains (involving muscles or tendons), dislocations, and carpal tunnel syndrome. Symptoms may include pain, swelling, tenderness, bruising, limited mobility, and in severe cases, deformity or numbness. Immediate medical attention is necessary for proper diagnosis and treatment to ensure optimal recovery and prevent long-term complications.