Poetry as Topic
Greek World
Air Bags
Rib Fractures
Medicine in Literature
Wounds, Nonpenetrating
Accidents, Traffic
Wounds and Injuries
Brain Injuries
Spinal Cord Injuries
Reperfusion Injury
Injury Severity Score
Non-fatal injuries sustained by seatbelt wearers: a comparative study. (1/363)
The injuries sustained by 969 drivers and front-seat passengers in road-traffic accidents were studied. Altogether 196 (20-2%) of the drivers and passengers were wearing seat belts and 773 (79-8%) were not. The injuries among the two groups differed greatly in both severity and distribution. A total of 54 (27-6%) of the seatbelt wearers sustained one or more fractures compared with 300 (38-8%) of the non-wearers, and 18 (9-2%) of the seatbelt wearers were severely injured compared with 300 (38-8%) of the non-wearers. Soft-tissue injuries to the face were sustained by only 29 (14-8%) of the seatbelt wearers compared with 425 (55%) of the non-wearers. Since wearing seatbelts may become compulsory, the type and pattern of injuries to be expected in wearers should be appreciated. (+info)Prospective, randomized comparison of epidural versus parenteral opioid analgesia in thoracic trauma. (2/363)
OBJECTIVE: To evaluate systemic versus epidural opioid administration for analgesia in patients sustaining thoracic trauma. SUMMARY BACKGROUND DATA: The authors have previously shown that epidural analgesia significantly reduces the pain associated with significant chest wall injury. Recent studies report that epidural analgesia is associated with a lower catecholamine and cytokine response in patients undergoing elective thoracotomy compared with patient-controlled analgesia (PCA). This study compares the effect of epidural analgesia and PCA on pain relief, pulmonary function, cathechol release, and immune response in patients sustaining significant thoracic trauma. METHODS: Patients (ages 18 to 60 years) sustaining thoracic injury were prospectively randomized to receive epidural analgesia or PCA during an 18-month period. Levels of serum interleukin (IL)-1beta, IL-2, IL-6, IL-8, and tumor necrosis factor-alpha (TNF-alpha) were measured every 12 hours for 3 days by enzyme-linked immunosorbent assay. Urinary catecholamine levels were measured every 24 hours. Independent observers assessed pulmonary function using standard techniques and analgesia using a verbal rating score. RESULTS: Twenty-four patients of the 34 enrolled completed the study. Age, injury severity score, thoracic abbreviated injury score, and length of hospital stay did not differ between the two groups. There was no significant difference in plasma levels of IL-1beta, IL-2, IL-6, or TNF-alpha or urinary catecholamines between the two groups at any time point. Epidural analgesia was associated with significantly reduced plasma levels of IL-8 at days 2 and 3, verbal rating score of pain on days 1 and 3, and maximal inspiratory force and tidal volume on day 3 versus PCA. CONCLUSIONS: Epidural analgesia significantly reduced pain with chest wall excursion compared with PCA. The route of analgesia did not affect the catecholamine response. However, serum levels of IL-8, a proinflammatory chemoattractant that has been implicated in acute lung injury, were significantly reduced in patients receiving epidural analgesia on days 2 and 3. This may have important clinical implications because lower levels of IL-8 may reduce infectious or inflammatory complications in the trauma patient. Also, tidal volume and maximal inspiratory force were improved with epidural analgesia by day 3. These results demonstrate that epidural analgesia is superior to PCA in providing analgesia, improving pulmonary function, and modifying the immune response in patients with severe chest injury. (+info)Injuries to riders in the cross country phase of eventing: the importance of protective equipment. (3/363)
OBJECTIVES: To determine the distribution of injuries in the eventing discipline of equestrian sports and the effectiveness of the protective equipment worn. METHODS: Data on all injuries sustained in the cross country phase over fixed obstacles were collected from 54 days of competition from 1992 to 1997. This involved 16,940 rides. RESULTS: Data on a total of 193 injuries were collected, which included two deaths. This represents an injury rate of 1.1%. Head and facial injuries represented the largest group (31%), with one third of these requiring treatment in hospital. All riders were wearing protective helmets and body protectors. CONCLUSIONS: Eventing is one of the most dangerous equestrian sports. Improved protective equipment, which is mandatory for 1999, should reduce the severity of these injuries. (+info)Aortic rupture as a result of low velocity crush. (4/363)
A case of aortic disruption in a 35 year old lorry driver is described. This occurred as a result of a low velocity crushing force. Clinicians should be aware that this mechanism of injury may result in aortic disruption as well as the more commonly mentioned severe deceleration force. (+info)Selective activation of the K(+)(ATP) channel is a mechanism by which sudden death is produced by low-energy chest-wall impact (Commotio cordis). (5/363)
BACKGROUND: Sudden death due to relatively innocent chest-wall impact has been described in young individuals (commotio cordis). In our previously reported swine model of commotio cordis, ventricular fibrillation (with T-wave strikes) and ST-segment elevation (with QRS strikes) were produced by 30-mph baseball impacts to the precordium. Because activation of the K(+)(ATP) channel has been implicated in the pathogenesis of ST elevation and ventricular fibrillation in myocardial ischemia, we hypothesized that this channel could be responsible for the electrophysiologic findings in our experimental model and in victims of commotio cordis. METHODS AND RESULTS: In the initial experiment, 6 juvenile swine were given 0.5 mg/kg IV glibenclamide, a selective inhibitor of the K(+)(ATP) channel, and chest impact was given on the QRS. The results of these strikes were compared with animals in which no glibenclamide was given. In the second phase, 20 swine were randomized to receive glibenclamide or a control vehicle (in a double-blind fashion), with chest impact delivered just before the T-wave peak. With QRS impacts, the maximal ST elevation was significantly less in those animals given glibenclamide (0.16+/-0.10 mV) than in controls (0.35+/-0.20 mV; P=0.004). With T-wave impacts, the animals that received glibenclamide had significantly fewer occurrences of ventricular fibrillation (1 episode in 27 impacts; 4%) than controls (6 episodes in 18 impacts; 33%; P=0.01). CONCLUSIONS: In this experimental model of commotio cordis, blockade of the K(+)(ATP) channel reduced the incidence of ventricular fibrillation and the magnitude of ST-segment elevation. Therefore, selective K(+)(ATP) channel activation may be a pivotal mechanism in sudden death resulting from low-energy chest-wall trauma in young people during sporting activities. (+info)Management of penetrating cervicomediastinal venous trauma. (6/363)
OBJECTIVES: to evaluate the results of management of penetrating cervicomediastinal venous trauma. DESIGN: retrospective study. Materials forty-nine consecutive patients with cervical and thoracic venous injuries treated at a tertiary hospital between 1991 and 1997. Method patients identified from a computerised database and data extracted from case records. RESULTS: forty-five patients were male and the mean age was 25.3 years. Forty injuries were due to stabs and 9 to gunshots. 22 patients were shocked, 25 actively bleeding and 31 were anaemic. Veins injured were internal jugular in 25, subclavian in 15, brachiocephalic in 6, and superior vena cava in 3. Injured veins were ligated in 25 cases and repaired by lateral suture in 22. No complex repairs were performed. There were 8 perioperative deaths and 5 cases of transient postoperative oedema. Venous ligation was not associated with increased risk of postoperative oedema. CONCLUSIONS: ligation is an acceptable form of treatment of cervicomediastinal venous injuries in the presence of haemodynamic instability, or where complex methods of repair would otherwise be necessary. (+info)Complications of tube thoracostomy in trauma. (7/363)
OBJECTIVE: To assess the complication rate of tube thoracostomy in trauma. To consider whether this rate is high enough to support a selective reduction in the indications for tube thoracostomy in trauma. METHODS: A retrospective case series of all trauma patients who underwent tube thoracostomy during a 12 month period at a large UK teaching hospital with an accident and emergency (A&E) department seeing in excess of 125,000 new patients/year. These patients were identified using the hospital audit department computerised retrieval system supplemented by a hand search of both the data collected for the Major Trauma Outcome Study and the A&E admission unit log book. The notes were assessed with regard to the incidence of complications, which were divided into insertional, infective, and positional. RESULTS: Fifty seven chest drains were placed in 47 patients over the 12 month period. Seven patients who died within 48 hours of drain insertion were excluded. The commonest indications for tube thoracostomy were pneumothorax (54%) and haemothorax (20%); 90% of tubes were placed as a result of blunt trauma. The overall complication rate of the procedure was 30%. There were no insertional complications and only one (2%) major complication, which was empyema thoracis. CONCLUSION: This study reveals no persuasive evidence to support a selective reduction in the indications for tube thoracostomy in trauma. A larger study to confirm or refute these findings must be performed before any change in established safe practice. (+info)Defining GERD. (8/363)
"It is not the death of GERD that I seek, but that it turns from its evil ways and follows the path of righteousness." The reflux world is fully aware of what GERD is and what GERD does. What the world does not know, however, is the answer to the most important yet least asked question surrounding GERD's raison-d'etre: Why is GERD here and why do we have it? What GERD is: abnormal gastric reflux into the esophagus that causes any type of mischief. What GERD does: causes discomfort and/or pain with or without destroying the mucosa; causes stricture or stenosis, preventing food from being swallowed; sets the stage for the development of esophageal adenocarcinoma; invades the surrounding lands to harass the peaceful oropharyngeal, laryngeal and broncho-pulmonary territories; reminds us that we are not only human, but that we are dust and ashes. Why GERD is here: We propose three separate and distinct etiologies of GERD, and we offer the following three hypotheses to explain why, after 1.5 million years of standing erect, we have evolved into a species (specifically Homosapiens sapiens) that is destined to live with the scourge of GERD. Hypothesis 1: congenital. The antireflux barrier, comprising the smooth-muscled lower esophageal sphincter, the skeletal-muscled right crural diaphragm and the phreno-esophageal ligament does not completely develop due to a developmental anomaly or incomplete gestation. Hypothesis 2: acute trauma: The antireflux barrier in adults suffering acute traumatic injury to the abdomen or chest is permanently disrupted by unexpected forces, such as motor vehicle accidents (with steering wheel crush impact), blows to the abdomen (from activities such as boxing, etc.), heavy lifting or moving (e.g., pianos, refrigerators) or stress positions (e.g., hand stands on parallel gym bars). The trauma creates a hiatal hernia that renders the antireflux mechanism useless and incapable of preventing GERD. Hypothesis 3: chronic trauma: The antireflux barrier in children and adults is gradually weakened over time as a result of chronic straining to defecate and straining in an unphysiologic position, both of which stem from our modern day habits of eating a low-fiber diet and living on the high-seated toilet. We suggest that the chronic traumatic hiatal hernia is (a) the cause of more than 90 percent of the GERD that stalks the Western world; (b) is a direct result of abandoning the popular and worldwide practice of squatting to socialize, eat and defecate; and (c) is our just reward for adopting the "civilized" high sitting position on chairs and modern toilets. (+info)Thoracic injuries refer to damages or traumas that occur in the thorax, which is the part of the body that contains the chest cavity. The thorax houses vital organs such as the heart, lungs, esophagus, trachea, and major blood vessels. Thoracic injuries can range from blunt trauma, caused by impacts or compressions, to penetrating trauma, resulting from stabbing or gunshot wounds. These injuries may cause various complications, including but not limited to:
1. Hemothorax - bleeding into the chest cavity
2. Pneumothorax - collapsed lung due to air accumulation in the chest cavity
3. Tension pneumothorax - a life-threatening condition where trapped air puts pressure on the heart and lungs, impairing their function
4. Cardiac tamponade - compression of the heart caused by blood or fluid accumulation in the pericardial sac
5. Rib fractures, which can lead to complications like punctured lungs or internal bleeding
6. Tracheobronchial injuries, causing air leaks and difficulty breathing
7. Great vessel injuries, potentially leading to massive hemorrhage and hemodynamic instability
Immediate medical attention is required for thoracic injuries, as they can quickly become life-threatening due to the vital organs involved. Treatment may include surgery, chest tubes, medications, or supportive care, depending on the severity and type of injury.
I'm sorry for any confusion, but "Poetry as Topic" is not a term that has a specific medical definition. It seems to be a subject that falls under the humanities or arts, rather than being a medical concept. Poetry can sometimes be used in therapeutic settings as a form of expressive art therapy, but it is not a medical diagnosis or treatment. If you have any questions related to medicine or health, I'd be happy to try and help answer those for you!
I believe there may be some confusion in your question as "Greek World" is not a medical term. If you are referring to the ancient Greek civilization, it was a significant period in human history that greatly contributed to the development of various fields including medicine. The ancient Greeks, particularly Hippocrates and his followers, are often referred to as the "Fathers of Medicine." They made substantial contributions to the field through their observations, theories, and practices which formed the foundation of much of Western medical thought. However, "Greek World" itself does not have a medical definition.
An air bag is a type of vehicle safety device that uses a inflatable cushion to protect occupants from collision forces in the event of a car accident. When a crash occurs, a sensor triggers the inflation of the air bag, which then rapidly deploys and fills the space between the driver or passenger and the steering wheel or dashboard. This helps to absorb the impact and reduce the risk of injury. Air bags are typically installed in the steering wheel, dashboard, and sides of the vehicle, and they can significantly improve safety in the event of a crash. However, air bags can also pose a risk of injury if they deploy improperly or in certain types of crashes, so it is important for drivers to understand how they work and when they are most effective.
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.
"Medicine in Literature" is not a medical term per se, but rather a field of study that explores the representation and interpretation of medicine, health, and illness in literature. It is an interdisciplinary approach that combines literary analysis with medical humanities to understand the cultural, historical, and social contexts of medical practices, theories, and experiences as depicted in various forms of literature. This field often examines how literature reflects and shapes societal attitudes towards health, disease, and medical care, and how it can contribute to medical education and empathic understanding of patients' experiences.
Nonpenetrating wounds are a type of trauma or injury to the body that do not involve a break in the skin or underlying tissues. These wounds can result from blunt force trauma, such as being struck by an object or falling onto a hard surface. They can also result from crushing injuries, where significant force is applied to a body part, causing damage to internal structures without breaking the skin.
Nonpenetrating wounds can cause a range of injuries, including bruising, swelling, and damage to internal organs, muscles, bones, and other tissues. The severity of the injury depends on the force of the trauma, the location of the impact, and the individual's overall health and age.
While nonpenetrating wounds may not involve a break in the skin, they can still be serious and require medical attention. If you have experienced blunt force trauma or suspect a nonpenetrating wound, it is important to seek medical care to assess the extent of the injury and receive appropriate treatment.
Traffic accidents are incidents that occur when a vehicle collides with another vehicle, a pedestrian, an animal, or a stationary object, resulting in damage or injury. These accidents can be caused by various factors such as driver error, distracted driving, drunk driving, speeding, reckless driving, poor road conditions, and adverse weather conditions. Traffic accidents can range from minor fender benders to severe crashes that result in serious injuries or fatalities. They are a significant public health concern and cause a substantial burden on healthcare systems, emergency services, and society as a whole.
A wound is a type of injury that occurs when the skin or other tissues are cut, pierced, torn, or otherwise broken. Wounds can be caused by a variety of factors, including accidents, violence, surgery, or certain medical conditions. There are several different types of wounds, including:
* Incisions: These are cuts that are made deliberately, often during surgery. They are usually straight and clean.
* Lacerations: These are tears in the skin or other tissues. They can be irregular and jagged.
* Abrasions: These occur when the top layer of skin is scraped off. They may look like a bruise or a scab.
* Punctures: These are wounds that are caused by sharp objects, such as needles or knives. They are usually small and deep.
* Avulsions: These occur when tissue is forcibly torn away from the body. They can be very serious and require immediate medical attention.
Injuries refer to any harm or damage to the body, including wounds. Injuries can range from minor scrapes and bruises to more severe injuries such as fractures, dislocations, and head trauma. It is important to seek medical attention for any injury that is causing significant pain, swelling, or bleeding, or if there is a suspected bone fracture or head injury.
In general, wounds and injuries should be cleaned and covered with a sterile bandage to prevent infection. Depending on the severity of the wound or injury, additional medical treatment may be necessary. This may include stitches for deep cuts, immobilization for broken bones, or surgery for more serious injuries. It is important to follow your healthcare provider's instructions carefully to ensure proper healing and to prevent complications.
A brain injury is defined as damage to the brain that occurs following an external force or trauma, such as a blow to the head, a fall, or a motor vehicle accident. Brain injuries can also result from internal conditions, such as lack of oxygen or a stroke. There are two main types of brain injuries: traumatic and acquired.
Traumatic brain injury (TBI) is caused by an external force that results in the brain moving within the skull or the skull being fractured. Mild TBIs may result in temporary symptoms such as headaches, confusion, and memory loss, while severe TBIs can cause long-term complications, including physical, cognitive, and emotional impairments.
Acquired brain injury (ABI) is any injury to the brain that occurs after birth and is not hereditary, congenital, or degenerative. ABIs are often caused by medical conditions such as strokes, tumors, anoxia (lack of oxygen), or infections.
Both TBIs and ABIs can range from mild to severe and may result in a variety of physical, cognitive, and emotional symptoms that can impact a person's ability to perform daily activities and function independently. Treatment for brain injuries typically involves a multidisciplinary approach, including medical management, rehabilitation, and supportive care.
Athletic injuries are damages or injuries to the body that occur while participating in sports, physical activities, or exercise. These injuries can be caused by a variety of factors, including:
1. Trauma: Direct blows, falls, collisions, or crushing injuries can cause fractures, dislocations, contusions, lacerations, or concussions.
2. Overuse: Repetitive motions or stress on a particular body part can lead to injuries such as tendonitis, stress fractures, or muscle strains.
3. Poor technique: Using incorrect form or technique during exercise or sports can put additional stress on muscles, joints, and ligaments, leading to injury.
4. Inadequate warm-up or cool-down: Failing to properly prepare the body for physical activity or neglecting to cool down afterwards can increase the risk of injury.
5. Lack of fitness or flexibility: Insufficient strength, endurance, or flexibility can make individuals more susceptible to injuries during sports and exercise.
6. Environmental factors: Extreme weather conditions, poor field or court surfaces, or inadequate equipment can contribute to the risk of athletic injuries.
Common athletic injuries include ankle sprains, knee injuries, shoulder dislocations, tennis elbow, shin splints, and concussions. Proper training, warm-up and cool-down routines, use of appropriate protective gear, and attention to technique can help prevent many athletic injuries.
Spinal cord injuries (SCI) refer to damage to the spinal cord that results in a loss of function, such as mobility or feeling. This injury can be caused by direct trauma to the spine or by indirect damage resulting from disease or degeneration of surrounding bones, tissues, or blood vessels. The location and severity of the injury on the spinal cord will determine which parts of the body are affected and to what extent.
The effects of SCI can range from mild sensory changes to severe paralysis, including loss of motor function, autonomic dysfunction, and possible changes in sensation, strength, and reflexes below the level of injury. These injuries are typically classified as complete or incomplete, depending on whether there is any remaining function below the level of injury.
Immediate medical attention is crucial for spinal cord injuries to prevent further damage and improve the chances of recovery. Treatment usually involves immobilization of the spine, medications to reduce swelling and pressure, surgery to stabilize the spine, and rehabilitation to help regain lost function. Despite advances in treatment, SCI can have a significant impact on a person's quality of life and ability to perform daily activities.
Reperfusion injury is a complex pathophysiological process that occurs when blood flow is restored to previously ischemic tissues, leading to further tissue damage. This phenomenon can occur in various clinical settings such as myocardial infarction (heart attack), stroke, or peripheral artery disease after an intervention aimed at restoring perfusion.
The restoration of blood flow leads to the generation of reactive oxygen species (ROS) and inflammatory mediators, which can cause oxidative stress, cellular damage, and activation of the immune system. This results in a cascade of events that may lead to microvascular dysfunction, capillary leakage, and tissue edema, further exacerbating the injury.
Reperfusion injury is an important consideration in the management of ischemic events, as interventions aimed at restoring blood flow must be carefully balanced with potential harm from reperfusion injury. Strategies to mitigate reperfusion injury include ischemic preconditioning (exposing the tissue to short periods of ischemia before a prolonged ischemic event), ischemic postconditioning (applying brief periods of ischemia and reperfusion after restoring blood flow), remote ischemic preconditioning (ischemia applied to a distant organ or tissue to protect the target organ), and pharmacological interventions that scavenge ROS, reduce inflammation, or improve microvascular function.
The Injury Severity Score (ISS) is a medical scoring system used to assess the severity of trauma in patients with multiple injuries. It's based on the Abbreviated Injury Scale (AIS), which classifies each injury by body region on a scale from 1 (minor) to 6 (maximum severity).
The ISS is calculated by summing the squares of the highest AIS score in each of the three most severely injured body regions. The possible ISS ranges from 0 to 75, with higher scores indicating more severe injuries. An ISS over 15 is generally considered a significant injury, and an ISS over 25 is associated with a high risk of mortality. It's important to note that the ISS has limitations, as it doesn't consider the number or type of injuries within each body region, only the most severe one.
Leg injuries refer to damages or harm caused to any part of the lower extremity, including the bones, muscles, tendons, ligaments, blood vessels, and other soft tissues. These injuries can result from various causes such as trauma, overuse, or degenerative conditions. Common leg injuries include fractures, dislocations, sprains, strains, contusions, and cuts. Symptoms may include pain, swelling, bruising, stiffness, weakness, or difficulty walking. The specific treatment for a leg injury depends on the type and severity of the injury.