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 28,200 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A statistical analysis of the case material at the Intensive Care Unit, Freiburg, for the years 1975 and 1976 established that 40% and 39% respectively of patients with multiple injuries had also suffered a chest trauma and that the latter was the direct cause of respiratory insufficiency in 61% (1975) and 57% (1976) of patients in need of controlled respiration, i.e. respiratory insufficiency dominated the clinical and pathophysiological picture. The causes were: restricted respiratory movements due to pain, compression of the lungs or pathological changes in the injured lung, and they affected the normal gaseous exchange in a variety of ways. Alveolar hypoventilation with disturbance of ventilation-perfusion, increase in the functional shunt volume, rise in the functional dead space combined with reduced functional residual capacity and compliance result, if left uncorrected, in a drastic increase of resistance on the part of the pulmonary vessels and finally in, often fatal, hyoxaemia and hypercapnia. Regular estimations of the arterial blood gases in air and pure oxygen, of the arterio-alveolar difference in oxygen pressure, shunt volume, dead space and effective compliance of the chest wall and lungs are, therefore, essential. Treatment in an intensive care unit comprises the relief of any acute condition, such as tension pneumothorax, haemothorax, and general measures. Means to relieve pain in patients whose chest injuries are not sufficiently severe to require artificial ventilation are: intercostal blocking, acupuncture or peridural analgesia; efficient breathing exercises are important. The indications for artificial ventilation should be interpreted generously and the decision to perform it should be made at an early stage. The technique is determined by the type of pathological changes in the gaseous exchange and should aim at restoring normal conditions as far as possible.
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PMID:[Intensive care in chest trauma (author's transl)]. 46 37

Adequate prehospital care of the severely traumatised patient is important to prevent or attenuate early as well as late life threatening complications, such as tissue hypoxia, ischemia/reperfusion injury and finally multiple organ failure. A mismatch of oxygen supply and oxygen demand is a hallmark in the pathophysiology of multiple trauma. Oxygen supply may be diminished by the following factors: shock-related decrease of cardiac output, anemia and hypoxia. On the other hand, oxygen demand may be increased by pain, panic, and agitation. Hence, it is a central point in prehospital care to reduce this supply-demand imbalance by identification and prompt reversal of the underlying causes. Most often, shock is caused by hypovolaemia and tissue injury ("traumatic-hemorrhagic shock"). However, shock may also be a result of central nervous system injury (neurogenic shock as a special form of distributive shock) or circulatory obstruction, e.g tension pneumothorax or cardiac tamponade (obstructive shock). Volume resuscitation by means of crystalloid or colloid solutions is an essential part in the therapy of the traumatic-haemorrhagic shock. In addition, catecholamines may be necessary in order to achieve an adequate arterial pressure. However, if bleeding cannot be controlled in the prehospital setting, only moderate volume support and permissive hypotension as well as rapid transportation into the next hospital may be preferable. This may be the case in penetrating thoracic or abdominal injuries as well as in traumatic amputations of the proximal limb. On the contrary, in patients with severe head injury, hypotension must be avoided by all means. Obstructive shock has to be treated urgently by insertion of a chest drain or drainage of the pericardium, respectively. Under all circumstances, it is an essential part of prehospital therapy to provide sufficient analgesia as soon as possible. Prehospital anesthesia, combined with artificial ventilation may be necessary for optimal patient management. Furthermore, ventilatory support is indicated when respiratory failure, loss of consciousness, or severe shock are present. Additional oxygen should be given whenever possible, even in the absence of an overt hypoxic state. Important additional measures are cervical spine immobilisation and reposition as well as splinting of long bone fractures or luxations, in order to avoid secondary injury of the spinal cord or ongoing tissue and vascular damage.
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PMID:[Emergency management of polytrauma patients]. 902 49

Blunt chest trauma is the leading cause of thoracic injuries in Germany, penetrating chest injuries are rare. Hereby, single or multiple rib fractures, hemato-pneumothorax and pulmonary contusion represent the most common injuries. The early management of thoracic injuries consists of detection and sufficient therapy of acute life threatening situations like tension pneumothorax, acute respiratory insufficiency or severe intrathoracic bleeding. Most of the isolated thoracic injuries are adequately treated by conservative means, sufficient analgesia, drainage of intrapleural air or blood, physiotherapy and clearance of bronchial secretions provided; operative intervention is rarely indicated. In multiple injured patients however, severe blunt chest trauma and especially pulmonary contusion negatively affects outcome with a significant increase of morbidity and mortality. Hence, patients with this combination of pulmonary injuries, such as lung contusion and associated severe injuries, carry a particular high risk of respiratory failure, ARDS and MOF with a considerable mortality. Therefore, early exact diagnosis of all thoracic injuries is essential and can be achieved by thoracic computed tomography, which becomes more and more popular in this setting. Early intubation and PEEP-ventilation, alternate prone and supine positioning of multiple injured patients with lung contusion and differentiated concepts of volume- and catecholamine therapy represent the basic therapeutic principles. Additionally, the entire early trauma management of multiple injured patients must focus on the presence of pulmonary contusion. Every additional burden on their pulmonary microvascular system like microembolisation during femoral nailing, the trauma burden of extended surgery or mediator release in septic states may cause rapid decompensation and organ failure and therefore, has to be avoided.
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PMID:[Thoracic trauma]. 961 9

Diagnostic and therapeutic potentials and our first two-year experience with video-assisted thoracic surgery (VATS) are reported. From May 1995 to April 1997, at the Department of Surgery, University Hospital Split, VATS approach was planned in 55 cases (recurrent pneumothorax in 23, tension pneumothorax in 1, traumatic effusion in 5, malignant metastatic lung tumor in 1, benignant lung tumor in 11, traumatic effusion in 5, suspected mediastinal lymph nodes in 4, long lasting unconfirmed pleural effusion in 9, foreign body in 1, mediastanal cyst in 1). Of these, 48 procedures (87.2%) were performed using VATS (diagnostic thoracoscopy in 12, wedge resection with or without pleural abrasion in 21, partial pleurectomy in 1, decortications in 3, mediastinal lymph nodes biopsy in 4, lung biopsy in 7). Seven patients (12.7%) underwent conventional posterolateral thoracotomy. Complications included persistent air leak in three patients, prolonged bleeding in one patient and supraventricular tachycardia in one patient. The mean duration of chest tube drainage after the procedure was 3.7 days (range 2 to 19 days), and mean hospital stay was 5.1 days (range 3 to 15 days). All patients received routine antimicrobial chemoprophylaxis with single-dose ceftriaxone 2 g intravenously immediately prior to the surgery, and average postoperative patient-controlled analgesia with buprenorphine 0.15 mg. We conclude that VATS is a very useful alternative to conventional thoracotomy in managing cases of exploration, recurrent spontaneous pneumothorax, benign pulmonary lesions, solitary pulmonary nodes, early decortications and different intrathoracic biopsies.
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PMID:[Our initial experience with video-assisted thoracoscopic surgery (VATS)]. 981 14

The surgical requirement for thoracoscopy is a good view of the contents of the thorax. This is achieved by capitalizing on natural consequences and the skills of anaesthesiologists to produce a pneumothorax and collapse the ipsilateral lung--a process that is commonly enhanced by insufflating carbon dioxide. Insufflating CO2 to actively promote lung collapse creates the dynamics of a tension pneumothorax. Complications are clinically insignificant if CO2 is used judiciously. There is a body of experience using ordinary endotracheal tubes and two-lung ventilation. Techniques of one-lung ventilation are more widely reported. All the factors known to contribute to the significant increase in shunt fraction associated with one-lung ventilation apply. The manoeuvre of collapsing a lung is no longer regarded as benign. Chemical attempts to produce a reversible post-pneumonectomy pulmonary circulation have not been shown to be an improvement. Post-operative pain can be severe. The mechanism is not defined but it differs from that associated with thoracotomy. Epidural analgesia and opioids may be required. Chronic pain syndromes have been described as complications.
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PMID:Anaesthesia for thoracoscopic surgery. 1249 43

Pneumothorax in preterm infants is associated with an increased risk of chronic lung disease, intraventricular hemorrhage and mortality. In mechanically ventilated preterm infants, for the management of tension pneumothorax if needle aspiration is not successful a thoracostomy is needed. In the last two decades management of tension pneumothorax has changed from the use of traditional chest tubes to percutaneous pigtail catheter thoracostomy (PPCT) as the most commonly used technique. When compared to placement of traditional chest tubes, PPCT is touted as being faster requiring, less analgesia and less training for proficiency and having fewer complications. There are only infrequent reports of complications with this procedure. Here, a rare complication, which previously has only been reported at autopsy, is described in an extreme preterm with prompt diagnosis and early management.
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PMID:Pleuro-pericardial communication due to pigtail catheters in extreme preterm infants: Diagnosis and intervention. 2968 39