BACKGROUND: One of the factors that affect the anesthetic risk is preoperative status especially in geriatric patients. So we studied about followings; 1) Can we use APACHE scoring index when we assess the physical status of geriatric patients preoperatively? 2) Is it meaningful in saying the risk of anesthesia? 3) Which one is more significant in predicting the morbidity and mortality: acute physiologic status vs chronic health status? METHOD: Preoperative status of the geriatric patients (above 65 years old), who were received operation from June 1994 to March 1996 at Hanil General Hospital, were assessed by APACHE scoring index and ASA classification. Age, sex, type of operation, emergency or elective, method of anesthesia, duration of procedure, APACHE scoring index, ASA classification, perioperative complication, postoperative complication is coded by grading or type. RESULT: Perioperative complication was showed statistically significant with acute physiologic score (APS) and duration of procedure. Postoperative complication was showed statistically significant with APACHE score or ASA class. Total complication was affected by duration of procedure and APS score. There was also correlation between ASA class and total complication. Among 265 cases, 1 case expired during operation and 7 cases expired after operation. Causes of postoperative death were pneumonia, hemorrhagic shock etc. CONCLUSION: In geriatric patients, 1) APACHE scoring index is available for preoperative assessment. 2) APACHE scoring index is meaningful in predicting the risk of anesthesia. 3) Perioperative complication was more correlated with acute physiologic status than chronic health evaluation.
Anesthesia ; APACHE* ; Classification ; Emergencies ; Hospitals, General ; Humans ; Mortality ; Pneumonia ; Postoperative Complications ; Shock, Hemorrhagic

*Eclampsia ; *Infusions, Parenteral ; *Ireland ; *Maternal Mortality ; *Postpartum Hemorrhage ; *Puerperal Infection ; *Shock, Hemorrhagic ; *Pregnancy

PURPOSE: The management of hemorrhagic shock is critical for trauma patients. To assess hemorrhagic shock, the clinician commonly uses a change in positional blood pressure, the shock index, an estimate of the diameter of inferior vena cava based on sonography, and an evaluation of hypoperfusion complex shown on a CT scan. To add the finding for the hypoperfusion complex, the 'halo sign' was introduced recently. To our knowledge, this 'halo sign' has not been evaluated for its clinical usefulness, so we designed this study to evaluate its usefulness and to find the useful CT signs for hypoperfusion complex. METHODS: The study was done from January 2007 to May 2007. All medical records and CT images of 124 patients with trauma were reviewed, of which 103 patients were included. Exclusion criteria was as follows: 1) age < 15 year old and 2) head trauma score of AIS > or = 5. RESULTS: The value of kappa, to assess the inter-observer agreement, was 0.51 (p < 0.001). The variables of the halo-sign-positive group were statistically different from those of the halo-sign-negative group. The rate of transfusion for the halo-sign-positive group was about 10 times higher than that of the halo-sign-negative group and the rate of mortality was about 6 times higher. CONCLUSION: In the setting of trauma, early abdominal CT can show diffuse abnormalities due to hypoperfusion complex. Recognition of these signs is important in order to prevent an unwanted outcome in hemorrhagic shock. We conclude that the halo sign is a useful one for hypoperfusion complex and that it is useful for assessing the degree of hemorrhagic shock.
Adolescent ; Blood Pressure ; Craniocerebral Trauma ; Humans ; Medical Records ; Mortality ; Shock ; Shock, Hemorrhagic ; Tomography, X-Ray Computed ; Vena Cava, Inferior

We examined the hypothesis that mild hypothermia (rectal temperature 34 degrees C) results in the same survival time, whether induced spontaneously or intentionally, during untreated, lethal, uncontrolled hemorrhagic shock in rats. Sixty-four Sprague-Dawley male rats were randomly assigned to normothermia (Nth) (n=19), spontaneous mild hypothermia (Sp.Hth) (n=25) or controlled mild hypothermia (Con.Hth) (n=20) groups. After blood withdrawal of 3 mL/100 g over 15 minutes, followed by 75% tail amputation under spontaneous breathing and light anesthesia by i.p. injection of pentobarbital sodium, rats were observed without fluid resuscitation or hemostasis for 180 minutes or until death. The initial temperature of the Nth group was artificially maintained throughout the experiment. For the mild hypothermia groups, the Sp.Hth group was exposed to ambient temperature while the Con. Hth group was actively cooled to a target rectal temperature of 34 degrees C. In the Con.Hth group, all rats except one died before 180 minutes. All rats in the Nth group died within 38 minutes, and within 67 minutes in the Sp.Hth group. The average survival time was shortest in the Nth group at 20.3 +/- 5.3 minutes, followed by the Sp.Hth group at 30.1 +/- 13.5 minutes, and the Con.Hth group at 81.9 +/- 39.8 minutes (p 0.01). Tail bleed out volume was 0.51 +/- 0.19, 0.26 +/- 0.15 and 0.19 +/- 0.12 mL/100 g in the Nth, Sp.Hth and Con.Hth groups, respectively (p 0.05). In conclusion, spontaneous mild hypothermia did not prolong the survival time as much as controlled mild hypothermia in the rat model for untreated, lethal, uncontrolled hemorrhagic shock.
Animal ; Blood Pressure ; Body Temperature ; Hypothermia/*physiopathology ; *Hypothermia, Induced ; Male ; Rats ; Rats, Sprague-Dawley ; Shock, Hemorrhagic/*mortality/physiopathology/therapy

To evaluate the risk factors affecting mortality in blunt abdominal injury we prospectively analysed 149 abdominal traumatic patients, who were performed laparotomy in 84 cases and conservative management in 65 cases, from January 1st. 1995 to September 30th. 1996. The liver was most frequently injured intraabdominal organ(46.3%), followed by spleen(32.9%), kidney(23.5%), small intestine(16.1%) and mesentery(13.4%). Mortality rate was 19.5%. The cause of death was hemorrhagic shock and its complications in 11 cases, craniocerebral injuries in 7 cases, pulmonary complications in 6 cases, and septic shock in 5 cases. The presence of hypotension(less than 90mmHg), head trauma(above 3 in severity code of abbreviated injury scale(AIS)) and chest trauma(hemothorax and/or pneumothorax) was associated with a high mortality rate(88.9%), but the mortality rate for the patients neither hypotension nor head and chest trauma was very low(1.8%). The mortality in the blunt abdominal injuries was highly influenced by hypotension, head injury and multiple intraabdominal injuries(p<0.05). Of the above influencing risk factors, the associated head injury was the most powerful determinant in the prognosis in the patients of blunt abdominal injuries.
Abdominal Injuries ; Cause of Death ; Craniocerebral Trauma ; Head ; Humans ; Hypotension ; Laparotomy ; Liver ; Mortality* ; Prognosis ; Prospective Studies ; Risk Factors ; Shock, Hemorrhagic ; Shock, Septic ; Thorax

Spontaneous uterine rupture during the second trimester of pregnancy is a rare obstetric emergency. When a patient presents with acute abdominal pain and signs of hemorrhagic shock, a number of differential diagnoses must be considered. Early diagnosis and proper management is necessary to decreased the high maternal and fetal morbidity and mortality associated with rupture of uterus. We present a case of spontaneous rupture of the uterus in the 18th week of pregnancy with a brief review of literatures.
Abdominal Pain ; Diagnosis, Differential ; Early Diagnosis ; Emergencies ; Female ; Humans ; Mortality ; Pregnancy Trimester, Second ; Pregnancy* ; Rupture ; Rupture, Spontaneous ; Shock, Hemorrhagic ; Uterine Rupture* ; Uterus

An accurate and relatively simple method for estimating the amount of acute blood loss is essential in the hemorrhagic shock patients. Conventional physiologic parameters, blood pressure, pulse rate and CVP, could not serve for evaluation of the adequate oxygen transport in the tissue. Pulmonary artery catheter is a best tool for evaluating the cardiopulmonary function and the oxygen transport system, and mixed venous oxygen saturation(SvO2) monitoring have made a great advances for early detection of cardiovascular dysfunction and the changes in peripheral tissue oxygenation. But pulmonary artery catheterization is complicated procedure in emergency setting. Although the central venous oxygen saturation(ScvO2) cannot completely replace the SvO2 value, it has a close relation with SvO2 change in variable clinical situations. We testify the usefulness of ScvO2 monitoring in 24 patients of the hemorrhagic shock. Initial resuscitation was performed with ATLS standard and continuous ScvO2 was monitored. Systolic blood pressure and pulse rate were recorded for one hour from initial resuscitation in each 15 minutes. Nineteen patient was traumatic hemorrhagic shock and five was non traumatic. Twelve of 19 patients was blunt trauma, and remains were stab in injury mechanism. Mortality rate was 29.2%. Initial ScvO2 of nonsurvivor was 43.6%, and 51.3% in survivor groups(p>0.05). In the group of stab wound and non-traumatic hemorrhage, the ScvO2 was gradually increase by time. But ScvO2 in survivors of blunt trauma was increased first 30 minutes and decrease afterthen. Continuous monitoring of ScvO2 may by partly useful in resuscitation for hemorrhagic shock. It is more valuable in the blunt trauma than in the penetrating injury or non-traumatic hemorrhage.
Blood Pressure ; Catheterization, Swan-Ganz ; Catheters ; Emergencies ; Heart Rate ; Hemorrhage ; Humans ; Mortality ; Oxygen* ; Pulmonary Artery ; Resuscitation ; Shock, Hemorrhagic* ; Survivors ; Wounds, Stab

PURPOSE: There have been many reports that point to the increasing death and emergency operation rate in traumatic hemorrhagic shock patients. The purpose of this study was to discover the clinical difference between the hypotensive traumatic patients and the non-hypotensive traumatic patients that had been managed in intensive care unit (ICU). METHODS: We retrospectively reviewed the medical records of 122 patients admitted to ICU for trauma from January 2001 to December 2002. We compared the hypotensive (systolic blood pressure (SBP) < 90 mmHg) group with the non-hypotensive group about age, diastolic blood pressure, initial hemoglobin, Injury Severity Score (ISS), Glasgow Coma Scale (GCS), Revised Trauma Score (RTS), transfusion volume at emergency department, blood pH, blood base deficit, duration of admission, ICU stay, death rate, transfusion volume and others. RESULTS: There was no difference between two groups in age, causes of injury, situation whether or not the patient was directly transported from the scene and ISS. But there were differences between two groups in initial hemoglobins, GCS, RTS, blood pH, blood base deficit, duration of admission, ICU stay, and death rate. It was documented that the ICU stay correlated with systolic blood pressure, diastolic blood pressure, initial hemoglobin, blood base deficit, ISS, GCS, and RTS but not correlated with transfusion volume in emergency department. CONCLUSION: Systolic blood pressure is not the sensitive parameter of blood loss. Various kinds of indices of hypotensive group are more severe than non-hypotensive group. If traumatic patients are hypotensive blood pressure on arrival at emergency department, we should be careful of the state of these patients.
Blood Pressure ; Emergencies ; Emergency Service, Hospital ; Glasgow Coma Scale ; Humans ; Hydrogen-Ion Concentration ; Injury Severity Score ; Intensive Care Units ; Medical Records ; Mortality ; Retrospective Studies ; Shock, Hemorrhagic

OBJECTIVETo introduce the concept, methods for calculation and application of "number needs to be exposed (NNE)" in Epidemiological studies.

METHODSData was analyzed from a study on the association between diaspirin cross-linked hemoglobin (DCLHb) with 28-day mortality in patients with severe traumatic hemorrhagic shock.

RESULTSThe crude "number needed to be exposed for one additional person to be harmed" (NNEH) was 3.7 (95% CI: 2.2-11.5) for the exposure to DCLHb. After controlling the confounding bias of the baseline mortality risk, the adjusted NNEH became 2.6 (95% CI: 1.6-8.0) id., on average, among 2.6 patients exposed to DCLHb, one additional case of death would have developed within 28 days after initial hospitalization if the distribution of baseline mortality risk in exposed group had been equal to that in the unexposed group.

CONCLUSIONNNE could be expressed as the estimated average number of persons needed to be exposed for contributing (either developing or preventing for) one additional case of disease or death in a prospective study when compared with the unexposed persons. As a new index for measuring the absolute effect of an exposure, NNE presented the results on epidemiological studies in a more intuitive and understandable manner. Consequently, this method could be favorably accepted by clinicians, health policy makers and the public.

Epidemiologic Studies ; Hemoglobins ; therapeutic use ; Humans ; Logistic Models ; Randomized Controlled Trials as Topic ; Risk ; Shock, Hemorrhagic ; complications ; drug therapy ; mortality ; pathology ; Software ; Wounds and Injuries ; complications

Hemorrhage is a major cause of death in trauma patients. The medical definition of hemorrhagic shock is tissue hypoperfusion resulting from a reduction of blood volume. Decreased blood pressure resulting from acute blood loss induces cardiac stimulation, systemic vasoconstriction, and volume redistribution. These effects are due to the baroreceptor reflex, the humoral compensatory mechanisms including the renin angiotensin system, and the release of catecholamine and vasopressin. Hemorrhagic shock causes acidosis, hypothermia, and coagulopathy, known as ‘the lethal triad.’ Tissue hypoxia induces metabolic acidosis by producing lactic acid. The three components of the lethal triad amplify each other and form a vicious cycle, eventually causing the death of the patient. To reduce the risk of mortality in severely bleeding patients, we need to understand the pathophysiology of hemorrhagic shock and the related complications.
Acidosis ; Anoxia ; Baroreflex ; Blood Pressure ; Blood Volume ; Cause of Death ; Disseminated Intravascular Coagulation ; Hemorrhage ; Humans ; Hypothermia ; Lactic Acid ; Mortality ; Renin-Angiotensin System ; Shock, Hemorrhagic* ; Vasoconstriction ; Vasopressins