BACKGROUND: A dynamic preload index such as stroke volume variation (SVV) is not as reliable in spontaneous breathing (SB) patients as in mechanically ventilated patients. This study examined the hypothesis that spectral analysis of hemodynamic variables during paced breathing (PB) activity may be a feasible index of volume changes and fluid responsiveness, despite insufficient respiratory changes in the preload index during SB activity. METHODS: Blood pressure and stroke volume (SV) were measured in 16 subjects undergoing PB (15 breaths/min), using a Finometer device and the Modelflow method. Respiratory systolic pressure variation (SPV) and SVV were measured and respiratory frequency (RF, 0.2-0.3 Hz) of power spectra of SPV (SPV(RF)) and SVV (SVV(RF)) were computed using fast Fourier transformation. Progressive hypovolemia was simulated with lower body negative pressure (LBNP). Volume challenges were produced by infusion of normal saline and subsequent release of LBNP to baseline. Fluid responsiveness, defined as a >20% increase in SV, was assessed by the area under the curve (AUC) of receiver operating characteristic curves. RESULTS: Graded hypovolemia caused a significant increase in SPV(RF) and a decrease in SVV(RF). During volume expansion, SPV(RF) decreased and SVV(RF) rose significantly. Fluid responsiveness was better predicted with SVV(RF) (AUC 0.75) than with SPV(RF), SPV, or SVV. SVV(RF) before volume challenge was significantly correlated with volume expansion-induced changes in SV (r = -0.64). CONCLUSIONS: These results suggest that RF spectral analysis of dynamic preload variables may enable the detection of volume change and fluid responsiveness in SB hypovolemic patients performing PB activity.
Blood Pressure ; Fourier Analysis ; Hemodynamics ; Humans ; Hypovolemia ; Lower Body Negative Pressure ; Respiration ; ROC Curve ; Stroke Volume

Abdominal compartment syndrome (ACS) is a life-threatening emergency requiring prompt treatment. In these cases, a patient cannot ventilate effectively and oliguria can occur because of the high intra-abdominal pressure (IAP). The mortality rate is very high. Treatment is abdominal decompression and secondary closure. There are very few reports of the anesthetic management of a patient with ACS. We report a 38-year-old male patient who was diagnosed with ACS at the operating room. The IAP was measured and emergency abdominal decompression and "Bogota bag" apply were performed. The respiratory and hemodynamic parameters improved after this treatment.
Adult ; Emergencies ; Hemodynamics ; Humans ; Intra-Abdominal Hypertension* ; Lower Body Negative Pressure ; Male ; Mortality ; Oliguria ; Operating Rooms

Abdominal compartment syndrome can produce a critical situation if not diagnosed early and managed properly. We report a case of abdominal compartment syndrome that was caused by massive irrigation of surgical fluid during endoscopic lumbar diskectomy at the L4–L5 level. There was a sudden increase in peak inspiratory pressure during the operation, and the patient's tidal volume and blood pressure decreased. When the patient's position was changed from prone to supine, abdominal distension and cyanosis of both lower extremities were discovered. Ultrasonic findings showed fluid collection in both the chest and intra-abdominal cavity. Thoracentesis and abdominal decompression surgery were performed, and the patient's overall state improved. We concluded that irrigation fluid used during the endoscopic operation leaked into the retroperitoneal space and caused abdominal compartment syndrome.
Blood Pressure ; Cyanosis ; Diskectomy* ; Endoscopy ; Intra-Abdominal Hypertension* ; Lower Body Negative Pressure ; Lower Extremity ; Retroperitoneal Space ; Thoracentesis ; Thorax ; Tidal Volume ; Ultrasonics

BACKGROUND: Immediate operative management has been applied to infants and children with an attacks of adhesive small-bowel obstruction (ASBO), but this treatment has been controversial. We retrospectively reviewed 30 patients who were admitted from 1992 to 1996 because of adhesive small-bowel obstructions. METHODS: Immediate operation was reserved for the 7 patients that presented with fever and leukocytosis and /or localized abdominal tenderness or complete obstruction. The remaining 23 patients initially underwent conservative treatment. RESULTS: Although 20 episodes were cured with conservative treatment, 3 cases subsequently required surgical intervention. No adverse occurrences were observed during or after the delayed operations. Recurrence occurred in 3 cases after surgery and in 2 cases after conservative treatment. In the study, we found that the age at the recent laparotomy, the time elapsed between the recent laparotomy and the obstructive episode, and the primary condition necessitating the laparotomy correlated significantly with the success of conservative treatment. CONCLUSIONS: We conclude that in the treatment of ASBO in children, conservative treatment through the use of abdominal decompression, antibiotics, fluid-electrolytes, physical therapy, etc. has to be applied first for patients without significant evidence of strangulation and complete obstruction.
Adhesives* ; Anti-Bacterial Agents ; Child* ; Fever ; Humans ; Infant ; Laparotomy ; Leukocytosis ; Lower Body Negative Pressure ; Recurrence ; Retrospective Studies

Abdominal compartment syndrome (ACS) is a life-threatening disorder caused by rapidly increasing intraabdominal pressure. ACS can result in multiorgan failure and carries a mortality of 60~70%. The treatment of choice in ACS is surgical decompression. There are very few reports of ACS and experience in Korea. We report 12-year-old male patient who developed an abdominal compartment syndrome due to traffic-accident-induced retroperitoneal hematomas, Which was successfully treated by performing a bedside emergency surgical decompression with open linea alba fasciotomy with intact peritoneum. When patients do not respond to medical therapy, a decompressive laparotomy is the last surgical resort. In patients with severe abdominal compartment syndrome, the use of a linea alba fasciotomy is an effective intervention to lower intra-abdominal hypertension (IAH) without the morbidity of a laparotomy. Use of a linea alba fasciotomy as a first-line intervention before committing to full abdominal decompression in patients with abdominal compartment syndrome improves physiological variables without mortality. Consideration for a linea alba fasciotomy as a bridge before full abdominal decompression needs further evaluation in patients with polytrauma abdominal compartment syndrome.
Child ; Decompression, Surgical ; Emergencies ; Health Resorts ; Hematoma ; Humans ; Intra-Abdominal Hypertension ; Korea ; Laparotomy ; Lower Body Negative Pressure ; Male ; Peritoneum

BACKGROUND AND AIMS: Abdominal distension from the insufflation of air can create more troublesome discomfort after colonoscopy (CFS) than after upper endoscopy. Many patients report difficulty in expelling insufflated air after CFS. One previous study demonstrated that insertion of rectal tube at the conclusion of CFS significantly improves patient satisfaction with the procedure. The aim of this study was to compare the effectiveness of rectal tube placement for abdominal decompression after CFS in an effort to limit patient discomfort by carefully applying air suction during CFS. METHODS: We conducted a prospective trial in 103 consecutive patients undergoing elective CFS. Patients were randomized to receive rectal tube placement at the end of the procedure or simple air suction during the procedure. Patients were evaluated by clinical symptoms and signs 10 minutes after completion of CFS. RESULTS: All 103 patients had a complete examination of the colon to the cecum. No specific complications occurred during and a day after examination. The two groups were well matched with respect to age, sex, height, weight, chief complaints. There were no significant differences between the two groups for bowel preparation, duration of examination, abdominal pain during procedure, abdominal disten-sion 10 minutes after CFS, and abdominal pain 10 minutes after CFS (p >0.05). CONCLUSIONS: Meticulous air suction during CFS reduces abdominal discomfort and distension after CFS and is as effectively as the placement of a rectal tube at the con-clusion of CFS.
Abdominal Pain ; Cecum ; Colon ; Colonoscopy* ; Endoscopy ; Humans ; Insufflation ; Lower Body Negative Pressure ; Patient Satisfaction ; Prospective Studies ; Suction

BACKGROUND: We examined the usefulness of respiratory pulse transit time (PTT) variation as an intravascular volume index in young, healthy, spontaneous, paced breathing volunteers exposed to simulated central hypovolemia by lower body negative pressure (LBNP). METHODS: With paced breathing at 0.25 Hz, beat-to-beat finger blood pressure (BP), heart rate (HR), cardiac output (CO), stroke volume (SV), total peripheral resistance (TPR), and PTT were measured non-invasively in 18 healthy volunteers. Graded central hypovolemia was generated using LBNP from 0 to -20, -30, -40, and -50 mmHg. Respiratory PTT variation (PTTV) was calculated as the difference of maximal and minimal values divided by their respective means. Respiratory-frequency PTT variability (PTTRF) using power spectral analysis was also estimated. RESULTS: During LBNP, SV, CO and PTTRF decreased, but PTT, PTTV and TPR increased significantly. PTTV did not correlate with SV changes (r = -0.08, P = 0.52), but PTTRF (r = 0.58, P < 0.01) and PTT (r = 0.43, P < 0.01) did during progressive hypovolemia. CONCLUSIONS: PTTRF is more applicable to the changes in intravascular volume than PTT and PTTV, suggesting spectral analysis of PTT might be used as a dynamic preload index in patients with spontaneous and paced breathing condition, which needs further studies.
Blood Pressure ; Cardiac Output ; Fingers ; Heart Rate ; Hemorrhage ; Humans ; Hypovolemia ; Lower Body Negative Pressure ; Pulse Wave Analysis ; Respiration ; Stroke Volume ; Vascular Resistance

Acute pancreatitis is one of the main causes of intra-abdominal hypertension (IAH). IAH contributes to multiple physiologic alterations and leads to the development of abdominal compartment syndrome (ACS) that induces multiorgan failure. We report a case of ACS in a patient with severe acute pancreatitis. A 44-year-old man who was admitted in a drunk state was found to have severe acute pancreatitis. During management with fluid resuscitation in an intensive care unit, drowsy mentality, respiratory acidosis, shock requiring inotropes, and oliguria developed in the patient, with his abdomen tensely distended. With a presumptive diagnosis of ACS, abdominal decompression through percutaneous catheter drainage was performed immediately. The intraperitoneal pressure measured with a drainage catheter was 31 mm Hg. After abdominal decompression, the multiorgan failure was reversed. We present a case of ACS managed with percutaneous catheter decompression.
Abdomen ; Acidosis, Respiratory ; Adult ; Catheters* ; Decompression ; Diagnosis ; Drainage* ; Humans ; Intensive Care Units ; Intra-Abdominal Hypertension* ; Lower Body Negative Pressure ; Oliguria ; Pancreatitis* ; Resuscitation ; Shock ; Transcutaneous Electric Nerve Stimulation

We introduced the method of computer simulation in the studies of gravitational physiology. Based on work of Melchior (1994), we developed a mathematical model that can be used to stimulate cardiovascular responses to orthostatic stress (lower body negative pressure, LBNP). The model includes 7 sub-models: the redistribution of blood, the filling of left ventricle, left ventricle working, peripheral circulation, control of heart rate (HR), control of peripheral resistance and control of venous tone. Then we simulated the changes of blood pressure (BP) and heart rate during lower body negative pressure, and the results agreed well with the results of our human experiment. By using the developed model, we also simulated the effects of hypovolemia on the BP, HR and shock index during orthostatic stress. The simulation results indicate that the cardiovascular responses to orthostatic stress change significantly when the decrease of blood volume is more than 15% of the total blood volume. However, if the amount of the decrease of blood volume is less than 5% of the total blood volume, HR and BP could be maintained in normal range by the regulation of baroreflex during LBNP. Our simulation results suggest that hypovolemia may be the main cause of orthostatic intolerance induced by weightlessness.
Adult ; Blood Pressure ; physiology ; Cardiovascular Deconditioning ; physiology ; Computer Simulation ; Heart Rate ; physiology ; Humans ; Hypotension, Orthostatic ; etiology ; physiopathology ; Hypovolemia ; etiology ; physiopathology ; Lower Body Negative Pressure ; adverse effects ; Male ; Models, Cardiovascular ; Ventricular Function, Left ; physiology ; Weightlessness Simulation ; adverse effects