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Objective:To investigate the value of partial pressure of end-tidal carbon dioxide (P ETCO 2) combined with passive leg raising test (PLR) in predicting volume responsiveness in patients with septic shock. Methods:A total of 43 patients with septic shock admitted to the second department of critical care medicine, People's Hospital of Xinjiang Uygur Autonomous Region from December 2019 to June 2021 were selected as the research subjects. P ETCO 2, cardiac index (CI), stroke volume variation (SVV), mean arterial pressure (MAP) and other hemodynamic indexes were monitored before and after PLR and volume stress test (VE). Subjects were grouped according to the CI variation rate (ΔCI) after VE test. Patients with ΔCI ≥ 15% were the responding group, and patients with ΔCI < 15% were the non-responding group. The receiver operator characteristic curve (ROC curve) was drawn to analyze the evaluation value of the change in P ETCO 2 after PLR on the evaluation value of fluid responsiveness. Results:Among the 43 patients, 22 cases were in the responding group, accounting for 51.2%; 21 cases were in the non-responding group, accounting for 48.8%. After the PLR test, the change values of MAP, SVV, CI and P ETCO 2 in the responding group were higher than those in the non-responding group, and the differences were statistically significant [MAP (mmHg): 3.8±2.1 vs. 1.4±2.0, SVV (%): -5.3±2.5 vs. 2.7±2.0, CI (mL·s -1·m -2): 0.48±0.13 vs. 0.14±0.18, P ETCO 2 (mmHg): 3.4±1.8 vs. 1.1±1.0, all P < 0.05, 1 mmHg≈0.133 kPa]. After the VE test, the changes of HR, MAP, SVV, CI and P ETCO 2 in the responding group were higher than those in the non-responding group [HR (times/min): -8.3±2.8 vs. -2.3±3.7, MAP (mmHg): 3.8±2.4 vs. 1.2±1.7, SVV (%): -6.3±3.1 vs. -3.3±2.0, CI (mL·s -1·m -2): 0.51±0.14 vs. 0.16±0.12, P ETCO 2 (mmHg): 3.3±1.2 vs. 1.3±1.1, all P < 0.05]. The area under the ROC curve (AUC) of the change in P ETCO 2 before and after the PLR test (ΔP ETCO 2 PLR) for evaluating fluid responsiveness was 0.881. When the critical value was 5.9%, the sensitivity was 76.7%, the specificity was 89.5%, and the correct index was 0.68; the AUC for SVV baseline assessment of fluid responsiveness was 0.835, and when the cut-off value was 12.8%, the sensitivity was 84.6%, the specificity was 80.0%, and the correct index was 0.65. The predictive value of ΔP ETCO 2 was not lower than the SVV baseline. Conclusion:After the PLR test, the change of P ETCO 2 can be used as a non-invasive, simple, safe and reliable indicator for predicting the volume responsiveness of patients with septic shock.
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@#Objective To investigate the perioperative hemodynamic changes of off-pump coronary artery bypass grafting (OPCABG) patients monitored by pulse recorded analysis method (MostCare/PRAM devices) and its relationship with the prognosis. Methods A total of 89 patients who underwent OPCABG from October 2016 to January 2017 in Beiijng Anzhen Hospital were included, including 53 males and 36 females aged 60.50±8.40 years. The hemodynamic changes were recorded. The patients were divided into two groups (a major adverse cardiovascular events group and a stable group) according to whether major adverse cardiovascular events occurred or not. The difference of hemodynamic changes between the two groups was analysed. Results The mean percentage increases of stroke volume (SV) in the passive leg raising (PLR) test before opening chest and after chest closure were 23.00%±3.20% and 29.40%±3.70%, respectively. Hemodynamic data were analysed seven times, namely, anaesthesia, opening chest, heparin administration, coronary artery bypass grafting, protamine administration, thoracic closure and after operation. SV was significantly decreased during above periods, while systemic vascular resistance index (SVRI) was significantly increased. Cardiac circle efficiency (CCE) and maximum pressure gradient (dP/dT) were decreased after anaesthesia, and decreased to the lowest value during the procedure of bypass grafting, and then they began to increase gradually after the manipulation of bypass grafting was finished. Stroke volume variation (SVV) and pulse pressure variation (PPV) were slightly decreased during anaesthesia, then increased significantly through the whole surgery. Major adverse cardiovascular events occurred in 9 patients and 4 of them died. The basic mean values of SVRI, SVV and PPV of patients in the major adverse cardiovascular events group before opening chest were significantly higher than those of patients in the stable group. There was no significant difference in the mean values of CCE, dP/dT or SV between the two groups. There was no significant correlation between the prognosis and the mean values of SVRI, SVV, PPV, CCE, dP/dT or SV. Conclusion The hemodynamic indexes are not stable, thus, it is necessary to monitor the perioperative hemodynamic changes of OPCABG patients timely by MostCare/PRAM device and adjust treatment measures accordingly.
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Objective To explore the clinical value of early fluid resuscitation guided by passive leg-raising test (PLR) combined with transthoracic echocardiography (TTE) in patients with septic shock. Methods A prospective randomized controlled trial (RCT) was conducted. Seventy-four patients with septic shock admitted to China-Japan Friendship Hospital from January 2017 to October 2018 were enrolled. The patients were randomly divided into control group and experimental group with 37 patients in each group. Both groups of patients were treated with broad-spectrum antibiotics empirically, while received fluid resuscitation via the subclavian vein catheter. The patients of control group were given rapid fluid replacement, and those of experimental group received fluid replacement according to result of PLR combined with TTE. The stroke volume (SV) was measured by TTE before and after PLR, volumetric response of patients was judged by stroke volume variation (SVV). If the SVV≥15%, it was considered that there was a volume responsiveness, and fluid loading was given. If SVV﹤15%, it was considered that there was no volume shortage, and the restrictive fluid replacement was given. The goal of fluid resuscitation in both groups were to simultaneously meet the central venous pressure (CVP) of 8-12 mmHg (1 mmHg = 0.133 kPa), mean arterial pressure (MAP) ≥65 mmHg, urine volume ≥ 0.5 mL·kg-1·h-1, and central venous blood oxygen saturation (ScvO2) ≥ 0.70 within 6 hours. Vasoactive drugs were used when the patients could not achieve the treatment goals. The MAP, lactic acid (Lac), oxygenation index (PaO2/FiO2) and ScvO2 of the patients were determined at 6 hours of treatment, and serum C-reactive protein (CRP) and chest CT were reviewed at 48 hours of treatment, and compared with those before treatment. The total hospital stay and the mortality were recorded. Results There was no significant difference in gender, age, body weight and etiological structure between the two groups, which indicated that the baseline data were generally balanced. There was no statistical difference in MAP, Lac, PaO2/FiO2, ScvO2 and CRP before infusion between the two groups. After 6 hours of treatment, the MAP, Lac, PaO2/FiO2 and ScvO2 of the two groups were all better than those before infusion. Except for the difference in MAP between the experimental group and the control group (mmHg: 78.76±5.22 vs. 76.35±6.66, P > 0.05), the other three parameters in the experimental group were significantly better than those in the control group [Lac (mmol/L): 2.52±1.15 vs. 3.89±1.42, PaO2/FiO2 (mmHg):338.14±27.47 vs. 303.35±22.52, ScvO2: 0.70±0.04 vs. 0.63±0.05, all P < 0.01]. After 48 hours of treatment, CRP levels of both groups were lower than those before infusion, and the experimental group was better than the control group (mg/L: 110.12±39.80 vs. 137.98±31.23, P < 0.01). Chest CT showed that the incidence of pulmonary edema in the experimental group was significantly lower than that in the control group [13.5% (5/37) vs. 37.8% (14/37), P < 0.01]. The hospital stay of the experimental group was shorter than that of the control group (days: 21.47±5.58 vs. 28.33±4.93, P < 0.01), but no significant difference in mortality was found between the two groups [18.9% (7/37) vs. 18.9% (7/37), P > 0.05]. Conclusion Compared with the traditional rapid fluid replacement, early fluid resuscitation treatment strategies guided by the PLR combined with TTE, could better improve perfusion and oxygenation level of tissues and organs, avoid pulmonary edema caused by rapid fluid replacement, shorten the hospital stay in patients with septic shock, but had no significant effect on hospital mortality.
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Objective To evaluate the feasibility of using noninvasive ultrasonic cardiac output monitor USCOM velocity time integral (VTI) as the observation index of PLR.Methods This prospective study recruited 36 septic shock or acute pancreatitis patients from October 2014 to October 2016 in the resuscitation room and EICU of Peking Union Medical College Hospital.The change of VTI and plus pressure before and after PLR (⊿VTIplr and ⊿pp),and the change of VTI and stroke volume before and after 500 mL of volume expansion (⊿VTIve and ⊿SV) were recorded.Fluid response positive was defined as stroke volume increase more than 15% after volume expansion.Results ⊿VTIplr was positively correlated with ⊿SV (Spearman correlation coefficient r=0.888,P<0.01).The predicting value of⊿VTIve,⊿VTIplr and ⊿PP in fluid response were as follows:the sensitivity of ⊿VTIve in >15% was 94.7%,the specificity was 94.1%,area under the ROC curve was 0.989;the sensitivity of⊿ VTIplr in >12% was 84.2%,the specificity was 88.2%,area under the ROC curve was 0.916;and the sensitivity of⊿ PP in >10.5% was 78.9%,the specificity was 88.2%,the area under the ROC curve was 0.870.Conclusions ⊿ VTIplr measured by USCOM before and after the PLR is a sensitive and specific index.It is better than the classic index ⊿ PP.⊿ VTIplr measured by USCOM is completely noninvasive,which has very good application prospect in the emergency department.
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Passive leg raising is widely used in clinic, but it lacks of specialized mechanical raise equipment. It requires medical staff to raise leg by hand or requires a multi-functional bed to raise leg, which takes time and effort. Therefore we have developed a new medical electric leg-raising machine. The equipment has the following characteristics: simple structure, stable performance, easy operation, fast and effective, safe and comfortable. The height range of the lifter is 50-120 cm, the range of the angle of raising leg is 10°-80°, the maximum supporting weight is 40 kg. Because of raising the height of the lower limbs and making precise angle, this equipment can completely replace the traditional manner of lifting leg by hand with multi-functional bed to lift patients' leg and can reduce the physical exhaustion and time consumption of medical staff. It can change the settings at any time to meet the needs of the patient;can be applied to the testing of PLR and dynamically assessing the hemodynamics; can prevent deep vein thrombosis and some related complications of staying in bed; and the machine is easy to be cleaned and disinfected, which can effectively avoid hospital acquired infection and cross infection; and can also be applied to emergency rescue of various disasters and emergencies.
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ObjectiveTo assess the value of passive leg raising (PLR) test in predicting fluid responsiveness in patients with sepsis-induced cardiac dysfunction.Methods A prospective observational cohort study was conducted. Thirty-eight patients under mechanical ventilation suffering from sepsis-induced cardiac dysfunction admitted to Department of Surgical Intensive Care Unit of First Affiliated Hospital of Sun Yat-Sen University from September 2013 to July 2014 were enrolled. The patients were studied in four phases: before PLR (semi-recumbent position with the trunk in 45°), PLR (the lower limbs were raised to a 45° angle while the trunk was in a supine position), before volume expansion (VE, return to the semi-recumbent position), and VE with infusing of 250 mL 5% albumin within 30 minutes. Hemodynamic parameters were recorded in every phase. The patients were classified into two groups according to their response to VE: responders (at least a 15% increase in stroke volume,ΔSVVE≥15%), and non-responders. The correlations among all changes in hemodynamic parameters were analyzed by linear correlation analysis, and the receiver operating characteristic curve (ROC) was plotted to assess the value of hemodynamic parameters before and after PLR in predicting fluid responsiveness.Results Of 38 patients, 25 patients were responders, and 13 non-responders. There was no significant difference in the baseline and hemodynamic parameters at semi-recumbent position between the two groups. The changes in SV and cardiac output (CO) after PLR (ΔSVPLR andΔCOPLR) were significantly higher in responders than those of non-responders [ΔSVPLR: (14.7±5.7)%vs. (6.4±5.3)%,t = 4.304,P = 0.000;ΔCOPLR: (11.2±7.5)% vs. (3.4±2.3)%,t = 3.454,P = 0.001], but there was no significant difference in the changes in systolic blood pressure, mean arterial pressure, pulse pressure, and heart rate after PLR (ΔSBPPLR,ΔMAPPLR,ΔPPPLR andΔHRPLR) between two groups.ΔSVVE in responders was significantly higher than that of the non-responders [(20.8±5.5) % vs. (5.0±3.7) %,t = 8.347,P = 0.000]. It was shown by correlation analysis thatΔSVPLR was positively correlated withΔSVVE (r = 0.593,P = 0.000),ΔCOPLR was positively correlated withΔSVVE (r = 0.494,P = 0.002). The area under ROC curve (AUC) ofΔSVPLR≥8.1% for predicting fluid responsiveness was 0.860±0.062 (P = 0.000), with sensitivity of 92.0% and specificity of 70.0%; the AUC ofΔCOPLR≥5.6% for predicting fluid responsiveness was 0.840±0.070 (P = 0.000), with sensitivity of 84.0%and specificity of 76.9%; the AUC ofΔMAPPLR≥6.9% for predicting fluid responsiveness was 0.662±0.089, with sensitivity of 68.0% and specificity of 76.9%; the AUC ofΔSBPPLR≥6.4% for predicting fluid responsiveness was 0.628±0.098, with sensitivity of 76.0% and specificity of 61.5%; the AUC ofΔPPPLR≥6.2% for predicting fluid responsiveness was 0.502±0.094, with sensitivity of 56.0% and specificity of 53.8%; the AUC ofΔHRPLR≥-1.7%for predicting fluid responsiveness was 0.457±0.100, with sensitivity of 56.0% and specificity of 46.2%.Conclusion In patients with sepsis-induced cardiac dysfunction, changes in SV and CO induced by PLR are accurate indices for predicting fluid responsiveness, but the changes in HR, MAP, SBP and PP cannot predict the fluid responsiveness.
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Objective To discuss the clinical significance of fluid management of severe patients according to arterial pressure-based cardiac output (APCO) monitoring volume responsiveness index.Methods A retrospective cohort study was conducted.The severe patients were selected from the intensive care unit (ICU) of the First Hospital of Jilin University from June 1st,2012 to December 31st,2013.The hemodynamic parameters were monitored by APCO,and the fluid resuscitation was managed by stroke volume variation (SVV) and passive leg-raising test (PLR) when the acute physiology and chronic health evaluation Ⅱ (APACHE Ⅱ) score ≥ 15,heart rate > 100 bpm with the result that the preload and heart function could not be evaluated.The heart rate,SVV,lactic acid (Lac) and central venous pressure (CVP) and curative effect were recorded before and after carrying out fluid management strategy.The criteria of clinical effective was defined as heart rate decreased and (or) stroke volume (SV) increased ≥ 10%,accompanied by blood Lac and SVV decreased,other than,the cases did not meet above criteria were considered ineffective.Results Sixty-eight patients were enrolled in the study.① Before carrying out fluid management strategy:40 cases with CVP> 12 cmH2O (1 cmH2O=0.098 kPa),and 16 cases with 5-12 cmH2O,12 with <5 cmH2O.SVV>13% in 35 cases,SVV < 13% in 9 cases.PLR positive in 18 cases,and PLR negative in 6 cases.It was implicated that the patients with poor preload (SVV > 13% and PLR positive) accounted by 77.9% (53/68).② There were 49 effective cases and 19 ineffective cases 4 hours after carrying out fluid management strategy,and the effective rate was 72.06% (49/68).While there were 56 effective cases and 12 ineffective cases after 12 hours,and the total effective rate was 82.35% (56/68).③ In effective group,heart rate,SVV,Lac after fluid management strategy were significantly lower than those before fluid management strategy [4 hours after fluid management strategy:heart rate (bpm) 112.45 ± 13.53 vs.129.55 ± 15.49,SVV (15.47 ± 6.32)% vs.(21.20 ± 7.40)%,Lac (mmol/L) 4.16 ± 3.12 vs.6.21 ± 4.11 ; 12 hours after fluid management strategy:heart rate (bpm) 110.02 ± 13.92 vs.129.61 ± 14.93,SVV (14.61 ± 15.52)% vs.(20.66 ± 7.40)%,Lac (mmol/L) 3.35 ± 2.26 vs.6.11 ± 4.02,P<0.05 or P<0.01],while there was no significant difference in those markers between before and after fluid management strategy in ineffective group [4 hours after fluid management strategy:heart rate (bpm) 119.53 ± 11.68 vs.125.79 ± 11.58,SVV (16.95 ±6.48)% vs.(18.47 ±4.96)%,Lac (mmol/L) 5.55 ± 3.80 比 6.54 ± 3.72 ; 12 hours after fluid management strategy:heart rate (bpm) 115.92 ± 11.71 vs.123.40 ± 11.59,SVV (17.17 ± 6.09)% vs.(19.42 ± 8.25)%,Lac (mmol/L) 6.33 ± 3.40 vs.7.21 ± 3.81,all P> 0.05].CVP only at 12 hours after fluid management strategy in effective group was significantly higher than that before fluid management strategy (cmH2O:12.88 ± 3.38 vs.11.27 ± 4.97,P<0.05).Conclusion SVV monitored by APCO is a good indicator of volume responsiveness index,which can be used as an important reference combined with PLR for fluid management of severe patients.
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Objective To compare the procotol of EGDT +Pt (cv-a ) CO2 with EGDT in fluid resuscitation and management after evaluate fluid responsiveness in shock patients by Vigileo and passive leg raising test.Metheds Prospectively collect patients who meet the criteria between 2013.5.1-2013.1 1.30 in our ICU.Randomly (random number)divided into Vigileo group (first evaluate the fluid responsiveness then give EGDT +Pt (cv-a) CO2 ) and CVP group (give EGDT).Compare the hospital mortality and morbility of MODS,the volume given in the first 6 hours and the first 7 days,consume of blood products , the ICU and hospital stay.Results Collected 46 patients,Vigileo group (21 )and CVP group (25 ). There’s no significant difference between groups at baseline.In the first 6 hours the CVP group had received more fluids (3656.281678.57 vs. 2639.141326.59 ) mL, P =0.03;and more blood products (573.00172.57 vs. 190.4770.82)mL,P=0.04,respictivily.Vigileo group significantly short the ICU stay ,(6.384.34 vs. 12.165.77)d,P=0.04.But there’s no significant difference in hospital motality and the morbility of MODS.The ROC of Age ,the accumulative volume of balance in 7 days,APACHEⅡscore in the first day to predict death is 0.84 (0.68-0.99)、0.82 (0.69-0.95)、0.80 (0.66-0.94),all P>0.05,respectively.By 7 days the accumulative volume of balance 3454.51mL as cutoff to predict death with the sensitivity of 0.67,specificity of 0.84.Conclusions 1.Given EGDT +Pt (cv-a) CO2 after evaluate the fluid responsiveness can reduce fluid and blood products given in the first 6 hours,significantly short the ICU stay,without worsen the tissue flow or increase the morbility of MODS;2.Consecutive positive fluid balance is a risk factor about poor prognosis,and also a sensitive indicator to predict death.
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BACKGROUND: Hypotension often occurs after induction of general anesthesia. Although preload status has been considered as an important factor for the occurrence of this hypotension, there have been inconsistent results on this topic. The dynamic preload parameters have not been studied as a predictor of hypotension, and therefore we hypothesized that the passive leg raising (PLR) test, a dynamic preload parameter, could predict anesthesia-induced hypotension and conducted a prospective clinical study. METHODS: In 40 patients undergoing elective cardiac surgery, mean arterial pressure (MAP), stroke volume variation, stroke volume (SV) and cardiac index (CI) were measured using arterial line and FloTrac(TM)/Vigileo(TM) system before, during and after PLR test, respectively. Occurrence of anesthesia-induced hypotension was recorded. The ability of PLR test to predict hypotension was evaluated by receiver operating characteristic (ROC) curve analysis. RESULTS: The incidence of hypotension was 90%, which includes 12.5% of refractory hypotension. Changes in MAP and CI induced by PLR test predicted hypotension (area under ROC curves: 0.722 and 0.788, respectively). Changes in SV and CI induced by PLR test predicted refractory hypotension (area under ROC curves: 0.863 and 0.789, respectively). CONCLUSIONS: Our results suggest that PLR test can predict hypotension and refractory hypotension occurring after induction of anesthesia in patients undergoing cardiac surgery.