Back to Journals » Drug Design, Development and Therapy » Volume 8

The influence of goal-directed fluid therapy on the prognosis of elderly patients with hypertension and gastric cancer surgery

Authors Zeng K, Li Y, Liang M, Gao Y, Cai H, Lin C

Received 23 April 2014

Accepted for publication 5 July 2014

Published 29 October 2014 Volume 2014:8 Pages 2113—2119

DOI https://doi.org/10.2147/DDDT.S66724

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 3



This paper has been retracted  

Kai Zeng,* Yanzhen Li,* Min Liang, Youguang Gao, Hongda Cai, Caizhu Lin

Department of Anesthesia, the First Affiliated Hospital, Fujian Medical University, Fuzhou, People’s Republic of China

*These authors contributed equally to this work


Purpose: We aimed to investigate the influence of perioperative goal-directed fluid therapy (GDFT) on the prognosis of elderly patients with gastric cancer and hypertension.
Methods: Sixty elderly patients (>60 years old) with primary hypertension who received gastric cancer radical surgery and who were American Society of Anesthesiologists (ASA) class II or III were enrolled in the current study. Selected patients were divided randomly into two arms, comprising a conventional intraoperative fluid management arm (arm C, n=30) and a GDFT arm (arm G, n=30). Patients in arm C were infused with crystalloids or colloids according to the methods of Miller’s Anesthesia (6th edition), while those in arm G were infused with 200 mL hydroxyethyl starch over 15 minutes under the FloTrac/Vigileo monitoring system, with stroke volume variation between 8% and 13%. Hemodynamics and tissue perfusion laboratory indicators in patients were recorded continuously from 30 minutes before the operation to 24 hours after the operation.
Results: Compared with arm C, the average intraoperative intravenous infusion quantity in arm G was significantly reduced (2,732±488 mL versus 3,135±346 mL, P<0.05), whereas average colloid fluid volume was significantly increased (1,235±360 mL versus 760±280 mL, P<0.05). In addition, there were more patients exhibiting intraoperatively and postoperatively stable hemodynamics and less patients with low blood pressure in arm G. Postoperative complications were less frequent, and the time of postoperative hospital stay shorter, in arm G. No significant differences were observed in mortality between the two arms.
Conclusion: Our research showed that GDFT stabilized perioperative hemodynamics and reduced the occurrence of postoperative complications in elderly patients who underwent gastric cancer surgery.

Keywords: stroke volume variation, gastric cancer, the elderly

Introduction

Fluid therapy is an integral part of daily anesthesia, as well as one of the most debated issues in perioperative management. With the aging of the population, more and more patients are in need of large-scale noncardiac surgery.13 Elderly hypertensive patients with hypovolemia and hypoxia are often unable to tolerate such surgery due to postoperative complications. The traditional methods normally introduce more liquid, but easily lead to tissue edema and postoperative low blood pressure. These methods also slow tissue healing and increase the incidence of complications such as pulmonary infection. Furthermore, rapid rehydration loading within a short time can easily lead to acute pulmonary edema and heart failure, which is often life threatening.47 Therefore, more stringent standards are required for fluid administration in elderly patients, and anesthetists should operate with great cautiousness. Since there are no instruments that can accurately assess blood volume or tissue perfusion, or accurately predict liquid overload, most studies811 have focused on the selection of types of blood for the perioperative treatment. Clinically, the decision regarding the amount of liquid to use during the surgery still depends on the anesthesiologist’s experience and patient’s tolerance.

Stroke volume variation (SVV) is an accurate and easy parameter by which to measure fluid responsiveness and functional hemodynamic parameters. It can be used to guide fluid therapy in mechanically ventilated patients. In the present study, we aimed to investigate the effect of goal-directed fluid therapy (GDFT) on prognosis in elderly hypertensive patients receiving gastric cancer surgery. The purpose is to provide a more objective basis for intraoperative fluid therapy and further refine the technique to improve outcomes for elderly patients.

Materials and methods

Patient selection

This study was approved by the ethics committee of Fujian Medical University, Fuzhou, People’s Republic of China. All patients signed consent forms. Between March 2011 and December 2012, 60 elderly hypertensive patients (older than 60 years) undergoing abdominal cancer surgery were enrolled in the study. All patients had normal preoperative blood pressures. According to the standards of the American Society of Anesthesiologists (ASA), the preoperative conditions of patients were classed as grades II or III. The averaged body mass index (BMI) was <30 kg/m2, and the averaged preoperative hematocrit level was >0.35 L/L. Patients were excluded if they had secondary hypertension, severe cardiopulmonary diseases (coronary heart disease, congenital heart disease, pneumonia, tuberculosis, pulmonary malignant tumors, etc), liver and kidney dysfunctions, or clear arrhythmia. The diagnostic criteria for hypertension were based on Chinese Hypertension Prevention Guide, 2010.12 All patients received regular preoperative antihypertensive treatments. Using random selection, patients were divided into two arms: a conventional infusion arm (arm C, n=30) and a GDFT group (arm G, n=30).

Perioperative management

Preparation before anesthesia

All patients received a restricted diet preoperatively. After entering the operation room, local anesthesia was administered by left radial artery catheterization guided by Doppler ultrasound (SKK24-S6 xk 9/1; Zhongxi Yuanda Technology Co., Ltd., Beijing, People’s Republic of China). Using a multifunction monitor (Datex-Ohmeda S/5TM type), heart rate (HR), systolic blood pressure (SBP), diastolic blood pressure (DBP), mean arterial pressure (MAP), central venous pressure (CVP), oxygen saturation (SpO2), end-tidal carbon dioxide partial pressure (PETCO2), and other indicators were continuously monitored. The FloTrac/Vigileo system (version 1.10; Edwards Lifesciences, Irvine, CA, USA) was used to obtain cardiac output/cardiac index (CI), stroke volume (SV)/stroke index, SVV, and other hemodynamic parameters.

Maintaining anesthesia

The patients in both arms underwent the same anesthetic procedure with drug application before surgery. Anesthesia was induced by midazolam (Jiangsu Nhwa Pharmaceutical Co., Ltd., Xuzhou, People’s Republic of China) 0.06 mg/kg, fentanyl (Yichang Humanwell Pharmaceutical Co., Ltd., Yichang, People’s Republic of China) 4 μg/kg, etomidate (German Braun Corporation, Southborough, Germany) 0.3 mg/kg, cis-atracurium (GlaxoSmithKline plc, London, UK) 0.2 mg/kg, followed by intravenous injection. Intubation was completed through video-assisted laryngoscopy. After intubation, a Datex-Ohmeda 7,100 ventilator was used to control breathing during anesthesia. All patients were supplied with 8 mL/kg tidal volume mechanical ventilation to maintain a respiratory ratio (times of inhale:times of exhale) of 1:2 and respiratory rate of 10 to 14 breaths per minute, to ensure a PETCO2 level of ~35–45 mmHg. The airway pressure was kept at less than 25 cm H2O. The anesthesia was maintained with inhalation of 1.5% to 3% sevoflurane (Jiangsu Nhwa Pharmaceutical Co., Ltd.), in air mixed with 50% O2. Intermittent boluses of cis-atracurium 0.04 mg/kg and fentanyl 1 μg/kg were administered. A bispectral index of between 40 and 60 was also maintained.

Volume management

The FloTrac/Vigileo device was used to measure SVV and other hemodynamic parameters. Patients in arm C underwent conventional fluid therapy management according to the methods of Miller’s Anesthesia (6th edition).13 The management objective for arm G was to induce 200 mL of 6% hydroxyethyl starch within 15 minutes each time, with SVV between 8% and 13%, under the monitoring of the FloTrac/Vigileo system. When the measured SVV was 13% above the normal level (lasting for 5 minutes), or the current subtest reaction was positive (SV increased more than 10%), an additional 200 mL of Voluven® was introduced. Intraoperatively, insulation blankets and a continuous heating device were used to maintain patient temperatures at above 36°C. Blood transfusion was conducted if bleeding constituted more than one-quarter of the total blood volume. Finally, all patients were treated postoperatively by the same team of physicians.

Monitoring indicators

Basic indicators

Patients were scheduled preoperative visits and vital information was collected, which included sex, age, weight, height, blood pressure classification, ASA classification, BMI, hemoglobin levels (Hb), preoperative complication type, etc.

Hemodynamics

All patients were continuously monitored in terms of conventional hemodynamic parameters, including HR, SBP, DBP, MAP, CVP, SpO2, and other indicators. The FloTrac/Vigileo system was used to obtain cardiac output/CI, SV/stroke index, SVV, and other hemodynamic parameters. Hemodynamic indexes of MAP, HR, and CVP were recorded at the following time points: 30 minutes before surgery (T0); at the beginning of surgery (T1); 1 hour after the initial surgery (T2); at the onset of surgery (T3); 6 hours after surgery (T4); 12 hours after surgery (T5); and 24 hours after surgery (T6). Also, the perioperative hypotensive events, defined as SBP <90 mmHg, DBP <50 mmHg, or a >30% drop in blood pressure compared with baseline blood pressure, were recorded. Once hypotensive events occurred, ephedrine was administrated to accelerate the infusion rate. We also recorded patients’ undergoing crystal volumes, colloids, blood losses, and urine outputs.

Central venous oxygen saturation (ScvO2) and arterial blood lactate (Lac)

Blood samples were collected from the jugular vein and radial artery in all patients at T0, T1, T2, T3, T4, T5, and T6. ScvO2 and Lac were then measured by a blood gas analyzer.

Postoperative conditions

The postoperative exhaust times were recorded. If any of postoperative nausea and vomiting, low blood pressure, cardiac arrhythmia, oliguria, anastomotic fistula, or other complications occurred multiple times, patients were immediately transferred to the intensive care unit. Postoperative complications were observed by physicians who were blinded to the two arms in combination with patient self-reports.

Statistical analysis

Data were analyzed by SPSS 18.0 software. Normal distribution was assessed with mean ± standard deviation. Within arms, data were assessed by using two-factor repeated measures analysis of variance. Analysis between arms used Student’s t-test. Ridit analysis was used to assess ordinal data. Counts were done by using the χ2 test or Fisher’s exact test. P<0.05 was considered statistically significant.

Results

There were no significant differences in sex ratio, age, hypertension classification, ASA classification, BMI, Hb, or other general information of the patients between the two arms (P>0.05), as shown in Table 1.

Table 1 Basic information of the patients (n=30)
Notes: Arm C received conventional infusion; arm G received goal-directed fluid therapy. Data are presented as number or mean ± standard deviation.
Abbreviations: ASA, American Society of Anesthesiologists; BMI, body mass index; Hb, hemoglobin.

There were no significant differences in the HR or CVP values of patients between the two arms. However, MAP values were statistically different between the two arms. For patients of the same arm, the values of MAP, HR, and CVP varied at different time points. There were cross-effects between arms and time points. Thus, it can be considered that the values and rates of change of MAP, HR, and CVP were different at different time points.

Compared with arm C, CVP values were higher at T4, T5, and T6, and HR values were higher at T3, T4, T5, and T6, in arm G.

From the time point of view, MAP began to rise 1 hour after surgery and then began to decline to the levels from 30 minutes before surgery, continuing to decline until 12 hours after the operation. HR began to decline after surgery, then to rise 6 hours after surgery, reaching peak 12 hours after surgery. CVP began to rise after the start of surgery, rose to the highest value during surgery, and then began to decline 24 hours after the operation to the level from the beginning of the operation (Table 2).

Table 2 Comparison of hemodynamics of patients between the two arms (n=30)
Notes: Data are presented as mean ± standard deviation. Arm C received conventional infusion; arm G received goal-directed fluid therapy. T0 =30 minutes before surgery; T1 = at the beginning of surgery; T2 =1 hour after the initial surgery; T3 = at the onset of surgery; T4 =6 hours after surgery; T5 =12 hours after surgery; T6 =24 hours after surgery. *P<0.05 compared to arm C.
Abbreviations: CVP, central venous pressure; HR, heart rate; MAP, mean arterial pressure.

The average volume of intravenous infusion in arm G (2,732±488 mL) was significantly lower than the value in arm C (3,135±346 mL). The amount of colloids was higher in arm G (1,235±360 mL) than in arm C (760±280 mL). There were no differences in intraoperative blood losses and urine outputs between the two arms. Arm G had a lower incidence of hypotensive events, thus patients in this arm had a smaller chance of requiring ephedrine (Table 3).

Table 3 Liquid intake and intraoperative administration of vasoactive drugs (n=30)
Notes: Data are presented as mean ± standard deviation. Arm C received conventional infusion; arm G received goal-directed fluid therapy. *P<0.05 compared to arm C.

ScvO2 values between the two arms were statistically different. The difference in Lac value was significant between the two arms. At different time periods, the values of ScvO2 and Lac varied and there were cross-effects between arms and time points.

Compared with arm C, the averaged values of ScvO2 were higher at T2, T3, T4, and T5 in arm G. The Lac values at T3, T4, and T5 were lower in arm G. From the time point of view, ScvO2 was slightly elevated before surgery, remained stable during surgery, started to increase after surgery, and then began to decline 12 hours after surgery to the preoperative levels. The values of Lac began to decrease during surgery to a minimum level 1 hour after surgery, then began to rise to the preoperative levels and remained stable thereafter (Tables 4 and 5).

Table 4 Comparison of ScvO2 and Lac between the two arms (n=30)
Notes: Data are presented as mean ± standard deviation. Arm C received conventional infusion; arm G received goal-directed fluid therapy. T0 =30 minutes before surgery; T1 = at the beginning of surgery; T2 =1 hour after the initial surgery; T3 = at the onset of surgery; T4 =6 hours after surgery; T5 =12 hours after surgery; T6 =24 hours after surgery. *P<0.05 compared to arm C.
Abbreviations: Lac, arterial blood lactate; ScvO2, central venous oxygen saturation.

Table 5 Comparison of different indicators between Arm G and Arm C by ANOVA
Abbreviations: ANOVA, analysis of variance; CVP, central venous pressure; HR, heart rate; Lac, arterial blood lactate; MAP, mean arterial pressure; ScvO2, central venous oxygen saturation.

Patients in arm G exhibited earlier onset of exhaust time than patients in arm C. The averaged postoperative start time of defecation in arm G was 3.6±1.4 days, and was 4.3±1.9 in arm C. The postoperative hospitalization time was shorter in arm G. The incidences of nausea, vomiting, and hypotension were lower in arm G than in arm C. There were no statistical differences in delirium, arrhythmia, pulmonary infection, pulmonary edema, pulmonary embolism, wound infection/dehiscence, oliguria, intestinal fistula, mortality, and other complications between the two arms (Table 6).

Table 6 Comparison of postoperative complications between the two arms
Notes: Arm C received conventional infusion; arm G received goal-directed fluid therapy. *P<0.05 compared to arm C. Data are presented as number or mean ± standard deviation.

Discussion

The debate about appropriate perioperative fluid treatment strategy has been going on for nearly half a century. Studies have reported a number of inconsistent or even contradictory points of views. Although clinical trials or meta-analysis with large sample sizes have been reported, researchers have failed to prove that one method has overwhelming advantages over others.14 Recently, some researches proposed an ideal perioperative state of the loop.515 These literatures showed that for patients at high risk for death, perioperative fluid load or the combination with dobutamine could increase the CI and oxygen delivery index (DO2I) to extraordinary values (CI >4.5 L/[min·m2], DO2I >650 mL/[min·m2]), significantly reducing patient hospital stay times or mortality. Subsequently, the GDFT term was introduced in many perioperative fluid-management studies.16

In recent years, more and more studies have started to reveal that the amount of perioperative transfusion is critical for maintaining the body’s fluid balance.17 Studies showed that the colloid and crystalloid solutions were not exchangeable, even with an appropriate proportion such as 1:3 to 1:5.1820 Using a crystal liquid supplement may retain most of the crystals in the blood vessels. However, it is not always ideal to use a colloidal solution, as surgeons need to consider various factors, such as drug indications, contraindications, and side effects.2123

The results of our study showed that, although the patients in arm G received a significantly lower amount of intravenous infusion, they also received a much higher amount of colloids. Although patients in arm C received more crystalloid, there was no significant difference in the amount of bleeding between the two arms. Compared with arm C, CVP values were higher at T4, T5, and T6, and HR values lower at T3, T4, T5, and T6, in arm G. For patients in arm G, the probability of having postoperative hypotension was lower, thus these patients were more likely to maintain more stable hemodynamics and good tissue perfusion condition.

Studies have shown that GDFT intervention can not only lower the Lac levels within 24 hours after surgery, but also reduce the incidence of infection.2431 In the present study, we discovered that Lac concentrations in arm G were lower at T3, T4, and T5, as compared to the values in arm C (P<0.05), in line with previous results.32 Studies on GDFT also showed that ScvO2 was a reliable parameter to predict postoperative effect, with accuracies of 64.4% and 73%.33,34 In the present study, the values of ScvO2 were higher at T2, T3, T4, and T5 in arm G, compared to arm C.

GDFT achieves the goal of optimal oxygen delivery by maintaining or increasing cardiac output. Thus, the immune cells can be free of the risk of preoperative hypoperfusion or intestinal disorder-associated lymphoid tissue damage, thus promoting tissue healing and reducing infection rates. The traditional treatment programs often use a large number of crystal liquid, which can easily lead to tissue edema and postoperative low blood pressure. Postoperative side-effects may affect tissue healing and increase the incidence of complications such as severe pulmonary infections. In the present study, patients in arm G experienced shorter postoperative hospital stay, better postoperative recovery, and faster bowel movement recovery. Also, the incidences of postoperative complications such as nausea, vomiting, and hypotension were significantly lower in patients in arm G than in those in arm C. Interestingly, there were no differences in the incidences of delirium, arrhythmia, pulmonary infection, pulmonary edema, pulmonary embolism, wound infection/dehiscence, oliguria, intestinal fistula, mortality, and other complications between the two arms. One possible explanation is that the type and amount of infusion may affect patients’ prognosis, as 6% of hydroxyethyl starch solution was found to be more likely to maintain gastrointestinal microcirculation perfusion and oxygen tension than the crystal.35,36

Study limitations

There were some shortcomings in this study. The observation time of the patients participating in this study was short. In addition, the experiment was a small, single-center study. A larger-sample-size multicenter study would certainly help investigation of the potential of full-scale implementation of GDFT.

Conclusion

Overall, this study showed that GDFT application in elderly hypertensive patients can stabilize the perioperative hemodynamic situation, improve tissue perfusion, reduce the incidence of postoperative complications, and shorten hospital stays.

Acknowledgment

This study was supported by the Joint Research Fund of Fujian Medical University, grant number 2013B002.

Disclosure

The authors report no conflicts of interest in this work.


References

1.

Pizon AF, Wolfson AB. Postpartum focal neurologic deficits: posterior leukoencephalopathy syndrome. J Emerg Med. 2005;29(2):163–166.

2.

Chambers KA, Cain TW. Postpartum blindness: two cases. Ann Emerg Med. 2004;43(2):243–246.

3.

Long TR, Hein BD, Brown MJ, Rydberg CH, Wass CT. Posterior reversible encephalopathy syndrome during pregnancy: seizures in a previously healthy parturient. J Clin Anesth. 2007;19(2):145–148.

4.

Singhal AB. Postpartum angiopathy with reversible posterior leukoencephalopathy. Arch Neurol. 2004;61(3):411–416.

5.

Shoemaker WC, Appel PL, Kram HB, Waxman K, Lee TS. Prospective trial of supranormal values of survivors as therapeutic goals in high-risk surgical patients. Chest. 1988;94(6):1176–1186.

6.

Hamilton-Davies C, Mythen MG, Salmon JB, Jacobson D, Shukla A, Webb AR. Comparison of commonly used clinical indicators of hypovolaemia with gastrointestinal tonometry. Intensive Care Med. 1997; 23(3):276–281.

7.

Marik PE, Baram M, Vahid B. Does central venous pressure predict fluid responsiveness? A systematic review of the literature and the tale of seven mares. Chest. 2008;134(1):172–178.

8.

Klatte T, Shariat SF, Remzi M. Systematic review and meta-analysis of perioperative and oncologic outcomes of laparoscopic cryoablation versus laparoscopic partial nephrectomy for the treatment of small renal tumors. J Urol. 2014;191(5):1209–1217.

9.

Chua TC, Liauw W, Saxena A, et al. Evolution of locoregional treatment for peritoneal carcinomatosis: single-center experience of 308 procedures of cytoreductive surgery and perioperative intraperitoneal chemotherapy. Am J Surg. 2011;201(2):149–156.

10.

Bienkowski P, Reindl R, Berry GK, Iakoub E, Harvey EJ. A new intramedullary nail device for the treatment of intertrochanteric hip fractures: Perioperative experience. J Trauma. 2006;61(6):1458–1462.

11.

Nagy K, Muranyi M, Nadas G, Tapolcsanyi E, Vimlati L. [Perioperative treatment after esophagogastric surgery]. Magy Seb. 2001;54(3):138–143. Hungarian.

12.

Ming BSY. Chinese Hypertension Prevention Guide (Chinese Edition). People’s Health Publishing House: Beijing, People’s Republic of China; 2010.

13.

Shafer SL, Stanski DR. Defining depth of anesthesia. Handb Exp Pharmacol. 2008;182:409–423.

14.

Bundgaard-Nielsen M, Secher NH, Kehlet H. ‘Liberal’ vs ‘restrictive’ perioperative fluid therapy – a critical assessment of the evidence. Acta Anaesthesiol Scand. 2009;53(7):843–851.

15.

Marik PE, Cavallazzi R, Vasu T, Hirani A. Dynamic changes in arterial waveform derived variables and fluid responsiveness in mechanically ventilated patients: a systematic review of the literature. Crit Care Med. 2009;37(9):2642–2647.

16.

Srinivasa S, Taylor MH, Singh PP, Yu TC, Soop M, Hill AG. Randomized clinical trial of goal-directed fluid therapy within an enhanced recovery protocol for elective colectomy. Br J Surg. 2013;100:66–74.

17.

Joshi GP. Intraoperative fluid restriction improves outcome after major elective gastrointestinal surgery. Anesth Analg. 2005;101(2):601–605.

18.

L’Hermite J, Muller L, Cuvillon P, et al. Stroke volume optimization after anaesthetic induction: An open randomized controlled trial comparing 0.9% NaCl versus 6% hydroxyethyl starch 130/0.4. Ann Fr Anesth Reanim. 2013;32:e121–127.

19.

Ni QY, Huang YX, Xu JY, Qiu HB. [Effects of different fluid resuscitations on mesenteric microcirculation in rabbits of acute hemorrhagic shock]. Zhonghua Yi Xue Za Zhi. 2013;93(9):693–697. Chinese.

20.

Li L, Zhang Y, Tan Y, Xu S. Colloid or crystalloid solution on maternal and neonatal hemodynamics for cesarean section: a meta-analysis of randomized controlled trials. J Obstet Gynaecol Res. 2013; 39:932–941.

21.

Chappell D, Jacob M, Hofmann-Kiefer K, Conzen P, Rehm M. A rational approach to perioperative fluid management. Anesthesiology. 2008;109(4):723–740.

22.

Bakker J, Coffernils M, Leon M, Gris P, Vincent JL. Blood lactate levels are superior to oxygen-derived variables in predicting outcome in human septic shock. Chest. 1991;99:956–962.

23.

Munoz R, Laussen PC, Palacio G, Zienko L, Piercey G, Wessel DL. Changes in whole blood lactate levels during cardiopulmonary bypass for surgery for congenital cardiac disease: an early indicator of morbidity and mortality. J Thorac Cardiovasc Surg. 2000;119(1):155–162.

24.

Lopes MR, Oliveira MA, Pereira VO, Lemos IP, Auler JO Jr, Michard F. Goal-directed fluid management based on pulse pressure variation monitoring during high-risk surgery: a pilot randomized controlled trial. Crit Care. 2007;11(5):R100.

25.

Chytra I, Pradl R, Bosman R, Pelnár P, Kasal E, Zidková A. Esophageal Doppler-guided fluid management decreases blood lactate levels in multiple-trauma patients: a randomized controlled trial. Crit Care. 2007;11(1):R24.

26.

Goodrich C. Continuous central venous oximetry monitoring. Crit Care Nurs Clin North Am. 2006;l8(2):203–209.

27.

Rivers EP, Ander DS, Powell D. Central venous oxygen saturation monitoring in the critically ill patient. Curr Opin Crit Care. 2001;7(3): 204–211.

28.

Dueck MH, Klimek M, Appenrodt S, Weigand C, Boerner U. Trends but not individual values of central venous oxygen saturation agree with mixed venous oxygen saturation during varying hemodynamic conditions. Anesthesiology. 2005;103(2):249–257.

29.

Ladakis C, Myrianthefs P, Karabinis A, et al. Central venous and mixed venous oxygen saturation in critically ill patients. Respiration. 2001; 68(3):279–285.

30.

Marx G, Reinhart K. Venous oximetry. Curr Opin Crit Care. 2006; 12(3):263–268.

31.

Reinhart K, Bloos F. The value of venous oximetry. Curr Opin Crit Care. 2005;11(3):259–263.

32.

Lindinger MI, Heigenhauser GJ, McKelvie RS, Jones NL. Role of nonworking muscle on blood metabolites and ions with intense intermittent exercise. Am J Physiol. 1990;258:R1486–1494.

33.

Pearse R, Dawson D, Fawcett J, Wort S, Rhodes A, Grounds R. The relationship between central venous saturation and outcome following high-risk surgery. Crit Care. 2004;8(6):51.

34.

Sax H, Uçkay I, Balmelli C, et al. Overall burden of healthcare-associated infections among surgical patients. Results of a national study. Ann Surg. 2011;253(2):365–370.

35.

Kimberger O, Arnberger M, Brandt S, et al. Goal-directed colloid administration improves the microcirculation of healthy and perianastomotic colon. Anesthesiology. 2009;110(3):496–504.

36.

Hiltebrand LB, Kimberger O, Arnberger M, Brandt S, Kurz A, Sigurdsson GH. Crystalloids versus colloids for goal-directed fluid therapy in major surgery. Crit Care. 2009;13(2):R40.

Creative Commons License © 2014 The Author(s). This work is published and licensed by Dove Medical Press Limited. The full terms of this license are available at https://www.dovepress.com/terms.php and incorporate the Creative Commons Attribution - Non Commercial (unported, v3.0) License. By accessing the work you hereby accept the Terms. Non-commercial uses of the work are permitted without any further permission from Dove Medical Press Limited, provided the work is properly attributed. For permission for commercial use of this work, please see paragraphs 4.2 and 5 of our Terms.