key: cord-025170-dtbm4ue1
authors: Malbrain, Manu L. N. G.; Langer, Thomas; Annane, Djillali; Gattinoni, Luciano; Elbers, Paul; Hahn, Robert G.; De laet, Inneke; Minini, Andrea; Wong, Adrian; Ince, Can; Muckart, David; Mythen, Monty; Caironi, Pietro; Van Regenmortel, Niels
title: Intravenous fluid therapy in the perioperative and critical care setting: Executive summary of the International Fluid Academy (IFA)
date: 2020-05-24
journal: Ann Intensive Care
DOI: 10.1186/s13613-020-00679-3
sha: 
doc_id: 25170
cord_uid: dtbm4ue1

Intravenous fluid administration should be considered as any other pharmacological prescription. There are three main indications: resuscitation, replacement, and maintenance. Moreover, the impact of fluid administration as drug diluent or to preserve catheter patency, i.e., fluid creep, should also be considered. As for antibiotics, intravenous fluid administration should follow the four Ds: drug, dosing, duration, de-escalation. Among crystalloids, balanced solutions limit acid–base alterations and chloride load and should be preferred, as this likely prevents renal dysfunction. Among colloids, albumin, the only available natural colloid, may have beneficial effects. The last decade has seen growing interest in the potential harms related to fluid overloading. In the perioperative setting, appropriate fluid management that maintains adequate organ perfusion while limiting fluid administration should represent the standard of care. Protocols including a restrictive continuous fluid administration alongside bolus administration to achieve hemodynamic targets have been proposed. A similar approach should be considered also for critically ill patients, in whom increased endothelial permeability makes this strategy more relevant. Active de-escalation protocols may be necessary in a later phase. The R.O.S.E. conceptual model (Resuscitation, Optimization, Stabilization, Evacuation) summarizes accurately a dynamic approach to fluid therapy, maximizing benefits and minimizing harms. Even in specific categories of critically ill patients, i.e., with trauma or burns, fluid therapy should be carefully applied, considering the importance of their specific aims; maintaining peripheral oxygen delivery, while avoiding the consequences of fluid overload.

Intravenous fluids have been in clinical use for over a century, yet the medical and scientific community have only recently begun to appreciate the importance of judicious fluid administration, the necessity to handle them as any other drug we prescribe [1] [2] [3] [4] , and the considerable side effects with which they may be associated [5, 6] .

Three major indications exist for intravenous fluid administration [1, 4, [7] [8] [9] : resuscitation, replacement, and maintenance. Resuscitation fluids are used to correct an intravascular volume deficit or acute hypovolemia; replacement solutions are prescribed to correct existing or developing deficits that cannot be compensated by oral intake alone [6] ; maintenance solutions are indicated in hemodynamically stable patients that are not able/allowed to drink water in order to cover their daily requirements of water and electrolytes [10, 11] . In addition to these classical indications, the quantitative relevance of fluids administered as drug diluents and to guarantee catheter patency, the so-called fluid creep, has been recently underlined [12, 13] .

Although the use of intravenous fluids is one of the most common interventions in medicine, the ideal fluid does not exist. In light of recent evidence, a reappraisal of how intravenous fluids should be used in the perioperative and critical care setting is warranted. Here, we present the executive summary on this area of the International Fluid Academy (https ://www.fluid acade my.org).

Similarly to antibiotics, the 4 Ds of fluid therapy need to be considered (Table 1 ) [4] .

Fluids are drugs with indications, contraindications, and side effects. Different indications need different types of fluids, e.g., resuscitation fluids should focus on rapid restoration of circulating volume; replacement fluids must mimic the fluid that has been lost; maintenance fluids must deliver basic electrolytes and glucose for metabolic needs.

The dose makes the poison, as stated by Paracelsus. However, timing and administration rate are equally important for fluids [14, 15] . Of note, in contrast to most drugs, there is no standard therapeutic dose for fluids.

The duration of fluid therapy is crucial and volume must be tapered when shock is resolved. However, while "starting triggers" for fluid resuscitation are quite clear, clinicians are less aware of "stopping triggers" of fluid resuscitation.

The final step in fluid therapy is to withhold/withdraw fluids when they are no longer required, thus reducing the risk of fluid overload and related deleterious effects [16] .

Intravenous "balanced" solutions include crystalloids and colloids with minimal effect on the homeostasis of the extracellular compartment, and in particular on acid-base equilibrium and electrolyte concentrations [3] . In addition, the term "balanced" has been recently applied also to fluids with a low chloride content (Cl − ). Therefore, there are two main categories of balanced solutions ( Table 2 ): (1) fluids causing a minimal effect on acid-base equilibrium, having an electrolyte content with an in vivo strong ion difference (SID), i.e., the SID after metabolism of the organic anion, close to 24-29 mEq/L; (2) fluids having a normal or sub-normal Cl − content (Cl − ≤ 110 mEq/L).

According to the quantitative approach to acid-base equilibrium [17, 18] , the three variables regulating the pH of biologic fluids independently are (1) partial pressure of carbon dioxide (PCO 2 ); (2) the concentration of non-volatile weak acids (A TOT ); (3) the strong ion difference (SID), defined as the difference between the sum of all strong cations and the sum of all strong anions [19] . These principles clearly suggest that intravenous fluids may affect pH due to (i) the specific electrolyte content characterizing the solution, therefore altering the SID of the extracellular compartment and (ii) the dilution effect due to the volume infused, thus reducing the concentration of A TOT [20] [21] [22] . Ideally, the fluid able to leave plasma pH unchanged after its administration, at constant PCO 2 , should balance these variations. Recent studies clearly showed that, in this regard, the ideal balanced solution should have an in vivo SID equal to the baseline concentration of HCO 3 − [23] . If the SID of the infused fluid is greater than plasma HCO 3 − , plasma pH will tend toward alkalosis; if the SID of the infused fluid is lower than plasma HCO 3 − , plasma pH will tend toward acidosis, as it is always the case for NaCl 0.9%, the so-called "normal" saline [24] .

As stated above, the definition of "balanced" solution includes also a category of iso-and near-isotonic fluids with a low Cl − content (equal to or lower than 110 mEq/L), as compared to NaCl 0.9%. Nonetheless, the final composition of such a fluid, especially when considering crystalloids, will depend on (1) tonicity; (2) electrical neutrality and (3) SID. Indeed, an isotonic balanced solution leaving unaltered acid-base equilibrium (i.e., with an SID close to 24 mEq/L) will necessarily have a Cl − content > 110 mEq/L (as in Sterofundin-ISO). In contrast, a fluid with an SID of 24 mEq/L and a lower Cl − content will necessarily be slightly hypotonic (as with Lactated Ringer's). Finally, an isotonic fluid with a low Cl − content will necessarily have a higher SID (as with PlasmaLyte), with a consequent alkalizing effect. [25, 26] . On the other hand, in an experimental model of near-fatal hemorrhagic shock, a lower dose of balanced solution was needed, as compared to NaCl 0.9% to restore a target blood pressure [27] . These conflicting results underline the fact that findings about fluid therapy are condition-specific, and that results obtained from septic patients or experimental models should not be extrapolated to all situations. Despite these controversies, which need further clarification, several definitive differences exist between these two categories of drugs. First, chloride-rich NaCl 0.9% causes a higher dose-dependent degree of acidosis and hyperchloremia, which possibly favors the contraction of vascular smooth muscles [28, 29] , potentially leading to a reduced renal perfusion.

When healthy volunteers received 2 L of either saline or Plasma-Lyte over 1 h, saline significantly decreased renal artery blood velocity, decreased renal cortical tissue perfusion, decreased urine output, and increased extravascular fluid accumulation compared with Plasma-Lyte [30] . These findings may support the idea that hyperchloremia may cause increased tubule-glomerular feedback and decreased renal cortical perfusion [31] .

Indeed, a large-scale propensity-matched observational analysis of U.S. insurance data showed that the use of PlasmaLyte ® versus NaCl 0.9% on the first day of major abdominal surgery led to significantly less renal failure requiring dialysis [32] . In addition to the effect on renal perfusion, NaCl 0.9%, being slightly hypertonic, likely causes an increased incretion of arginine vasopressin. These two effects can conceivably contribute to the slower renal excretion of NaCl 0.9% as compared to balanced solutions [33, 34] . Indeed, more fluid will be retained in the interstitial space, with the consequent propensity to cause more edema [35, 36] . However, it is not merely the renal function that could be deranged by high chloride concentrations; infusion of NaCl 0.9% can cause abdominal discomfort in healthy volunteers [37] and a reduced gastric perfusion in elderly surgical patients [38] .

Two important and large randomized controlled trials comparing the use of balanced solutions and normal saline have been published in the last years. The SPLIT

In-vivo SID-all organic molecules contained in balanced solutions are strong anions. The resulting calculated SID (in vitro-SID) is equal to 0 mEq/L, due to electrical neutrality. Once infused, the organic molecules are metabolized to CO 2 and water; the resulting in vivo-SID corresponds to the amount of organic anions metabolized a Sterofundin-ISO or Ringerfundin b In vivo-SID of Tetraspan reported in the Table results from the sum of organic anions; of note, there is a discrepancy as compared to the SID calculated as the difference between inorganic cations and inorganic anions (29 mEq/L vs. 33 mEq/L). No study was the first multi-center double-blind randomized controlled trial performed on 2092 patients, comparing balanced and unbalanced fluids in intensive care units. It showed no significant difference in the main outcome, i.e., incidence of acute kidney injury [39] . While providing a high level of evidence, this trial did not give a definitive answer. Indeed, the median volume of study fluid was only 2 L over 90 days. Moreover, both study groups had received a median volume of 1.0-1.2 L of PlasmaLyte within 24 h prior to enrolment, therefore making it plausible that prior administration of PlasmaLyte counterbalanced the effects of low-dose NaCl 0.9%. The SMART-trial was a large study performed in five intensive care units of a single academic center [40] . A total of 15,802 patients were randomized to receive either NaCl 0.9% or a balanced solution (Plasma-Lyte A or Lactated Ringer's).

In both groups, patients received an extremely small amount of fluids: a median of 1 L from admission to day 30 or discharge, whichever came first. Despite the unexpectedly low volume of crystalloids, the authors found a small difference in the primary outcome, i.e., the incidence of major adverse kidney events within 30 days (composite of death, new renal replacement therapy or persistent renal dysfunction) in favor of balance solutions. Looking at the overall outcome, it is important to emphasize that there was no reduction of in-hospital mortality and that neither the incidence of renal replacement therapy (2.5% vs. 2.9%, p = 0.08) nor the incidence of persistent renal dysfunction (6.4% vs. 6.6%, p = 0.60) was statistically significant. A similar study performed by the same authors and published in the same issue of the New England Journal of Medicine, the SALT-ED trial, found a similar difference in the incidence of major adverse kidney events in noncritically ill adults [41] . In summary, we can avoid fluid-induced metabolic acidosis and excessive chloride loading simply using balanced solutions. There is increasing evidence that an excessive chloride administration may have a detrimental effect on renal function, even at low doses. Therefore, the use of balanced solutions, particularly in patients that potentially need a significant amount of intravenous fluids, seems to be a reasonable pragmatic choice [42] . On the contrary, saline may be an intuitive choice for patients with hypovolemic hyponatremia or hypochloremic metabolic alkalosis. In any other settings, the most important reason to choose NaCl 0.9% over balanced solutions is likely economic in nature. Therefore, the patient's serum chloremia is an important factor to determine the appropriate type of fluids.

Albumin accounts for approximately 50% of the plasma protein content [43] and is the main determinant of plasma oncotic pressure, playing a crucial role in the regulation of microvascular fluid dynamics [44, 45] . Normal plasma concentration of albumin ranges between 35 and 55 g/L, corresponding to approximately 0.54-0.85 mmol/L, and to an in vitro pressure of approximately 9.2 mmHg. In contrast, in vivo colloid-oncotic pressure is lower, since the permeability of the endothelial barrier to albumin is variable, even in healthy subjects. Nonetheless, according to Starling's law, oncotic pressure is the force counteracting intravascular hydrostatic pressure, therefore acting to reabsorb water and small solutes from the interstitium to the intravascular space. The crucial role of albumin's oncotic property in the regulation of microcirculatory fluid dynamics also seems to apply to the endothelial glycocalyx layer [46, 47] . This gel-like layer, lining the luminal side of the endothelium, is thought to comprise 20% of the intravascular volume. The current view of the glycocalyx is that it holds many compounds that are mandatory for the functioning of the endothelium and mediates several key physiological processes, such as maintaining the vascular barrier, hemostasis, prevention of cell adhesion to the endothelium and transmission of shear stress [48] . The role of the glycocalyx is however under continuous investigation and its role and function might need to be revised in the future [49] . Of note, shedding of the glycocalyx occurs in the presence of reactive oxygen species, hyperglycemia, cytokines, and endotoxin, and is therefore common in critically ill patients [50] . In the context of fluid homeostasis, loss of barrier function induced by glycocalyx shedding is associated with the formation of edema [51] . Furthermore, fluid therapy itself is known to be potentially deleterious for endothelial function [27] , likely because of the resulting oxidative stress. However, the risks probably relate to the specific clinical context. Indeed, while volume loading did not cause glycocalyx shedding in surgical patients and healthy volunteers [52, 53] , the amount of glycocalyx shedding was proportional to the volume of fluid given in septic shock patients [54] .

The ALBIOS study, a large Italian randomized controlled trial, gave some suggestions on whether or not albumin administration improves outcomes in severe sepsis and septic shock [55] . Patients with severe sepsis were randomized to receive either 20% albumin and crystalloids or crystalloids alone after initial early goal-directed resuscitation. In patients randomized to albumin treatment, albumin was supplemented for 28 days, to maintain an albumin concentration ≥ 30 g/L. Despite some beneficial physiologic effects (lower heart rates, higher mean arterial pressure, and lower daily net positive fluid balance over the first 7 days), no difference was observed either in mortality at 90 days (41.1% vs. 43.6%) or in overall organ failure scores. However, when analyzing the results according to disease severity, patients with septic shock randomized to albumin supplementation showed a lower risk of death (relative risk 0.87; 95% confidence interval-CI 0.77-0.99) as compared to those just receiving only crystalloids. It is worth mentioning that this trial did not utilize albumin as a resuscitation fluid, but as a drug to correct hypoalbuminemia.

Colloids should remain in the intravascular space longer than crystalloids, provided that the endothelial barrier is intact, which is often not the case in critically ill patients [56] . Given the recent discussion on the potential adverse effects of artificial colloids, especially of hydroxyethyl starches (HES), a renewed interest in the use of albumin has emerged. However, despite the strong physiologic rationale and significant scientific effort [55, 57] , to date, no randomized controlled trial has shown any significant benefit of fluid resuscitation using albumin over other types of fluids, including crystalloids [58] . Some reports have even suggested that albumin administration in the setting of cardiac surgery may be associated with the development of acute kidney injury [59] . As stated previously, one of the largest albumin trials to date, the ALBIOS study, reported a reduction in 90-day mortality in a subgroup of patients with septic shock. However, this result was based on a post-hoc rather than predefined analysis and should, therefore, be interpreted with caution. The results of two ongoing randomized trials, the ALBumin Italian Outcome Septic Shock-BALANCED Trial (ALBIOSS-BALANCED) and the Albumin Replacement Therapy in Septic Shock (ARISS), may provide some answers to the above-mentioned issues.

The significant cost and the availability of equally effective low-cost alternatives do not play in favor of albumin, although a subgroup analysis of the ALBIOS dataset may suggest that albumin infusion is likely cost-effective in patients' septic shock [60] . Up to date, the theoretical benefits of albumin are not supported by sound clinical evidence, and the case for albumin remains controversial.

The aim of perioperative fluid therapy, in parallel with the maintenance of the effective circulating blood volume, is to avoid both fluid overload and under-hydration, while maintaining patients' fluid balance as close as possible to zero. Despite this rationale, it is not unusual for surgical patients to receive 5-10 L of fluid and 600-1000 mmol of sodium, leading to edema and adverse outcomes [61] , which is also favored by the marked and mean arterial pressure-dependent reduction of the elimination capacity of crystalloids [62, 63] . On the other hand, overnight fasting and bowel preparation, when traditionally applied, lead to fluid deficits. Apparently, patients develop postoperative complications when fluid retention exceeds 2.5 L [32, 64] . Of course, fluid gain depends not only on the amount of fluid administered, but also on the capacity of the kidney to excrete the excessive fluid and salt [32] .

Fluid therapy is not only meant to compensate intraoperative losses but should also take into account those occurring prior to surgery, induced by poor water intake, bowel preparation, major inflammation associated with a stress response, and possibly, hemorrhage. Dehydration, however, is difficult to detect through clinical methods.

Many studies examined whether a fluid load is capable of reducing hypotension caused by the induction of general/regional anesthesia. However, results regarding a preload strategy have been discouraging [65, 66] .

In response to the ongoing administration of large volumes of crystalloid to patients undergoing major surgery, a 'fluid restrictive' strategy has been proposed. For example, Brandstrup et al. demonstrated in a multicenter randomized controlled trial that a more restrictive regimen was associated with better outcomes following colorectal surgery [61] . However, the regimen was restrictive compared with the standard of care that was excessive (e.g., 5 L positive balance due to high crystalloid volumes) [67] . It is therefore conceivable that the group with a better outcome rather benefitted from the avoidance of fluid excess than from fluid restriction. The interpretation of the literature on the topic is hampered by the use of very heterogeneous definitions [68] . What is however clear from observational studies is that both too much and too little fluid are associated with poor outcomes [69] [70] [71] [72] . Recently, a large cohort study from 500 U.S. hospitals including adult patients having colon, rectal or primary hip or knee surgery was concluded [72] . A significant association was found between liberal fluid administration on the day of surgery and worse outcomes (increased total costs and length of stay in all patients), as well as increased presence of postoperative ileus, in patients undergoing colorectal surgery. Interestingly, the authors also observed that restrictive fluid utilization (the lowest 25% by volume) was also associated with worse outcomes.

It is common in Enhanced Recovery after Surgery (ERAS) protocols to find the term "intraoperative fluid restriction" [73] . However, alternative terms, such as "zero balance" or the avoidance of salt and water excess, are also available. Protocols advocate the infusion of balanced crystalloid of 1-3 ml/kg/h and to give additional boluses of fluid only to match needs judged by either measured volumes lost during surgery, or the assessment of peripheral perfusion (such as according to the so-called 'Goal-Directed Fluid Restriction') [74] . Overall, the literature suggests that algorithm-based perioperative fluid regimens result in improved patient outcomes.

Fluid management in postoperative patients is a key determinant of their outcomes. While restoring effective volume is critical for these patients, fluid management should not compromise healing processes. Optimal fluid management should thus target efficient central hemodynamics and tissue perfusion while avoiding positive net fluid balance. In theory, colloids offer the advantages over crystalloids of higher plasma expansion capacity and longer plasma half-life. They have the theoretical disadvantage of delaying clotting time and increasing the risk of kidney injury. In randomized trials, the ratio of the cumulative dose of colloids over the cumulative dose of crystalloids ranged roughly from 0.41 to 1 [75] . In patients with overt clinical hypovolemia, colloids were superior to crystalloids in improving cardiac filling pressures and performance [76] . Likewise, in a large multinational randomized trial performed in critically ill patients with acute hypovolemia, colloids reduced vasopressor and ventilator dependency when compared to crystalloids [77] . A recent systematic review of resuscitation with HES in surgical critically ill patients identified 13 randomized trials [78] . However, this review found no statistically significant difference between HES and crystalloids, in terms of mortality (risk ratio 2.97; 95% CI 0.96 to 9.19; I 2 = 0%), need for renal replacement therapy (risk ratio 1.11; 95% CI 0.26 to 4.69; I 2 = 34%), and major infectious complications (risk ratio 1.19; 95% CI 0.59 to 2.39; I 2 = 0%). It is worth mentioning that eligible trials were too small to draw firm conclusions on this issue.

It should also be stated that there are opposing views regarding the use of starches [79] . For example, several criticisms regarding the CHEST trial have been put forward which still require to be addressed [80, 81] . Furthermore, it can be stated that in the CHEST trial starches were administered to patients that were not hypovolemic. On the other hand, the CRISTAL trial (where 70% of the colloid group received HES) concluded that significantly less volume was required to achieve hemodynamic stability for HES vs. NaCl in the initial phase of fluid resuscitation in severe sepsis patients without any difference for adverse events in both groups [77] . Taking these opposing views into consideration, the ongoing debate about the use of starches in hypovolemic critically ill patients still requires more data.

Among patients undergoing major abdominal surgery, the recent results of the FLASH trial, showed no significant difference in a composite outcome of death or major postoperative complications within 14 days after surgery [82] .

Pending the results of ongoing trials, there are currently insufficient data to ban the use of colloids in the surgical intensive care unit.

Many patients undergoing surgery are not able to ingest food or fluids for some time following surgery and will require maintenance fluids. Recently, a debate emerged on the tonicity of these solutions: although guidelines traditionally recommended the use of hypotonic maintenance fluids, in pediatric literature, these were shown to be associated with an increased incidence of symptomatic hyponatremia [83, 84] . The recent randomized controlled TOPMAST trial in adults undergoing major thoracic surgery found this problem to be mild in these patients. Isotonic maintenance fluids, on the other hand, were associated with a considerably larger positive cumulative fluid balance (estimated at 1.4L more positive under fluids containing 154 compared to 54 mmol/L of sodium) [85] .

The problem with fluid overload in the perioperative setting A certain degree of hypervolemia is necessary to maintain organ perfusion during anesthesia and surgery. However, fluid given after the induction of anesthesia mainly increases "unstressed" blood volume, because vasodilatation occurs as a consequence of anesthesia. At this point, additional fluid administration is needed to optimize stroke volume, i.e., to add to the "stressed" intravascular volume [86] . Many clinicians still consider this "wet" approach as the gold standard for intraoperative fluid therapy [87] , although intravascular volume expansion certainly bears some dangers. Myocardial work and cardiac pressures increase when infused fluids have exceeded the degree of anesthesia-induced vasodilatation. Moreover, fluid overload reduces the colloid osmotic pressure that, together with raised cardiac pressures, might promote pulmonary edema [88] . These issues are of particular relevance in patients with poor cardiovascular status. Finally, hypervolemia may be responsible for another important effect: the release of atrial natriuretic peptides (ANPs) to the circulation caused by the stretching of atrial myocardial fibers [68, 89] . Indeed, in response to a rapid infusion of crystalloids, ANP levels increase 2-to 3-fold [90] [91] [92] , therefore reducing strain on the circulation by promoting natriuresis and capillary leakage of albumin.

Fluid administration is one of the cornerstones of hemodynamic resuscitation in critically ill patients. How much fluid to give has been the subject of lively debate over the years. Too much fluid can have harmful consequences on multiple organ systems, e.g., worsening gas exchange, renal function and wound healing. Fluid overload is particularly likely to arise in conditions when capillary permeability is altered due to an inflammatory response, such as during sepsis. A positive fluid balance has been associated with worse outcomes in several studies in various groups of intensive care unit (ICU) patients [16, [93] [94] [95] . In patients with septic shock, fluid administration and positive fluid balance were independently associated with increased mortality rates [93, 96] . Similarly, in patients admitted to the ICU after major surgery, fluid balance was an independent risk factor for death [95] . Indeed, a multimodal restrictive fluid strategy aiming for negative fluid balance (PAL-treatment) in patients with acute lung injury (ALI) was associated with improved outcomes in a retrospective study [97] .

It has to be acknowledged that a positive fluid balance could be a marker of disease rather than a pure iatrogenic or preventable problem and it would be erroneous to assume the default position of underresuscitation. Indeed, inadequate resuscitation due to insufficient fluid administration may result in poorer tissue perfusion and hence organ dysfunction and failure, particularly in the early phase of treatment. A balance needs to be achieved, such that each patient receives sufficient, but not excessive, fluid for her/his needs. Crucially, different patients will have different needs and baseline fluid status depending on multiple factors including age, co-morbid disease and current diagnosis. In addition, it is mandatory to consider indices of fluid tolerance, such as CVP, lung water, oxygenation and hemoglobin levels. Fluid requirements vary during the course of illness. As such, fluids must be prescribed on an individual patient basis; the prescription should be regularly reviewed and tailored to the evolving clinical stage. The answer to the question of whether fluid overload is a problem in the ICU will thus depend on when it is asked. In the acute resuscitation/ salvage phase, fluid administration is generous. While fluid overload should always be a concern, a positive fluid balance is a specific target of this phase.

The term deresuscitation/de-escalation was first suggested in 2012 [98] and finally coined in 2014 [16] . It specifically refers to 'Late Goal-Directed Fluid Removal' , which involves "aggressive and active fluid removal through diuretics and renal replacement therapy with net ultrafiltration". Deresuscitation/de-escalation is sometimes also used to more loosely refer to the phase of critical illness and/or the care of a critically ill patient, after initial resuscitation, stabilization, and optimization. It is characterized by the discontinuation of invasive therapies and a reduction of a spurious fluid balance. Late conservative fluid management is defined as 2 consecutive days of negative fluid balance within the first week of ICU stay, and is an independent predictor of survival in ICU patients [16] .

Fluid overload and a positive cumulative fluid balance are associated with increased morbidity and worse outcomes, as previously discussed. The natural course of events after a first insult (such as infection, trauma, etc.) is a systemic inflammatory response with increased capillary permeability and organ dysfunction [98] . The presence of fluid overload and interstitial edema may thus trigger a vicious cycle. This is what has been referred to as the Ebb phase of shock [16] . In the majority of patients, shock reversal occurs (with correct antibiotics and proper source control) and excess fluids can be mobilized: this is called the Flow phase [16] . However, some patients will not transfer spontaneously from the Ebb to Flow phase and will remain in a state of unresolved shock with positive cumulative fluid balance, and this is where active deresuscitation/de-escalation might have an important role.

It is unclear which is the best therapeutic option for deresuscitation/de-escalation. The administration of albumin in combination with diuretics (20% albumin to achieve a serum albumin levels of 30 g/L and furosemide bolus of 60 mg followed by continuous infusion of 10 mg/h) and the association of this strategy with the sequential application of PEEP set to counteract intraabdominal pressure (IAP) have been proposed [97] . In addition, renal replacement therapy and aggressive ultrafiltration can be used to achieve a negative fluid balance in selected patients [99] . When it comes to deresuscitation/de-escalation, it is important to decide on when, how and for how long. For this purpose, we need to use the right targets to reach our goals. "Over-deresuscitation" has its drawbacks and may cause neurologic dysfunction in the long run [100] .

In conclusion, it is crucial to ensure that the indication for fluid resuscitation no longer exists (e.g., absence of vasopressor, no lactate, adequate venous oxygen saturation of hemoglobin) before starting with deresuscitation. Furthermore, the 5 steps of Deresuscitation/De-Escalation need to be kept in mind: (1) define a clinical endpoint (e.g., improvement in oxygenation); (2) set a fluid balance goal (e.g., 1 L negative balance in 24 h); (3) set perfusion and renal safety precautions (e.g., vasopressor need, 25% serum creatinine increase); (4) re-evaluate after 24 h unless safety limits reached; (5) adjust the plan accordingly.

Two articles were published recently, almost simultaneously, referring to the dynamics of fluid therapy [16, 101] . These conceptual models identified four dynamic phases. The Acute Dialysis Quality Initiative (ADQI) group proposed S.O.S.D. (Salvage, Optimization, Stabilization, De-escalation) as acronym [101] . However, during the International Fluid Academy Day (IFAD) meetings there was a clear preference for the R.O.S.E. acronym (Resuscitation, Optimization, Stabilization, Evacuation) as summarized below, in Fig. 1 and Table 3 . We tried to suggest endpoints and targets for the different phases; however, it was decided not to include them because there cannot be a specific target of cardiac index and PPV must be considered only if cardiac output is low. A high PPV is often a physiological state and defining a "normal" state when a low PPV value is reached might lead to unnecessary fluid infusion [102] . Also, defining a given preload level as a target of resuscitation is senseless as it may shift from patient to patient and from time to time.

In the first, salvage/resuscitation phase, when a patient presents with hemodynamic shock, the aim of the treatment is resuscitation and correction of shock with the achievement of an adequate perfusion pressure. A rapid fluid bolus should be given (although the exact amount can vary, usually 3-4 mL/kg given over 10 to 15 min and repeated when necessary), normally in association with vasopressor administration. In parallel, emergency procedures to resolve any obvious underlying cause should be performed, with hemodynamic monitoring initiated. In this phase, the goal is early adequate goal-directed fluid management: fluid balance must be positive. We do not support blind adherence to the surviving sepsis campaign guidelines adagio to administer 30 ml/kg of fluids within the first hour for all patients, as explained previously [9] . This may lead to either over-or under resuscitation in some patients. Every patient needs an individual and personalized approach.

The optimization phase starts when the patient is no longer in overt absolute/relative hypovolemia, but remains hemodynamically unstable. Some form of monitoring will by now be in place. Fluids should be administered according to individual needs, reassessed on a regular basis, e.g., using fluid challenge techniques [103, 104] . Fluid challenges must be conducted carefully, bearing in mind the four essential components (TROL): Type of fluid (e.g., a balanced crystalloid-like PlasmaLyte); Rate (e100-200 mL over 10 min); Objective (e.g., normal arterial pressure or heart rate); and Limits (e.g., high central venous pressure level) (Fig. 2) [105] . The aim of this phase is to optimize and maintain adequate tissue perfusion and oxygenation in order to prevent and limit organ damage. The patient must be carefully monitored during the optimization phase: often several types of monitoring (e.g., arterial catheter, echocardiography, central venous pressure, arteriovenous blood gas) are required to obtain the most complete picture of a patient's hemodynamic status.

Although a resuscitation based on microcirculatory endpoints is expected to result in analogous amelioration in the microcirculation, a lack of coherence may exist between macro-and microcirculation. Thus, markers of hypoperfusion should include also lactate, prolonged capillary refill time and mottling score [106] .

Once the patient is stable, the stabilization phase begins and evolves over days. In this phase, the aim of fluid management is to ensure water and electrolytes to replace ongoing losses and provide organ support. The target should be a zero or slightly negative fluid balance. It might be of interest, in this context, to underline the Weeks fact that in the major trials suggesting a harmful effect of starches [2, 107] , these colloids were given abundantly also in the stabilization phase, i.e., in a phase that possibly did not require these drugs.

The final phase is evacuation or de-escalation, with the purpose of removing excessive fluid. This will be frequently achieved by spontaneous diuresis as the patient recovers, although ultrafiltration or diuretics might be necessary. Of note, it was recently shown that diuretics might favor the recruitment of microcirculation, thus decreasing diffusion distances and improving oxygen extraction [108] .

Fluid management in acute hemorrhagic shock following trauma

Although traumatic brain injury remains the commonest cause of death following severe blunt injury, concomitant major hemorrhage will result in cerebral hypoperfusion, which undoubtedly contributes to secondary brain injury and death. As such, hemorrhage remains the most preventable cause of trauma mortality. An adequate intravascular volume, hemoglobin concentration and oxygen saturation are essential to maintain aerobic metabolism. Humans do not tolerate anaerobic metabolism and 90% of oxygen consumption is used in the formation of adenosine triphosphate (ATP), the major energy source for cell function. Rapid reversal of anaerobic metabolism is imperative to restore ATP and prevent irreversible cellular apoptosis and death [109] . Recognizing that hypovolemia is the consequence of hemorrhagic shock, past strategies utilized crystalloids to restore intravascular volume, followed by blood transfusion. Crystalloids, however, do not carry oxygen, and oxygen delivery may only be enhanced by an adequate hemoglobin concentration. Furthermore, major hemorrhage is accompanied by a unique coagulation disorder, the Acute Coagulopathy of Trauma and Shock (ACoTS) [110] , leading to poor clot formation, as a result of increased binding of thrombin to thrombomodulin and enhanced fibrinolysis. Dilution of coagulation factors, acidosis, and hypothermia play a secondary role in this scenario. The approach to resuscitation must therefore be proactive and not reactive with the combined administration of packed red blood cells, plasma, platelets, and cryoprecipitate. The use of clear resuscitation fluids should be minimized. Based on military experience, the recommended ratio of packed red blood cells to plasma and platelets should be 1:1:1. The endpoints for hemoglobin concentration of 10 g/dL, a platelet count of > 50,000, an INR < 1.5 and a fibrinogen concentration of > 1 g/L cannot be generally recommended. In addition, the ionized calcium level should be > 1.0 mmol/L.

While the above is a general recommendation, not all patients will require such an aggressive approach [111] . Indeed, over-zealous transfusion is associated with unwanted complications.

The standard approach has been to use conventional laboratory coagulation testing to determine the need for component therapy. These, however, are performed at room temperature and do not reflect individual steps in coagulation. Thromboelastometry has now been recognized as an essential tool to monitor coagulopathy in trauma [112] . This device reflects the entire process of coagulation and can graphically determine the need for specific coagulation factors. Unlike laboratory coagulation studies, modern thromboelastometry machines may be set to the patient's core temperature and accurately reflect the in vivo coagulation status. These instruments should be the standard of care in centers handling major trauma.

Following the CRASH-2 trial indicating the benefit of tranexamic acid given within 3 h from injury, such treatment has been included in many protocols for major hemorrhage [112] . In the presence of a sophisticated trauma system, the benefits are doubtful and further data are warranted [113] .

The understanding of burn shock pathophysiology and subsequent development of fluid resuscitation strategies resulted in dramatic outcome improvements in burn care during the last decades [114] . However, while under-resuscitation has become rare in clinical practice, there is growing concern that over-resuscitation, leading to increased morbidity and mortality, has become more of an issue in burn care. In the late sixties of the previous century, Baxter and Shires developed their landmark formula at the Parkland Memorial Hospital, which has lasted decades as the gold standard for fluid resuscitation in acute burn care across the world [115] . The formula advocates 4 ml crystalloids per kg per % of total body surface area for 24 h, of which half is given during the first 8 h. Diuresis (target 1 ml/kg/h) is used to guide the amount of intravenous fluids. During the second 24 h of resuscitation, colloids are allowed, and resuscitation volume is adapted according to diuresis (with a gradual decrease if diuresis is adequate).

However, over the last 15 years, multiple centers have reported excess fluid administration [116, 117] . This fluid excess often leads to "resuscitation morbidity", a group of complications linked to fluid overload, such as delayed wound healing, delayed recovery of gastrointestinal function (with ileus), pulmonary edema (due to capillary leak and increased extravascular lung water), limb compartment syndrome, orbital compartment syndrome, intra-abdominal hypertension and abdominal compartment syndrome leading to multiple organ failure [118] [119] [120] .

This discrepancy between the predicted and the administered fluid is known as "fluid creep", a term brought to life by Basil Pruitt [119] .

Recommendations for fluid resuscitation in burns are listed in Table 4 . The most well-known adverse effect of NaCl 0.9% is hyperchloremic metabolic acidosis. Given the large infusion volumes administered to burn patients, balanced solutions are preferred. Indeed, since the beginning of burn resuscitation, most formulae advocate the use of balanced crystalloid solutions. Of note, an observational study reported lower Sequential Organ Failure Assessment (SOFA) scores in severely burned patients resuscitated with acetated Ringer's [121] .

The use of colloids in the first 24 h has been controversial since it was thought that the existing capillary leak would allow large molecules to leak out into the extravascular space and exert an osmotic pull increasing the formation of edema [122] . In the last 15 years, renewed interest in colloids has arisen during burn resuscitation, instigated by the awareness of morbidity related to resuscitation and fluid creep. Until recently, the low molecular weight HES solutions were widely used as a resuscitation fluid in critically ill ICU, surgery and burn patients. However, after large fluid trials, including the CHEST and 6S trials, showing increased mortality and a higher rate of renal replacement therapy have raised alarming conclusions regarding the safety of HES solutions, starches can no longer be used in burn injuries as recommended by the Pharmacovigilance Risk Assessment Committee (PRAC) [2, 107, 123] .

Albumin is a natural plasma protein that contributes most to intravascular oncotic pressure in humans (see above). The most common solutions are 4%, 5% or 20% albumin. It is a relatively expensive solution and its availability may be limited in some countries. Although albumin resuscitation has been used with some reservations, especially in the acute phase of burn resuscitation, trials provide promising data regarding the use of albumin as an adjunctive therapy in burn resuscitation [124, 125] . Similarly, hypertonic saline has been used for decades in burn resuscitation; theoretically, it expands the circulating volume by an intravascular water shift. Proponents claim that this process will decrease tissue edema and will lower the rate of complications. This hypothesis, however, needs to be confirmed by further studies.

Consider the 5 Ps of fluid prescription as shown in Fig. 3 and tailor the IV fluids to the patient's need via individualized and personalized care (Table 5 ) [126] . Prescription safety can be summarized by the '4 Ds' principle as explained above [4] : The bottom line is "Give the right fluid in the right dose to the right patient at the right time"

The prescription of fluid therapy is one of the most common medical acts in hospitalized patients but many of the aspects of this practice are surprisingly complex. It is time to introduce fluid stewardship in your ICU. The physician should engage in writing a prescription that accounts for drug, dose, duration and whenever possible de-escalation. c Pharmacy: The prescription is sent to the pharmacy and is checked for inconsistencies by the pharmacist to get a more holistic view. d Preparation:

The process by which the prescription is prepared and additions (e.g., electrolytes) made. e Patient: The filled prescription goes back to the patient and fluid stewards should observe administration, response, and debrief

To avoid fluid-induced harm, we recommend a careful evaluation of the chosen solution and a phase-wise approach to its administration, taking into account the clinical course of the disease or surgical procedure.

Fluids should be prescribed with the same care as any other drug and every effort should be made to avoid their unnecessary administration. C. Replacement and redistribution If patients have ongoing abnormal losses or a complex redistribution problem, the fluid therapy is adjusted for all other sources of fluid and electrolyte losses (e.g., normal saline may be indicated in patients with metabolic alkalosis due to gastro-intestinal losses)

D. Fluid creep All sources of fluids administered need to be detailed: crystalloids, colloids, blood products, enteral and parenteral nutritional products, and oral intake (water, tea, soup, etc.) Precise data on the concentrated electrolytes added to these fluids or administered separately need to be collected Fluid creep is defined as the sum of the volumes of these electrolytes, the small volumes to keep venous lines open (saline or glucose 5%), and the total volume used as a vehicle for medication

The following information is included in the IV fluid prescription:

The type of fluid The rate of fluid infusion The volume or dose of fluid The IV fluid prescription is adapted to current electrolyte disorders and other sources of fluid intake

Patients have an IV fluid management plan, including a fluid and electrolyte prescription over the next 24 h The prescription for a maintenance IV fluid only changes after a clinical exam, a change in dietary intake or evaluation of laboratory results

Fluid management before, during and after elective surgery

Hydroxyethyl starch 130/0.42 versus Ringer's acetate in severe sepsis

Intravenous balanced solutions: from physiology to clinical evidence

It is time to consider the four D's of fluid management

Association between a chloride-liberal vs chloride-restrictive intravenous fluid administration strategy and kidney injury in critically ill adults

Resuscitation fluids

National Institute for H, Care Excellence Guideline Development G. Intravenous fluid therapy for adults in hospital: summary of NICE guidance

Intravenous fluid therapy for hospitalized and critically ill children: rationale, available drugs and possible side effects

Principles of fluid management and stewardship in septic shock: it is time to consider the four D's and the four phases of fluid therapy

Effect of isotonic versus hypotonic maintenance fluid therapy on urine output, fluid balance, and electrolyte homeostasis: a crossover study in fasting adult volunteers

Maintenance intravenous fluids in acutely ill patients

Maintenance fluid therapy and fluid creep impose more significant fluid, sodium, and chloride burdens than resuscitation fluids in critically ill patients: a retrospective study in a tertiary mixed ICU population

Normal saline to dilute parenteral drugs and to keep catheters open is a major and preventable source of hypernatremia acquired in the intensive care unit

Mortality after fluid bolus in African children with severe infection

Unintended consequences: fluid resuscitation worsens shock in an ovine model of endotoxemia

Fluid overload, de-resuscitation, and outcomes in critically ill or injured patients: a systematic review with suggestions for clinical practice

Independent and dependent variables of acid-base control

Stewartìs textbook of acid-base Lulucom

Electrolyte shifts across the artificial lung in patients on extracorporeal membrane oxygenation: interdependence between partial pressure of carbon dioxide and strong ion difference

Crystalloid strong ion difference determines metabolic acid-base change during in vitro hemodilution

Effects of intravenous solutions on acid-base equilibrium: from crystalloids to colloids and blood components

In vivo conditioning of acid-base equilibrium by crystalloid solutions: an experimental study on pigs

The rule regulating pH changes during crystalloid infusion

Rapid saline infusion produces hyperchloremic acidosis in patients undergoing gynecologic surgery

Kinetics of isotonic and hypertonic plasma volume expanders

Influences of red blood cell and platelet counts on the distribution and elimination of crystalloid fluid

Balanced vs unbalanced crystalloid resuscitation in a near-fatal model of hemorrhagic shock and the effects on renal oxygenation, oxidative stress, and inflammation

Chloride regulates afferent arteriolar contraction in response to depolarization

Regulation of renal blood flow by plasma chloride

Acetate-buffered crystalloid fluids: current knowledge, a systematic review

An acetate-buffered balanced crystalloid versus 0.9% saline in patients with end-stage renal disease undergoing cadaveric renal transplantation: a prospective randomized controlled trial

Major complications, mortality, and resource utilization after open abdominal surgery: 0.9% saline compared to Plasma-Lyte

Effect of volume loading with 1 liter intravenous infusions of 0.9% saline, 4% succinylated gelatine (Gelofusine) and 6% hydroxyethyl starch (Voluven) on blood volume and endocrine responses: a randomized, three-way crossover study in healthy volunteers

Ab)normal saline and physiological Hartmann's solution: a randomized double-blind crossover study

Should chloride-rich crystalloids remain the mainstay of fluid resuscitation to prevent 'pre-renal' acute kidney injury?: con

Iatrogenic salt water drowning and the hazards of a high central venous pressure

The effect of intravenous lactated Ringer's solution versus 0.9% sodium chloride solution on serum osmolality in human volunteers

The effects of balanced versus saline-based hetastarch and crystalloid solutions on acid-base and electrolyte status and gastric mucosal perfusion in elderly surgical patients

Effect of a buffered crystalloid solution vs saline on acute kidney injury among patients in the intensive care unit: The SPLIT randomized clinical trial

Balanced crystalloids versus saline in critically ill adults

Balanced crystalloids versus saline in non-critically ill adults

Balanced crystalloid solutions

Human serum albumin: from bench to bedside

The clinical use of albumin: the point of view of a specialist in intensive care

Albumin in critically ill patients: the ideal colloid?

The endothelial glycocalyx: composition, functions, and visualization

The role of endothelial surface glycocalyx in mechanosensing and transduction

The structure and function of the endothelial glycocalyx layer

Glycocalyx degradation is independent of vascular barrier permeability increase in non-traumatic hemorrhagic shock in rats

The endothelium in sepsis

Reactive oxygen species mediate modification of glycocalyx during ischemia-reperfusion injury

Long intravascular persistence of 20% albumin in postoperative patients

Minimal shedding of the glycocalyx layer during abdominal hysterectomy

Intravenous fluid resuscitation is associated with septic endothelial glycocalyx degradation

Albumin replacement in patients with severe sepsis or septic shock

Role of albumin, starches and gelatins versus crystalloids in volume resuscitation of critically ill patients

Impact of albumin compared to saline on organ function and mortality of patients with severe sepsis

Colloids versus crystalloids for fluid resuscitation in critically ill people

Albumin administration is associated with acute kidney injury in cardiac surgery: a propensity score analysis

Economic model of albumin infusion in septic shock: The EMAISS study

Effects of intravenous fluid restriction on postoperative complications: comparison of two perioperative fluid regimens: a randomized assessor-blinded multicenter trial

Arterial pressure and the rate of elimination of crystalloid fluid

Volume kinetics of Ringer's lactate solution in acute inflammatory disease

Fluids and gastrointestinal function

Is crystalloid preloading useful in spinal anaesthesia in the elderly?

Volume preloading is not essential to prevent spinal-induced hypotension at caesarean section

Variability in practice and factors predictive of total crystalloid administration during abdominal surgery: retrospective two-centre analysis

A rational approach to perioperative fluid management

Perioperative fluid management: turning art to science

Perioperative fluid management: science, art or random chaos?

Importance of intraoperative oliguria during major abdominal surgery: findings of the Restrictive versus Liberal Fluid Therapy in Major Abdominal Surgery trial

Perioperative fluid utilization variability and association with outcomes: considerations for enhanced recovery efforts in sample US surgical populations

Guidelines for perioperative care in elective colorectal surgery: enhanced recovery after surgery (ERAS((R))) society recommendations

Effect of a perioperative, cardiac output-guided hemodynamic therapy algorithm on outcomes following major gastrointestinal surgery: a randomized clinical trial and systematic review

Fluid resuscitation in sepsis: a systematic review and network meta-analysis

Greater cardiac response of colloid than saline fluid loading in septic and non-septic critically ill patients with clinical hypovolaemia

Effects of fluid resuscitation with colloids vs crystalloids on mortality in critically ill patients presenting with hypovolemic shock: the CRISTAL randomized trial

Comparison of hydroxyethyl starch colloids with crystalloids for surgical patients: a systematic review and meta-analysis

EMA recommendation to suspend HES is hazardous

Data too important to share: do those who control the data control the message?

The great fluid debate: methodology, physiology and appendicitis

Effect of hydroxyethyl starch vs saline for volume replacement therapy on death or postoperative complications among high-risk patients undergoing major abdominal surgery: The FLASH randomized clinical trial

140 mmol/L of sodium versus 77 mmol/L of sodium in maintenance intravenous fluid therapy for children in hospital (PIMS): a randomised controlled double-blind trial

NICE CG 174: intravenous fluid therapy in adults in hospital

154 compared to 54 mmol per liter of sodium in intravenous maintenance fluid therapy for adult patients undergoing major thoracic surgery (TOPMAST): a single-center randomized controlled double-blind trial

Volume and its relationship to cardiac output and venous return

Fluid management and goal-directed therapy as an adjunct to Enhanced Recovery After Surgery (ERAS)

Effect of elevated left atrial pressure and decreased plasma protein concentration on the development of pulmonary edema

The endothelial glycocalyx: the great luminal barrier

Plasma atrial natriuretic peptide concentration and renin activity during overhydration with 1.5% glycine solution in conscious sheep

Changes in serum electrolyte and atrial natriuretic peptide concentrations, acid-base and haemodynamic status after rapid infusion of isotonic saline and Ringer lactate solution in healthy volunteers

Population volume kinetics predicts retention of 0.9% saline infused in awake and isoflurane-anesthetized volunteers

A positive fluid balance is an independent prognostic factor in patients with sepsis

Positive fluid balance as a prognostic factor for mortality and acute kidney injury in severe sepsis and septic shock

The effect of excess fluid balance on the mortality rate of surgical patients: a multicenter prospective study

Fluid administration in severe sepsis and septic shock, patterns and outcomes: an analysis of a large national database

Aiming for a negative fluid balance in patients with acute lung injury and increased intra-abdominal pressure: a pilot study looking at the effects of PAL-treatment

Fluid management in critically ill patients: the role of extravascular lung water, abdominal hypertension, capillary leak, and fluid balance

Continuous veno-venous hemofiltration to adjust fluid volume excess in septic shock patients reduces intra-abdominal pressure

The adult respiratory distress syndrome cognitive outcomes study: long-term neuropsychological function in survivors of acute lung injury

Four phases of intravenous fluid therapy: a conceptual model

Liberal versus restrictive fluid therapy in critically ill patients

Fluid challenges in intensive care: the FENICE study: a global inception cohort study

Fluid challenge revisited

Let's give some fluid and see what happens" versus the "mini-fluid challenge

Effects of fluids on the macro-and microcirculations

Hydroxyethyl starch or saline for fluid resuscitation in intensive care

Recruitment of sublingual microcirculation using handheld incident dark field imaging as a routine measurement tool during the postoperative de-escalation phase-a pilot study in post ICU cardiac surgery patients

Recovery of hepatocellular ATP and "pericentral apoptosis" after hemorrhage and resuscitation

Acute coagulopathy of trauma: hypoperfusion induces systemic anticoagulation and hyperfibrinolysis

Early and individualized goal-directed therapy for trauma-induced coagulopathy

Effects of tranexamic acid on death, vascular occlusive events, and blood transfusion in trauma patients with significant haemorrhage (CRASH-2): a randomised, placebo-controlled trial

Do all trauma patients benefit from tranexamic acid?

An overview on fluid resuscitation and resuscitation endpoints in burns: past, present and future. Part 1-historical background, resuscitation fluid and adjunctive treatment

Physiological response to crystalloid resuscitation of severe burns

Fluid creep: the pendulum hasn't swung back yet!

A systematic review on intra-abdominal pressure in severely burned patients

Intra-abdominal hypertension and the abdominal compartment syndrome: updated consensus definitions and clinical practice guidelines from the World Society of the Abdominal Compartment Syndrome

Protection from excessive resuscitation: "pushing the pendulum back

Elevated orbital pressure: another untoward effect of massive resuscitation after burn injury

Safety of resuscitation with Ringer's acetate solution in severe burn (VolTRAB)-an observational trial

Fluid volume and electrolyte changes of the early postburn period

Assessment of hemodynamic efficacy and safety of 6% hydroxyethyl starch 130/0.4 vs. 0.9% NaCl fluid replacement in patients with severe sepsis: the CRYSTMAS study

Burn patient characteristics and outcomes following resuscitation with albumin

Colloid administration normalizes resuscitation ratio and ameliorates "fluid creep

It is time for improved fluid stewardship

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations

MLNGM and NVR are co-founders of the International Fluid Academy (IFA). This open access article is endorsed by the IFA. The mission statement of the IFA is to foster education, promote research on fluid management and hemo-

4 Ds: Drug-Dose-Duration-De-escalation; ANP: Atrial natriuretic peptide; ATP: Adenosine triphosphate; CI: Confidence interval; ERAS: Enhanced recovery after surgery; HES: Hydroxyethyl starch; IAP: Intra-abdominal pressure; ICU: Intensive care unit; PEEP: Positive end-expiratory pressure; ROSE: Resuscitation-Optimization-Stabilization-Evacuation; SID: Strong ion difference; SOFA: Sequential Organ Failure Assessment.

MLNGM wrote the concept. MLNGM wrote first draft. All other authors reviewed and edited the manuscript. All authors read and approved the final manuscript.

Dr. Manu Malbrain is professor at the faculty of Medicine and Pharmacy at the Vrije Universiteit Brussels (VUB) and member of the Executive Committee of the Abdominal Compartment Society, formerly known as the World Society of Abdominal Compartment Syndrome (https ://www.wsacs .org/). He is a cofounder, past-president and current treasurer of WSACS. He is a co-founder of the International Fluid Academy (IFA).

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