Indian Journal of Anaesthesia  
About us | Editorial board | Search | Ahead of print | Current Issue | Past Issues | Instructions
Home | Login  | Users Online: 209  Print this pageEmail this pageSmall font sizeDefault font sizeIncrease font size    




 
 Table of Contents    
REVIEW ARTICLE
Year : 2012  |  Volume : 56  |  Issue : 5  |  Page : 454-462  

Basics of fluid and blood transfusion therapy in paediatric surgical patients


Department of Anaesthesia and Intensive Care, Postgraduate Institute of Medical Education and Research, Chandigarh, India

Date of Web Publication28-Nov-2012

Correspondence Address:
Virendra K Arya
Department of Anaesthesia and Intensive Care, Cardiac Anaesthesia Unit, ACC, PGIMER Chandigarh
India
Login to access the Email id

Source of Support: None, Conflict of Interest: None


DOI: 10.4103/0019-5049.103960

Rights and Permissions
 

Perioperative fluid, electrolyte and blood transfusion therapy for infants and children can be confusing due the numerous opinions, formulas and clinical applications, which can result in a picture that is not practical and is often misleading. Perioperatively, crystalloids, colloids and blood components are required to meet the ongoing losses and for maintaining cardiovascular stability to sustain adequate tissue perfusion. Recently controversies have been raised regarding historically used formulas and practices of glucose containing hypotonic maintenance crystalloid solutions for perioperative fluid therapy in children. Paediatric intraoperative transfusion therapy, particularly the approach to massive blood transfusion (blood loss ≥ one blood volume) can be quite complex because of the unique relationship between the patient's blood volume and the volume of the individual blood product transfused. A meticulous fluid, electrolyte and blood transfusion management is required in paediatric patients perioperatively because of an extremely limited margin for error. This article reviews the basic concepts in perioperative fluid and blood transfusion therapy for paediatric patients, along with recent recommendations. For this review, Pubmed, Ovid MEDLINE, HINARI and Google scholar were searched without date restrictions. Search terms included the following in various combinations: Perioperative, fluid therapy, paediatrics, blood transfusion, electrolyte disturbances and guidelines. Only articles with English translation were used.

Keywords: Fasting, fluid therapy, hyperglycaemia, hypoglycaemia, hyponatraemia, massive blood transfusion, perioperative, transfusion therapy


How to cite this article:
Arya VK. Basics of fluid and blood transfusion therapy in paediatric surgical patients. Indian J Anaesth 2012;56:454-62

How to cite this URL:
Arya VK. Basics of fluid and blood transfusion therapy in paediatric surgical patients. Indian J Anaesth [serial online] 2012 [cited 2017 Mar 26];56:454-62. Available from: http://www.ijaweb.org/text.asp?2012/56/5/454/103960


   Introduction Top


Perioperative fluid management in paediatric surgical patients has been the focus for considerable interest and debate. [1] It is a medical prescription for which both the volume and composition should be adapted as per patient status, type of operation and the expected events in the perioperative period. The total body water of a newborn is 75-80% and decreases gradually as fat and muscle content increase with age to the adult level of approximately 60%. The extracellular fluid (ECF) fluid represents 45% of body weight in term neonates and 30% by the age of 1 year, compared with 20% in adults. [2] The term infant can compensate more than the preterm infant, but newborns with a large surface-to-weight ratio, higher total water content, limited renal ability to concentrate, greater insensible water loss from thin skin and high blood flow all can become clinically dehydrated in a very short period of time. [3] A meticulous fluid management is required in paediatric patients because of an extremely limited margin for error.


   Crystalloids: The '4/2/1' Rule Top


Holliday and Segar in 1957 first presented a practical method to prescribe IV fluids based on the estimated metabolic requirements for patients at bed rest. [4] The calorie expenditure calculated was 100 kcal/kg for infants weighing 3-10 kg, 1000 kcal +50 kcal/kg for each kilogram over 10 kg but <20 kg for children ranging from 10 to 20 kg, and 1500 kcal +20 kcal/kg for each kilogram over 20 kg for children 20 kg and above. Under normal conditions, 1 ml of water is required to metabolise 1 kcal, taking into account insensible water losses across the skin and respiratory tract, and urinary water loss. Therefore, in the awake child, calorie and water consumption are considered equal and the corresponding weight-based rule for hourly water requirement evolved into what is termed the "4 / 2/1 rule" for maintenance fluid therapy in children [Table 1]. [5] In the same study, Holliday and Segar defined daily maintenance electrolyte requirements considering the electrolyte composition of same volume of human milk and cow's milk; they recommended 2 mEq/100 kcal/day of both potassium and chloride and 3 mEq/100 kcal/day of sodium. These electrolyte requirements are theoretically met by the hypotonic maintenance fluid commonly used in hospitalised children by 5% dextrose (D5) with 0.45% normal saline (NS). For many decades, the fluid given to children by paediatricians was one-fourth to one-third strength saline based on this concept. [6] Recent studies have shown that use of hypotonic solutions along with stress-induced increased secretion of antidiuretic hormone (ADH) perioperatively can lead to hyponatraemic encephalopathy, permanent neurological damage and even death in children. [7],[8],[9]
Table 1: Hourly (4/2/1 rule) and daily maintenance fluids according to child's weight

Click here to view



   Preoperative Estimation of Fluid Deficit: Facts and Controversies Top


Historically, the accepted intraoperative practice has been to administer IV fluids to meet maintenance requirements as well as to replace the preoperative deficits and ongoing losses incurred during the surgical procedure. [6] Conventionally, as a result of the fasting state, children are presumed to develop preoperative fluid deficits secondary to continuing insensible losses and urine output. In 1975, Furman et al. proposed calculating the preoperative deficits by multiplying the hourly rate, as per 4 / 2/1 rule method, by the number of hours the patient was nil per oral (NPO). [10] They then suggested replacing half of this volume during the first hour of surgery, followed by the other half over the next 2 h. In 1986, Berry simplified the method of Furman et al. by delivering a bolus of basic salt solution to otherwise healthy children over the first hour of surgery. Berry concluded that children 3 years and younger should receive 25 ml/kg, whereas children 4 years and older should receive 15 ml/kg. [11] These practices were adopted for many years without questioning their utility. However, considerable debate has recently occurred regarding the amount of deficit generated by the NPO status and the existence of "third space losses." [1]

The methods of both Furman et al. and Berry were developed based on the assumption that patients had been NPO for at least 6-8 h. [10],[11] The debate about the significance of preoperative dehydration secondary to NPO status has become less important due to the new fasting guidelines for elective surgery published by the American Society of Anaesthesiologists (ASA), allowing administration of clear liquids up to 2 h before anaesthesia [Table 2]. [12] Despite this, children may still present for surgery having been NPO for more than 2 h or having significant deficits related to their disease process. Whereas there are no data to determine the exact amount of fluid deficit that occurs in normal fasting children, strong evidence suggests that healthy adult patients will maintain normal intravascular volumes despite a prolonged fast. [13]
Table 2: Fasting guidelines for elective surgery

Click here to view


Estimation of degree of preoperative dehydration is based on classical clinical signs [Table 3]. In an acute clinical situation, the weight loss of the child is usually a very good indication of total water loss. The most important sign of normal hydration status is kidney function. [3] Thus, monitoring of urinary output is essential for evaluating and treating any fluid deficit. Correction of 1% of dehydration requires about 10 ml/kg of fluids. [6] Rate of fluid administration depends on seriousness and on rapidity of dehydration. In the dehydrated paediatric patient requiring resuscitation, a bolus of Ringer's lactate (LR) 20 ml/kg should be administered intravenously as soon as possible. This bolus may need to be repeated in cases of more severe dehydration. [6] The ultimate goal of perioperative fluid therapy is to maintain a correct fluid and electrolyte balance and, as a consequence, normal cardiovascular stability. Indeed, dehydration and some medical conditions associated with third space sequestration of fluids (e.g. intestinal occlusion) will in turn affect vascular fluid volume. Restoration of an adequate vascular fluid volume is essential to maintain cardiovascular stability, organ perfusion and adequate tissue oxygenation. Isotonic transfer of fluid from the extracellular compartment to a non-functional interstitial space forms third space volume. Replacement of intravascular volume losses should be performed by administration of normotonic and normo-osmolar solution. Crystalloid solutions such as LR or NS, or even a colloid solution, can be used during the initial resuscitation period. [14]
Table 3: The clinical assessment for degree of dehydration

Click here to view



   Intraoperative Fluid Management Top


Intraoperative fluid therapy is aimed at providing basal metabolic requirements (maintenance fluids), compensating for preoperative deficits and replacing losses from surgical field [Table 4]. [6],[15] Third space losses refers to the sequestration of fluid to a non-functional extracellular space that is beyond osmotic equilibrium with the vascular space. These losses in paediatrics may vary from 1 ml/kg/h for a minor surgical procedure to as much as 15-20 ml/kg/h for major abdominal procedures, or even up to 50 ml/kg/h for surgery of necrotising enterocolitis in premature infants. [14] The younger the child, the greater is the relative proportion of losses because of the large ECF volume in young infants compared with older children and adults. Third space losses should be replaced with crystalloids (NS or LR). Large amounts of NS are responsible for hyperchloraemic metabolic acidosis, whereas this does not occur after LR administration. [15] However, a recent review of predominantly adult literature concludes that a classic "third space" does not exist. [16] Several studies using multiple blood samples and steady-state tracer kinetics revealed that the functional fluid space is either unchanged or expanded rather than contracted after surgery. [17],[18],[19] Substantial amounts of fluid accumulate in the interstitial space secondary to factors including volume overload with crystalloid infusions and iatrogenic deterioration of the vascular barrier. [16] There is little evidence regarding this in paediatric patients and it is possible that our traditional practice of liberal isotonic fluid delivery in major paediatric surgeries may have adverse implications. [14] Individualised goal-directed fluid management using only the amount of crystalloid and/or colloid necessary to optimise flow-related variables such as stroke volume can alter the incidence of postoperative complications such as it might reduce the amount of tissue oedema previously thought to generate a third space and improve recovery from surgery. [20],[21] However, perioperative studies in paediatric patients using the oesophageal Doppler, pulse contour analysis, or mixed venous oxygen saturation to guide and determine optimum fluids are lacking.
Table 4: Guidelines for fluid administration of balanced salt solution in children according to the age and to the severity of tissue trauma

Click here to view



   Perioperative Dextrose: Rationale for Avoiding Both Hypoglycaemia and Hyperglycaemias Top


Hypoglycaemia as well as hyperglycaemia, depending on the severity, can have devastating effects in paediatric patients. Low blood glucose invokes a stress response and alters cerebral blood flow and metabolism. Permanent neurodevelopmental impairment can result if hypoglycaemia goes unrecognised and untreated. [22] Studies have further demonstrated that cerebral injury is caused not only by severe prolonged hypoglycaemia (blood glucose level <45 mg/dl or 2.6 mmol/l), but also by mild hypoglycaemia combined with mild hypoxia or ischaemia. [23] The incidence of preoperative hypoglycaemia has been shown to be between 0% and 2.5%, and is usually associated with fast durations from 8 to 19 h, well beyond the current ASA recommended guidelines. [12] Hyperglycaemia has also been recognised as detrimental for the nervous system, especially in the setting of an ischaemic or hypoxic event due to the anaerobic metabolism of excess glucose causing an accumulation of lactate, a decrease in intracellular pH, and subsequently severely compromised cellular function that may result in cell death. [24] In addition, hyperglycaemia can induce an osmotic diuresis that may lead to dehydration and electrolyte abnormalities in the paediatric population. [25]

At present, there is a growing consensus to selectively administer intraoperative dextrose only in those children at greatest risk for hypoglycaemia and, in such situations, to consider the use of fluids with lower dextrose concentrations (e.g. 1% or 2.5%) with LR (LRD1 and LR½ D2.5). [25],[26],[27] The highest risk of hypoglycaemia is in neonates, children receiving hyperalimentation, and those with endocrinopathies, in whom monitoring blood glucose levels and adjusting the rate of infusion is also recommended. Glucose infusion at a rate of 120-300 mg/kg/h is sufficient to maintain an acceptable blood glucose level and to prevent lipid mobilisation in hypoglycaemia-prone infants. [28] Routine dextrose administration is no longer advised for otherwise healthy children receiving anaesthesia even in neonatal period. [6],[14],[26]


   Volume Replacement During Infancy: Indications And Choice of Crystalloids and Colloids Top


When determining the particular crystalloid or colloid fluid to administer, the type of fluid deficit (fluid loss or plasma loss) and the effect that these replacement fluids might have on the intravascular volume, coagulation cascade, microcirculation and any possible allergic reactions must be considered. [14],[26] Crystalloids are first administered to treat absolute or relative blood volume deficits observed during surgery in children. Most anaesthesiologists now use either NS or LR for both maintenance and deficit fluid replacement in the operating room setting. [29] Their advantages include low cost, lack of effect on coagulation, no risk of anaphylactic reaction and no risk of transmission of any known or unknown infectious agent. Normally, 15-20 ml/kg/h of LR/NS solution over 15-20 min will re-establish cardiovascular stability. After administration of a total of 30-50 ml/kg of crystalloid solution, the administration of a colloid solution (albumin or synthetic colloid) to maintain intravascular osmotic pressure is indicated. [30] It is recommended that intraoperative fluid in children should have an osmolarity close to the physiological range in order to avoid hyponatraemia, an addition of 1-2.5% glucose in order to avoid hypoglycaemia, if indicated, and should also include metabolic anions (i.e. acetate, lactate or malate) as bicarbonate precursors to prevent hyperchloraemic acidosis especially in neonates. [31],[32] Many a time, neonates and infants present to operating room with various paediatric solution infusions (Isolyte P, D5%+ NS0.45%., etc.) already started by paediatricians. Anaesthesiologist must check the composition of these solutions [Table 5]. Some of these contain potassium and glucose in high concentration and are not suitable for rapid or bolus infusion intraoperatively.
Table 5: Composition of frequently used IV fluids

Click here to view



   Colloids Top


Colloid fluids can be divided into natural protein colloids (albumin) and synthetic colloids (hydroxyethyl starches (HESs), gelatins and dextrans). Albumin occurs naturally and is regarded as the colloid "gold standard." An albumin 5% solution is osmotically equivalent to an equal volume of plasma, whereas a 25% solution causes intravascular volume expansion 3-5 times because of fluid translocation from the interstitial compartment. However, in subjects with increased intravascular permeability (e.g. critically ill, sepsis, trauma and burn), the colloids may actually leak into the interstitial space, thereby worsening oedema. Weak anticoagulation effects of albumin through inhibition of platelet aggregation or heparin-like effects on antithrombin III are clinically insignificant if volume replacement with it is kept below 25% of the patient's blood volume. [33],[34] Recently, its use as plasma expander in neonates and infants is declining. [35],[36] Data supporting the continued use of albumin for general fluid resuscitation in children are lacking, and in children with traumatic brain injury, it may actually be harmful. [37] Its utility may exist in specific subgroups such as neonates and patients undergoing cardiac surgery. [36],[38]

HESs are synthetic colloids prepared with modified natural polysaccharides made resistant to hydrolysis by circulating amylases. As a rule, the solutions with a higher molecular weight and molar substitution ratio have a prolonged volume effect, but also have greater side effects like coagulation abnormalities (interference with the function of von Willebrand factor, factor VIII and platelets), worsen renal function (induce renal tubular cell swelling and create a hyperviscous urine) and pruritus (accumulation and storage of the HES in the skin). [38],[39],[40] Newest-generation HES fluids are designed with low molecular weight and molar substitution ratios to minimise side effects, as well as a high C2:C6 hydroxyethylation ratio to prolong the duration of action (4-6 h). One potential side effect of HES reported is a decrease in the anion gap as well as an increase in the chloride concentration. A low anion gap caused by HES infusion could mask a high anion gap acidosis signifying acute renal failure (ARF) or sepsis during paediatric surgery. [41] Moderate doses of HES (130 / 0.42 / 6:1) for perioperative plasma volume replacement seem to be safe even in neonates and small infants. Changes in acid-base balance may be decreased when HES is used in an acetate-containing balanced electrolyte solution instead of NS. [42]

Gelatins are polypeptides produced by degradation of bovine collagen and from a haemostatic point of view, they are preferable to HES. [43] However, they also effect coagulation and should be avoided in children with bleeding disorders. Gelatins cause increase in blood volume less than the infused volume because of the rapid but transient passage of gelatins into the interstitial space, rapid glomerular filtration and susceptibility to enzymatic cleavage by proteases. A multicentre study done in preterm infants showed no adverse short-term outcomes related to gelatin use. [44] Some studies have reported concern over risk of developing necrotising enterocolitis in preterm infants and worsening capillary leak syndrome in septic newborns with the use of gelatins. [45],[46]

Dextran is a water-soluble glucose polymer (polysaccharide) synthesised by specific bacteria from sucrose. The current formulations available are 10% dextran-40 and 6% dextran-70. Dextran induces a dose-dependent von Willebrand-type syndrome and enhances fibrinolysis that is worse with the high molecular weight dextrans. Other side effects are ARF in patients with acute ischaemic strokes and anaphylactoid reactions as a result of dextran reactive antibodies. [47],[48] The current suggestion is to limit the use of dextrans to 20 ml/kg/day in children. Patients pre-treated with a hapten inhibition prior to the infusion of a dextran have shown decreased incidence of allergic reactions. [48]

Hypertonic saline

In children with traumatic brain injury, hypertonic saline (4 ml/kg) was shown to increase cerebral perfusion pressure in the 3 days after head trauma, when compared with LR. [49] Side effects include possibility of the development of osmotic demyelination syndrome, rebound increases in intracranial pressure, and ARF from an increase in serum osmolarity. [50] Peterson et al. reported that no child developed ARF after the use of hypertonic saline; however, hyperkalaemia and a non-anion gap metabolic acidosis were the common electrolyte abnormalities associated with its use. Both were not clinically relevant if the serum sodium was kept below 155 mmol/l. [51]


   Postoperative Fluid Therapy Top


If oral intake should be delayed (e.g. after abdominal surgery), fluid therapy should be administered on a peripheral venous access if duration of intravenous infusion is not expected to exceed 5 days or on a central venous access when long-term parenteral nutrition is necessary. Fluid therapy should provide basic metabolic requirements, and compensate for gastrointestinal losses (e.g. gastric suctioning) and additional losses (e.g. fever). Postoperative hyponatraemia is the most frequent electrolyte disorder in the postoperative period. [7],[8] Severe hyponatraemia (<120-125 mmol/l) may result in transient or permanent brain damage. The postoperative hyponatraemia observed in most of the ASA 1 children is due to the administration of hypotonic fluids when capacities of free water elimination are impaired due to increased ADH secretion as a result of hypovolaemia, stress, pain, or traction of dura mater. [52] Postoperative hyponatraemia should be prevented by avoiding hypotonic solutions during surgery and in the early postoperative period. [9],[53]


   Intraoperative Paediatric Blood Transfusion Therapy Top


Paediatric patients have higher oxygen consumption and a higher cardiac output to blood volume ratio than adults. The neonatal myocardium that operates at near maximum level of performance as a baseline may be unable to compensate for a decreased oxygen carrying capacity by increasing cardiac output in the event of falling haemoglobin. The normal term neonate haemoglobin value (range 14-20 gm%) gradually decreases over the first several months of life such that the physiologic nadir for haemoglobin occurs at approximately 2-3 months of age [Table 6]. [54] Term infants with haemoglobin levels <9 gm% and preterm infants with haemoglobin values <7 gm% around this nadir should be investigated for the cause, and if concern over adequate oxygen carrying capacity exists, an elective procedure may be postponed pending evaluation and treatment. Premature infants have higher percentages of foetal haemoglobin (HbF) than their full-term counterparts (97% vs. 70% of total haemoglobin) and decreased erythropoietin production which inhibits them from responding to anaemia appropriately. HbF production diminishes during the first few months of life until only a trace is present at 6 months of age. Red blood cells (RBCs) containing HbF have a shorter life span (90 days vs. 120 days in adult) and high oxygen affinity (P 50 of 19 mmHg vs. 26 mmHg in adult). In clinical terms, younger infants have higher fraction of HbF, and thus lower oxygen delivering capacity. In the presence of congenital heart disease or lung disease, neonates may have a decreased ability to oxygenate blood also. It is for these reasons that haemoglobin levels that are adequate for the older patient may be suboptimal in the younger infant or neonate and the threshold for transfusing RBCs to a neonate should be at a higher haemoglobin trigger than an older child or healthy adult. Maintaining higher haemoglobin levels will increase oxygen carrying capacity, and in the premature infant, may protect from post-anaesthetic apnoea of prematurity. [55]
Table 6: Normal haemoglobin values for full-term and premature infants

Click here to view


Although most of the complications associated with paediatric blood transfusions are similar to those encountered in adults, however, metabolic complications occur more readily and with a greater frequency in children (e.g. hypocalcaemia, hyperkalaemia and hypothermia). Hence, in the operating room, the decision to initiate RBC transfusion should be based upon a constellation of factors such as the rapidity of the blood loss, the presence of impaired oxygenation (pulmonary or cardiac in origin), metabolic consequences, infectious disease transmission risks and the general medical condition of the child. [56] Administration of RBCs to infants less than 4 months of age may be either type specific or O negative, and does not require further cross matching because major haemolytic reactions do not occur. For the first 3-4 months of life, infants are unable to form allo-antibodies to RBC antigens with the exception of exposure to the Rh-D antigen. [57]

Massive blood transfusion and allowable blood loss

Massive blood transfusion is defined as the loss of one or more circulating blood volumes. [58] It is, therefore, important to calculate the patient's estimated blood volume (EBV) and to relate this to the volume of blood products and other fluids administered. The patient's EBV is generally related in part to the patient's age as well as body habitus [Table 7]. In addition, the anaesthesiologist should estimate maximal allowable blood loss (MABL) that may be allowed before the initiation of packed RBC transfusion.
Table 7: Estimated circulating blood volume versus age or weight

Click here to view


MABL = [(starting haematocrit − target haematocrit) ÷ starting haematocrit] × EBV

MABL can be replaced with a balanced salt solution such as LR in a volume of 3:1, or with 5% albumen or hetastarch 1:1. Once the estimated blood loss reaches this target value, then RBC cell transfusion should be initiated. Obviously preterm and term infants, children with cyanotic congenital heart disease, large ventilation/perfusion mismatch, high metabolic demand, and children with respiratory failure may benefit from having the haematocrit maintained at a higher target value. Since the haematocrit in packed RBCs is approximately 70%, each 100 ml of packed RBCs transfused will provide 70 ml of RBCs. Replacement would be made for additional blood loss (say XBL) above the MABL according to the following formula:

Volume of 100% RBCs blood to be transfused = XBL × desired haematocrit (30%)

As the approximate haematocrit in packed RBCs is 70%, the volume of packed RBCs in millilitres to be transfused will be = [XBL × desired haematocrit (suppose 30%)] ÷ 0.70

This can usually be simplified by transfusing approximately 0.5 ml packed RBCs for each millilitre of blood loss beyond the MABL; this will result in a slightly higher haematocrit than the target 30%, but since all of these calculations are estimates, the end result is usually close to the desired value. [58]

While transfusing blood, one should always consider coagulopathy of massive blood transfusion due to dilutional thrombocytopenia and reduction in clotting factors. In general, a patient will lose about 40% of the starting platelet count with the first blood volume lost, another 20% with the second blood volume lost, and so on. Thus, at three blood volumes lost with no platelet replacement, the platelet count would be expected to be reduced by approximately 70% from baseline values. [59] Hence, it is important to have a baseline platelet count when massive blood loss is anticipated since patients who begin with a low platelet count are at risk for pathological bleeding even after only one blood volume loss. The coagulopathy secondary to dilution of clotting factors depends upon the type and volume of transfused blood product. Whole blood contains all clotting factors including fibrinogen at normal values except for the labile factors (V and VIII); even these factors are present in 20-50% of their normal values. Therefore, with transfusion of whole blood, pathological coagulation generally does not occur until three or more blood volumes have been lost. However, such large quantities of whole blood are rarely used; instead the blood loss is replaced with albumen, starch, crystalloid and packed RBCs. With this type of replacement, multiple clotting factor deficiencies should be anticipated once blood loss exceeds one blood volume of the patient. [60]


   Other Practical Tips Top


Beside the volume and composition of fluid administered, here are a few other practical considerations:

  1. Always get rid of air bubbles in the intravenous administration set (risk of paradoxical air embolism via patent cardiac shunts)
  2. Use "flush" syringe to negate dead space when administering intravenous drugs
  3. Warm intravenous fluids where possible
  4. Hidden fluid administration used to dilute antibiotics or analgesics should be taken into account, especially in neonatal anaesthesia where margin for error is miniscule
  5. Always administer calculated volumes accurately using a burette or syringe driver.


 
   References Top

1.Lonnqvist P. Inappropriate perioperative fluid management in children: Time for a solution? Paediatr Anaesth 2007;17:203-5.  Back to cited text no. 1
    
2.Friis-Hansen BJ, Holiday M, Stapleton T, Wallace WM. Total body water in children. Pediatrics 1951;7:321-7.  Back to cited text no. 2
    
3.Holliday MA, Ray PE, Friedman AL. Fluid therapy for children: Facts, fashions and questions. Arch Dis Child 2007;92:546-50.  Back to cited text no. 3
[PUBMED]    
4.Holliday MA, Segar WE. The maintenance need for water in parenteral fluid therapy. Pediatrics 1957;19:823-32.  Back to cited text no. 4
[PUBMED]    
5.Oh TH. Formulas for calculating fluid maintenance requirements. Anesthesiology 1980;53:351.  Back to cited text no. 5
[PUBMED]    
6.Murat I, Dubois M. Perioperative fluid therapy in pediatrics. Pediatr Anesth 2008;18:363-70.  Back to cited text no. 6
    
7.Halberthal M, Halperin ML, Bohn D. Lesson of the week: Acute hyponatraemia in children admitted to hospital: Retrospective analysis of factors contributing to its development and resolution. BMJ 2001;322:780-2.  Back to cited text no. 7
[PUBMED]    
8.Dearlove OR, Ram AD, Natsagdoy S, Humphrey G, Cunliffe M, Potter F. Hyponatraemia after postoperative fluid management in children. Br J Anaesth 2006;97:897-8; author reply 898.  Back to cited text no. 8
    
9.Montañana PA, Modesto i Alapont V, Ocón AP, López PO, LópezPrats JL, Toledo Parreño JD. The use of isotonic fluid as maintenance therapy prevents iatrogenic hyponatremia in pediatrics: A randomized, controlled open study. Pediatr Crit Care Med 2008;9:589-97.  Back to cited text no. 9
    
10.Furman E, Roman DG, Lemmer LA, Jairabet J, Jasinska M, Laver MB. Specific therapy in water, electrolyte and bloodvolume replacement during pediatric surgery. Anesthesiology 1975;42:187-93.  Back to cited text no. 10
    
11.Berry F. Practical aspects of fluid and electrolyte therapy. In: Berry F, editor. Anesthetic management of difficult and routine pediatric patients. New York: Churchill Livingstone; 1986. p. 107-35.  Back to cited text no. 11
    
12.ASA Task Force on preoperative fasting. Practice guidelines for preoperative fasting and the use of pharmacologic agents to reduce the risk of pulmonary aspiration: Application to healthy patients undergoing elective procedures. Anesthesiology 1999;90:896-905.  Back to cited text no. 12
    
13.Jacob M, Chappell D, Conzen P, Finsterer U, Rehm M. Blood volume is normal after preoperative overnight fasting. Acta Anaesthesiol Scand 2008;552:522-9.  Back to cited text no. 13
    
14.Bailey AG, McNaull PP, Jooste E, Tuchman JB. Perioperative crystalloid and colloid fluid management in children: Where are we and how did we get here? Anesth Analg 2010;110:375-90.  Back to cited text no. 14
    
15.O'Malley CM, Frumento RJ, Hardy MA, Benvenisty AI, Brentjens TE, Mercer JS, et al. A randomized, double-blind comparison of lactated Ringer's solution and 0.9% NaCl during renal transplantation. Anesth Analg 2005;100:1518-24.  Back to cited text no. 15
    
16.Chappell D, Jacob M, Hofmann-Kiefer K, Conzen P, Rehm M. A rational approach to perioperative fluid management. Anesthesiology 2008;109:723-40.  Back to cited text no. 16
    
17.Roth E, Lax LC, Maloney JV. Ringer's lactate solution and extracellular fluid volume in the surgical patient: A critical analysis. Ann Surg 1969;169:149-64.  Back to cited text no. 17
    
18.Reid DJ. Intracellular and extracellular fluid volume during surgery. Br J Surg 1968;55:594-6.  Back to cited text no. 18
    
19.Cleland J, Pluth JR, Tauxe WN, Kirklin JW. Blood volume and body fluid compartment changes soon after closed and open intracardiac surgery. J Thorac Cardiovasc Surg 1966;52:698-705.  Back to cited text no. 19
    
20.Wakeling HG, McFall MR, Jenkins CS, Woods WG, Miles WF, Barclay GR, et al. Intraoperative esophageal Doppler guided fluid management shortens postoperative hospital stay after major bowel surgery. Br J Anaesth 2005;95:634-42.  Back to cited text no. 20
    
21.Kehlet H. Goal-directed perioperative fluid management. Why, when and how? Anesthesiology 2009;110:453-5.  Back to cited text no. 21
    
22.Burns CM, Rutherford MA, Boardman JP, Cowan FM. Pattern of cerebral injury and neurodevelopmental outcomes after symptomatic neonatal hypoglycemia. Pediatrics 2008;122:65-74.  Back to cited text no. 22
    
23.Inder T. How low can I go? The impact of hypoglycemia on the immature brain. Pediatrics 2008;122:440-1.  Back to cited text no. 23
    
24.Sieber FE, Traystman RJ. Special issues: Glucose and the brain. Crit Care Med 1992;20:104-14.  Back to cited text no. 24
    
25.Leelanukrom R, Cunliffe M. Intraoperative fluid and glucose management in children. Paediatr Anaesth 2000;10:353-9.  Back to cited text no. 25
    
26.Paut O, Lacroix F. Recent developments in the perioperative fluid management for the paediatric patient. Curr Opin Anaesthesiol 2006;19:268-77.  Back to cited text no. 26
    
27.Welborn L, McGill W, Hannallah R, Nisselson C, Ruttimann U, Hicks J. Perioperative blood glucose concentrations in pediatric outpatients. Anesthesiology 1986;65:543-7.  Back to cited text no. 27
    
28.Nishina K, Mikawa K, Maekawa N, Asano M, Obara H. Effects of exogenous intravenous glucose on plasma glucose and lipid homeostasis in anesthetized infants. Anesthesiology 1995;83:258-63.  Back to cited text no. 28
    
29.Snaith R, Peutrell J, Ellis D. An audit of intravenous fluid prescribing and plasma electrolyte monitoring; a comparison with guidelines from the National Patient Safety Agency. Paediatr Anaesth 2008;18:940-6.  Back to cited text no. 29
    
30.Sumpelmann R, Schurholz T, Marx G, Thorns E, Hausdörfer J. Haemodynamic, acid-base and electrolyte changes during plasma replacement with hydroxyethyl starch or crystalloid solution in young pigs. Paediatr Anaesth 2000;10:173-9.  Back to cited text no. 30
    
31.Sümpelmann R, Becke K, Crean P, Jöhr M, Lönnqvist PA, Strauss JM, et al. German Scientific Working Group for Paediatric Anaesthesia. European consensus statement for intraoperative fluid therapy in children. Eur J Anaesthesiol 2011;28:637-9.  Back to cited text no. 31
    
32.Sümpelmann R, Mader T, Dennhardt N, Witt L, Eich C, Osthaus WA. A novel isotonic balanced electrolyte solution with 1% glucose for intraoperative fluid therapy in neonates: Results of a prospective multicentre observational post-authorisation safety study (PASS). Paediatr Anaesth 2011;21:1114-8.  Back to cited text no. 32
    
33.Jorgensen KA, Stoffersen E. On the inhibitory effect of albumin on platelet aggregation. Thromb Res 1980;17:13-8.  Back to cited text no. 33
    
34.Joorgensen KA, Stoffersen E. Heparin like activity of albumin. Thromb Res 1979;16:569-74.  Back to cited text no. 34
    
35.Soderlind M, Salvignol G, Izard P, Lonnqvist PA. Use of albumin, blood transfusion and intraoperative glucose by APA and ADARPEF members: A postal survey. Paediatr Anaesth 2001;11:685-9.  Back to cited text no. 35
    
36.Tabbers MM, Boluyt N, Offringa M. Implementation of an evidence-based guideline on fluid resuscitation: Lessons learnt for future guidelines. Eur J Pediatr 2010;169:749-58.  Back to cited text no. 36
    
37.Myburgh J, Cooper DJ, Finfer S, Bellomo R, Norton R, Bishop N, et al. SAFE Study Investigators; Australian and New Zealand Intensive Care Society Clinical Trials Group; Australian Red Cross Blood Service; George Institute for International Health. Saline or albumin for fluid resuscitation in patients with traumatic brain injury. N Engl J Med 2007;357:874-84.  Back to cited text no. 37
    
38.Wilkes MM, Navickis RJ, Sibbald WJ. Albumin versus hydroxyethyl starch in cardiopulmonary bypass surgery: Ametaanalysis of postoperative bleeding. Ann Thorac Surg 2001;72:527-33; discussion 534.  Back to cited text no. 38
    
39.Vogt NH, Bothner U, Lerch G, Lindner KH, Georgieff M. Large-dose administration of 6% hydroxyethyl starch 200/0.5 total hip arthroplasty: Plasma homeostasis, hemostasis, and renal function compared to use of 5% human albumin. Anesth Analg 1996;83:262-8.  Back to cited text no. 39
    
40.Morgan PW, Berridge JC. Giving long-persistent starch as volume replacement can cause pruritus after cardiac surgery. Br J Anaesth 2000;85:696-9.  Back to cited text no. 40
    
41.Sumpelmann R, Schurholz T, Marx G, Thorns E, Zander R. Alteration of anion gap during almost total plasma replacement with synthetic colloids in piglets. Intensive Care Med 1999;25:1287-90.  Back to cited text no. 41
    
42.Sümpelmann R, Kretz FJ, Luntzer R, deLeeuw TG, Mixa V, Gäbler R, et al. Hydroxyethyl starch 130 / 0.42 / 6:1 for perioperative plasma volume replacement in 1130 children: Results of an European prospective multicenter observational postauthorization safety study (PASS). Paediatr Anaesth 2012;22:371-8.  Back to cited text no. 42
    
43.deJonge E, Levi M. Effects of different plasma substitutes on blood coagulation: A comparative review. Crit Care Med 2001;29:1261-7.  Back to cited text no. 43
    
44.A randomized trial comparing the effect of prophylactic intravenous fresh frozen plasma, gelatin or glucose on early mortality and morbidity in preterm babies. The Northern Neonatal Nursing Initiative [NNNI] Trial Group. Eur J Pediatr 1996;155:580-8.  Back to cited text no. 44
    
45.Osborn DA, Evans N. Early volume expansion for prevention of morbidity and mortality in very preterm infants. Cochrane Database Syst Rev 2001;CD002055.  Back to cited text no. 45
    
46.Abrahamov D, Erez E, Tamariz M, Dagan O, Pearl E, Abrahamov Y, et al. Plasma vascular endothelial growth factor level is a predictor of the severity of postoperative capillary leak syndrome in neonates undergoing cardiopulmonary bypass. Pediatr Surg Int 2002;18:54-9.  Back to cited text no. 46
    
47.Biesenbach G, Kaiser W, Zazgornik J. Incidence of acute oligoanuric renal failure in dextran 40 treated patients with acute ischemic stroke stage III or IV. Ren Fail 1997;19:69-75.  Back to cited text no. 47
    
48.Laxenaire MC, Charpentier C, Feldman L. [Anaphylactoid reactions to colloid plasma substitutes: Incidence, risk factors, mechanisms. A French multicenter prospective study]. Ann Fr Anesth Reanim 1994;13:301-10.  Back to cited text no. 48
    
49.Simma B, Burger R, Falk M, Sacher P, Fanconi S. A prospective, randomized, and controlled study of fluid management in children with severe head injury: Lactated Ringer's solution versus hypertonic saline. Crit Care Med 1998;26:1265-70.  Back to cited text no. 49
    
50.Huang PP, Stucky FS, Dimick AR, Treat RC, Bessey PQ, Rue LW. Hypertonic sodium resuscitation is associated with renal failure and death. Ann Surg 1995;221:543-54; discussion 554-7.  Back to cited text no. 50
    
51.Peterson B, Khanna S, Fisher B, Marshall L. Prolonged hypernatremia controls elevated intracranial pressure in head injured pediatric patients. Crit Care Med 2000;28:1136-43.  Back to cited text no. 51
    
52.Arieff AI. Postoperative hyponatraemic encephalopathy following elective surgery in children. Paediatr Anaesth 1998;8:1-4.  Back to cited text no. 52
    
53.Moritz ML, Ayus JC. Prevention of hospital-acquired hyponatremia: A case for using isotonic saline. Pediatrics 2003;111:227-30.  Back to cited text no. 53
    
54.Brown MS. Physiologic anemia of infancy: Normal red-cell values and physiology of neonatal erythropoiesis. In: Stockman JA III, Pochedly C, editors. Developmental and Neonatal Hematology. New York: Raven Press; 1988. P. 249-74.  Back to cited text no. 54
    
55.Cote×CJ, Zaslavsky A, Downes JJ, Kurth CD, Welborn LG, Warner LO, et al. Postoperative apnea in former preterm infants after inguinal herniorrhaphy. A combined analysis. Anesthesiology 1995;82:809-22.  Back to cited text no. 55
    
56.Barcelona SL, Thompson AA, Cote CJ. Intraoperative pediatric blood transfusion therapy: A review of common issues. Part I: Hematologic and physiologic differences from adults; metabolic and infectious risks. Paediatr Anaesth 2005;15:716-26.  Back to cited text no. 56
    
57.Floss AM, Strauss RG, Goeken N, Knox L. Multiple transfusions fail to provoke antibodies against blood cell antigens in human infants. Transfusion 1986;26:419-22.  Back to cited text no. 57
    
58.Barcelona SL, Thompson AA, Cote CJ. Intraoperative pediatric blood transfusion therapy: A review of common issues. Part II: Transfusion therapy, special considerations, and reduction of allogenic blood transfusions. Paediatr Anaesth 2005;15:814-30.  Back to cited text no. 58
    
59.Cote× CJ, Liu LM, Szyfelbein SK, Goudsouzian NG, Daniels AL. Changes in serial platelet counts following massive blood transfusion in pediatric patients. Anesthesiology 1985;62:197-201.  Back to cited text no. 59
    
60.Haas T, Mauch J, Weiss M, Schmugge M. Management of dilutional coagulopathy during pediatric major surgery.Transfus Med Hemother 2012;39:114-19.  Back to cited text no. 60
    



 
 
    Tables

  [Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6], [Table 7]


This article has been cited by
1 Hemostasis in Pediatric Surgery
Soham Roy,Jo-Lawrence Bigcas,Laura Vandelaar
Otolaryngologic Clinics of North America. 2016; 49(3): 601
[Pubmed] | [DOI]
2 Comparison of Surgical Pleth Index–guided Analgesia with Conventional Analgesia Practices in Children
Ji Hye Park,Byung Gun Lim,Heezoo Kim,Il Ok Lee,Myoung Hoon Kong,Nan Suk Kim
Anesthesiology. 2015; 122(6): 1280
[Pubmed] | [DOI]



 

Top
 
  Search
 
    Similar in PUBMED
   Search Pubmed for
   Search in Google Scholar for
 Related articles
    Access Statistics
    Email Alert *
    Add to My List *
* Registration required (free)  

 
  In this article
    Abstract
   Introduction
    Preoperative Est...
    Intraoperative F...
    Perioperative De...
    Volume Replaceme...
   Colloids
    Postoperative Fl...
    Intraoperative P...
   Other Practical Tips
    Crystalloids: Th...
    References
    Article Tables

 Article Access Statistics
    Viewed13196    
    Printed137    
    Emailed7    
    PDF Downloaded3942    
    Comments [Add]    
    Cited by others 2    

Recommend this journal