Hypertonic saline-dextran resuscitation of acute canine bile-induced pancreatitis

In this study, we examined the effects of hypertonic saline-dextran resuscitation (2,400 mOsm of sodium chloride, 6 percent dextran 70) on cardiopulmonary function and extravascular lung water in acute canine pancreatitis. Acute pancreatitis was induced in 21 dogs by injecting 0.5 ml/kg of autologous bile into the pancreatic duct. In 10 dogs, resuscitation was begun with a 4 ml/kg bolus of hypertonic saline-dextran solution; 11 dogs received no bolus. Lactated Ringer's solution was infused in all dogs to maintain mean arterial pressure and cardiac output at baseline values. Pulmonary hypertension accompanied by a significant increase in pulmonary vascular resistance and a decrease in lung blood flow occurred in those dogs resuscitated with lactated Ringer's solution alone. By contrast, dogs in the hypertonic saline-dextran group maintained pulmonary artery pressure and pulmonary vascular resistance at baseline values while nutritive blood flow to the lung decreased progressively. Our data suggest that hypertonic saline-dextran resuscitation effectively restores cardiac function while it significantly reduces fluid requirements, as well as the pulmonary hypertension and pulmonary edema that frequently accompany lactated Ringer's resuscitation of acute pancreatitis.     

Beneficial effects of a hypertonic solution for resuscitation in the presence of acute hemorrhage

Crystalloid solutions such as Ringer's lactate have become the standard for initial volume replacement after hemorrhage. Although the relative merits of blood, colloid, and crystalloid have been extensively studied, little attention has been directed toward determining the optimal composition of the crystalloid solution. Based on the beneficial properties of hypertonic lactated saline solution in burn resuscitation, we have extended its use to acute hemorrhage. Using an awake canine model analogous to the clinical situation, we compared hypertonic lactated saline solution with Ringer's lactate solution for resuscitation in the presence of acute blood loss. The hypertonic lactated saline solution group required less fluid to restore and maintain cardiac output and blood pressure while maintaining better urine output. Although the Ringer's lactate solution group had increased shunt function indicative of pulmonary dysfunction, the shunt function in the hypertonic lactated saline solution group did not differ from that in the control group. Serum sodium and osmolality values were higher in the hypertonic lactated saline solution group, but at no time did they approach toxic levels.     

Effectiveness of hypertonic saline-dextran 70 for initial fluid resuscitation of major burns.

Small-volume resuscitation (4 ml/kg) with hypertonic saline-dextran (HSD) has been shown effective in hemorrhagic shock. In the present study the effectiveness of an initial 4 ml/kg bolus infusion of HSD on cardiovascular function and fluid resuscitation requirements after a major burn injury was evaluated in anesthetized sheep following a 40% BSA scald burn. One hour after injury resuscitation was initiated by a rapid intravenous bolus infusion (4 ml/kg) of either hypertonic saline-dextran (7.5% NaCl in 6% dextran 70) (HSD) or the same volume of normal (isotonic) saline (NS). Lactated Ringer's was later infused as needed to maintain cardiac output at 90% of baseline. HSD rapidly and effectively restored cardiac output and mean arterial pressure significantly better than the same volume of NS. Hemodynamic improvement by HSD was short lived, and need for further fluid therapy was only marginally delayed (HSD 38 +/- 8 min, NS 20 +/- 3 min; p = 0.06) (mean +/- SEM). The total requirements for fluid therapy during the first 6 hr postburn were not reduced by the initial HSD bolus (HSD 3,145 +/- 605 ml, NS 2,905 +/- 495 ml; n.s.), nor was skin edema formation reduced. We conclude that in anesthetized sheep HSD resuscitation was only transiently effective in treating burn shock. This may be attributed to the sustained increase in vascular permeability and continued plasma leak following thermal injury.     

Effects of hypertonic saline versus lactated Ringer's solution on cerebral oxygen transport during resuscitation from hemorrhagic shock

Hypertonic saline successfully restores systemic hemodynamics in dogs and humans with severe hemorrhagic shock and, in contrast to lactated Ringer's solution, does not increase intracranial pressure (ICP). This study compares cerebral oxygen delivery in 12 dogs subjected to hemorrhagic shock by the rapid removal of blood (mean arterial pressure of 40 mm Hg maintained for 30 minutes), and then resuscitated with lactated Ringer's solution (six dogs) or 7.5% saline solution (six dogs) to restore systolic arterial pressure. Both solutions effectively restored systemic hemodynamic stability, increasing cardiac output and systolic blood pressure while decreasing mean and diastolic arterial pressure and systemic vascular resistance. The ICP was significantly lower after resuscitation in the hypertonic saline group (p less than 0.05), but cerebral blood flow, which had decreased during shock, was not restored by either fluid, and cerebral oxygen transport fell further secondary to a hemodilutional reduction of hemoglobin. Although hypertonic saline may improve systemic hemodynamics and maintain a low ICP during resuscitation, it fails, as does Ringer's solution, to restore cerebral oxygen transport to prehemorrhagic shock levels.     

Small-volume hypertonic saline dextran resuscitation from canine endotoxin shock.

This study evaluated resuscitation of endotoxin shock with 7.5% hypertonic saline dextran (HSD 2400 mOsm) by measuring hemodynamic and regional blood flow responses. Endotoxin challenge (1 mg/kg) in adult dogs caused a significant decrease in mean arterial blood pressure (MABP), cardiac output (CO), left ventricular +/- dP/dt max, and regional blood flow (radioactive microspheres). Cardiocirculatory dysfunction and acid-base derangements persisted throughout the experimental period in untreated endotoxin shock (group 1, n = 10). In contrast both regimens of fluid resuscitation (group 2, n = 11: bolus of 4 mL/kg HSD followed by a constant infusion of lactated Ringer's [LR] to maintain MABP and CO at baseline values; group 3, n = 10; LR alone given as described for group 2) improved regional perfusion and corrected acid-base disturbances similarly in all dogs. Hypertonic saline dextran enhanced all indices of cardiac contraction and relaxation more than LR alone. The total volume of LR required to maintain MABP and CO at baseline values was less in the HSD group (59.2 +/- 6.8 mL/kg) than in the LR alone group (158 +/- 16 mL/kg, p = 0.01). The net fluid gain (infused volume minus urine output and normalized for kilogram body weight) was five times greater in the LR (24.8 +/- 6.2 mL/kg) than in the HSD group (4.6 +/- 1.2 mL/kg, p = 0.01). Lung water was similar in all dogs, regardless of the regimen of fluid resuscitation. Hypertonic saline dextran effectively resuscitates endotoxin shock in this canine model.     

Effect of a hypertonic lactated Ringer's solution on intracranial pressure and cerebral water content in a model of traumatic brain injury

There has recently been an increased interest in the use of hypertonic solutions for fluid resuscitation of trauma victims. In this study, we examined the acute cerebral effects of a hypertonic lactated Ringer's solution (measured osmolality = 469 mOsm/kg) in an animal model of traumatic brain injury. Following the production of a cerebral cryogenic lesion, eight New Zealand white rabbits were randomized to undergo hemodilution with either lactated Ringer's (measured osmolality = 254 mOsm/kg) or hypertonic lactated Ringer's. Over the course of the experiment the lactated Ringer's group required significantly more fluid than the hypertonic group to maintain stable central venous and mean arterial pressure (245 +/- 5 ml vs. 132 +/- 20 ml; p less than 0.0001). Osmolality increased in the hypertonic group by 13.5 +/- 3.3 mOsm/kg whereas it decreased in the lactated Ringer's group by 5.5 +/- 2.6 mOsm/kg. Intracranial pressure increased in both groups over the course of the experiment but the increase in pressure was greater in the lactated Ringer's group than the hypertonic group (9.5 +/- 2.4 mm Hg vs. 1.7 +/- 1.5 mm Hg; p less than 0.001). Brain water content was significantly increased in the region of the lesion as assayed by both the wet/dry weight method and cortical specific gravity determinations, but there was no difference between the two treatment groups. Water content of the nonlesioned hemisphere was significantly less in the hypertonic group. This study suggests that hypertonic saline solutions may be useful for the resuscitation of hypovolemic patients with localized brain injury.     

Inhibition of CD18-dependent neutrophil adherence reduces organ injury after hemorrhagic shock in primates

Neutrophil adherence or aggregation may be important in the development of organ injury after hemorrhagic shock. Monoclonal antibody (MAb) 60.3 prevents both adherence and aggregation. Therefore we investigated MAb 60.3 treatment in prevention of organ injury after hemorrhagic shock in rhesus monkeys (Macaca mulatta). We performed esophagogastroscopy and placed catheters to measure cardiac output, mean arterial pressure, arterial blood gases, and urine output. Blood was removed to decrease CO to 30% of baseline for 90 minutes. Just before resuscitation, MAb 60.3 (2 mg/kg) or saline solution (control) was administered intravenously. Monitoring and fluid resuscitation continued for 24 hours, with lactated Ringer's solution given as a maintenance infusion (4 ml/kg/hr) plus additional lactated Ringer's solution to maintain CO at preshock levels. Esophagogastroscopy was repeated 24 hours after shock. There were two deaths in the control group at about 72 hours and none in the MAb 60.3 group. MAb 60.3-treated animals required less fluid (9.6 +/- 8.8 ml/kg vs 263.8 +/- 225.7 ml/kg), gained less weight (0.08 +/- 0.11 kg vs 0.70 +/- 0.37 kg), and maintained a higher hematocrit level (35.0% +/- 1.0% vs 26.9% +/- 4.9%). All five control animals had gastritis; MAb 60.3-treated animals had none (p less than 0.05; Fisher's exact test). Inhibition of neutrophil adherence or aggregation with MAb 60.3 at the time of resuscitation reduces fluid requirements and gastric injury in monkeys after hemorrhagic shock.     

Blood loss after fluid resuscitation with isotonic or hypertonic saline for the initial treatment of uncontrolled hemorrhage induced by spleen rupture

BACKGROUND: It has been suggested that fluid resuscitation for the prehospital management of hypotensive trauma victims increases bleeding. In a model of uncontrolled hemorrhage induced by complete splenic laceration with a hilar vascular injury, we hypothesized that small-volume hypertonic saline or large-volume lactated Ringer's solution may provide sustained hemodynamic benefits despite promoting increases in intra-abdominal bleeding. METHODS: Forty anesthetized, spontaneously breathing dogs (18 +/- 1 kg) underwent laparotomy. A suture line was placed around the spleen to produce a splenic rupture with hilar vascular injury by pulling the exteriorized lines after incision closure. Intra-abdominal blood loss was measured directly, immediately after the animal was killed. Dogs were randomly assigned to four groups (n = 10 per group): Untreated controls were killed 20 (CT20) or 40 (CT40) minutes after splenic rupture to measure blood loss directly. Treatment groups received (20 minutes after spleen rupture) lactated Ringer's (LR), 33 mL/kg over 15 minutes, or 7.5% NaCl/6% dextran 70 (HSD), 4 mL/kg over 4 minutes. Blood loss was measured 40 minutes after spleen rupture. RESULTS: Mean arterial pressure dropped from an average value of 103 +/- 3 mm Hg to 67 +/- 5 mm Hg during the first 20 minutes and was partially restored afterward in all groups, with no significant differences between them. No resuscitation was associated with low cardiac output, whereas HSD restored and LR overshot baseline cardiac output. Intra-abdominal blood loss was 30 +/- 4, 38 +/- 4, 43 +/- 5, and 42 +/- 5 mL/kg for groups CT20, CT40, HSD, and LR, respectively, with no statistical significance between groups. CONCLUSION: No-fluid resuscitation in uncontrolled hemorrhage from splenic rupture resulted in a low-flow state, whereas resuscitation with small volumes of HSD or large volumes of LR produced hemodynamic benefits without significant increases in bleeding.     

Hypertonic saline resuscitation in a porcine model of severe hemorrhagic shock

The purpose of this study was to investigate the effect of 7.5% hypertonic saline solution (HTS) as the initial solution in resuscitation of a pig in shock. Twenty-two animals were bled 50% of their blood volume over 30 minutes and maintained in shock for 60 minutes. The 14 survivors were divided into two groups. The first group was given 20 mL/kg of lactated Ringer's solution (LR) over a ten-minute period, while the second group was given 10 mL/kg of HTS. Both groups were then given LR at 2 mL/kg/min until the mean arterial pressure reached 80 mm Hg. The HTS group achieved a more rapid rise in mean arterial pressure over the first ten minutes of resuscitation. During this period, the cardiac index increased significantly more in the HTS group when compared with the LR group. All animals in the HTS group developed an adequate urine output. Only two animals in the LR group developed an adequate urine output. Hypertonic saline solution markedly improved survival, and there were significant improvements in hemodynamics. This was accomplished with smaller volumes of resuscitation fluid and may prove useful under conditions where intravascular access is limited.     

Ethanol impairs cardiocirculatory function in treated canine hemorrhagic shock

This study examined the hypothesis that ethanol-induced alterations in cardiac function and regional blood flow impair recovery from shock after resuscitation. Blood ethanol levels 45 minutes after ethanol (3 gm/kg) was administered intrajejunally were 276 +/- 30 mg/100 ml (N = 14 dogs). Twelve dogs received saline solution and served as control animals. Elevated blood ethanol levels increased the rate of left ventricular pressure rise (+763 +/- 80 mm Hg X sec) and coronary blood flow (+0.77 +/- 0.18 ml X min X gm), decreased respiration, and caused a significant metabolic acidosis (arterial pH, 7.25 +/- 0.02; arterial lactate, 1.5 +/- 0.07 mmol/L). Two hours of hemorrhagic shock impaired cardiovascular function and regional blood flow to a similar extent in all dogs. Volume replacement (shed blood and lactated Ringer's solution, 50 ml/kg) transiently improved cardiac performance in the ethanol group. Two hours after volume replacement, a lower cardiac output, stroke volume, stroke work, myocardial oxygen efficiency, and persistent acidosis occurred in the intoxicated dogs (p less than 0.05) despite adequate coronary perfusion. Myocardial sensitivity to acidosis after shock may account for the reduced cardiac function in the ethanol group. However, it is possible that shock aggravated ethanol-induced pancreatic ischemia and contributed to impaired cardiocirculatory function in postinfusion shock.     

Hypertonic saline as a resuscitation solution in hemorrhagic shock: effects on extravascular lung water and cardiopulmonary function

To determine the effect of resuscitation with hypertonic saline on extravascular lung water, seven adult sheep were endotracheally intubated; mean arterial pressure (MAP), pulmonary artery pressure (PAP), pulmonary capillary wedge pressure (PCWP), and central venous pressure (CVP) were monitored. A 5-French, thermistor-tipped catheter was used to measure extravascular lung water (EVLW). Colloid oncotic pressure (COP), serum electrolytes and osmolality, and arterial and mixed venous blood gas tensions were measured. The COP-PCWP gradient and the shunt fraction (Qsp/Qt) were calculated. After baseline measurements, the animals were bled to an MAP of 50 mm Hg (blood volume removed, 16.2 +/- 3.6 ml/kg), which was maintained for 30 min, measurements then being repeated. Three percent sodium chloride solution was infused at 500 ml/15 min until two of three parameters--cardiac output (CO), PCWP, or MAP--were restored to baseline values. Data were recorded again and then 60 min later. No shed blood was reinfused. The total volume of hypertonic saline infused was 39 +/- 19 ml/kg. Pulmonary artery pressure did not vary throughout the study. PCWP, MAP, and CO were significantly lower than baseline (P less than 0.05) 30 min after bleeding but all except MAP returned to baseline with resuscitation. Throughout the study, EVLW did not vary despite a COP-PCWP gradient less than 4 mm Hg. Serum sodium levels and serum osmolality were significantly above baseline values after resuscitation. In this animal model of hemorrhagic shock, infusion of hypertonic saline effected resuscitation without compromising cardiopulmonary function or increasing EVLW.     

Impact of vasopressin on hemodynamic and metabolic function in the decompensatory phase of hemorrhagic shock

OBJECTIVES: To explore how the potent vasoconstrictive features of vasopressin impact the rate of cardiovascular collapse and metabolic derangements associated with prolonged hemorrhagic shock. DESIGN: A prospective randomized trial. SETTING: University hospital-based animal laboratory. PARTICIPANTS: Sixteen swine. INTERVENTIONS: Swine were bled in an isobaric fashion to achieve a linear decrease in the mean arterial blood pressure to 40 mmHg. The mean arterial blood pressure was then maintained at 40 mmHg until the onset of cardiovascular decompensation, defined as the need to reinfuse shed blood to maintain the blood pressure at 40 mmHg. Once at the onset of cardiovascular decompensation, animals were randomly assigned to 2 resuscitation groups: the crystalloid group received lactated Ringer's solution and the vasopressin group received lactated Ringer's solution and arginine vasopressin. Resuscitation consisted of infusing lactated Ringer's solution with and without vasopressin (0.05 U/kg/min) to maintain a blood pressure of 70 mmHg for 60 minutes. MEASUREMENTS AND MAIN RESULTS: The rate of crystalloid infusion was compared between groups using an unpaired 2-tailed t test. Metabolic and hemodynamic parameters between groups over time were compared with a repeated measures analysis of variance. Vasopressin decreased the rate of crystalloid infusion during resuscitation by 50%. During resuscitation, the cardiac index in the crystalloid group was restored to near baseline levels and was decreased to near half of baseline levels in the vasopressin group. Animals in the vasopressin group developed a lactic acidemia, but animals in the crystalloid group revealed no change from baseline in the arterial pH and a slight decrease in the plasma lactate. CONCLUSIONS: Administration of vasopressin used as an adjunct to maintain blood pressure in the decompensatory phase of hemorrhagic shock slows cardiovascular collapse, but has an adverse effect on metabolic and hemodynamic function. Further investigation is warranted to clarify the role of vasopressin in the delayed management of severe hemorrhagic shock.     

A comparison of several hypertonic solutions for resuscitation of bled sheep

Small volumes (4 ml/kg) of 2400 mOsm NaCl restore cardiac output and mean arterial pressure to 80% of baseline after hemorrhage (65% of blood volume) in unanesthetized sheep. An equal volume of normal saline is less effective. To identify an optimal hypertonic solution, we screened six 2400 mOsm solutions in 18 randomized experiments in 8 sheep: NaCl, NaHCO3, NaCl/sodium acetate, NaCl/mannitol, NaCl/6% Dextran 70, and glucose. Cardiovascular function, as determined by cardiac output and mean arterial pressure, was restored best with NaCl, NaCl/NaAc, and NaCl/Dex. These three solutions were then evaluated using 18 sheep in 36 experiments. Following a 1-hr baseline period, the sheep were bled to a mean arterial pressure of 50 mm Hg for 2 hr. One of the solutions was then given in a volume of 4 ml/kg over 2 min and the sheep were monitored for 3 hr. Within 3 min of the infusion, cardiac output increased to greater than 100% of baseline for all three solutions. The NaCl-Dex solution sustained a significantly higher cardiac output over the 3-hr observation period than the other solutions. Plasma volume increased for all solutions following infusion. NaCl-Dex maintained plasma volume significantly better than the other solutions. As a further control, an isotonic solution of 6% Dextran 70 in normal saline was studied. It was not as effective as the hypertonic NaCl-Dex in maintaining cardiac output, mean arterial pressure, or plasma volume. Osmolality increased 10% (309 to 326 mOsm/kg H2O), plasma [NA] increased 7% (151 to 161 meq/liter), and plasma [K] decreased from 3.9 to 2.6 meq/liter following the hypertonic infusions. The sheep appeared to tolerate these electrolyte changes well. We conclude that a single bolus infusion of 2400 mOsm NaCl with 6% Dextran 70 best resuscitates sheep that have been subjected to a moderate degree of hemorrhagic shock compared to several other solutions. Its beneficial effects are caused in part by a sustained reestablishment of plasma volume. More studies are needed to document the safety of dextran in the clinical setting of hemorrhagic shock. Small volumes of hypertonic solutions may be valuable in the initial fluid resuscitation of patients in hemorrhagic shock.     

Hemodynamic Response of Modified Fluid Gelatin Compared with Lactated Ringer's Solution for Volume Expansion in Emergency Resuscitation of Hypovolemic Shock Patients: Preliminary Report of a Prospective, Randomized Trial

The objective of this study was to compare the cardiac and hemodynamic responses to a rapid infusion of 1000 ml of modified fluid gelatin (group A) or 1000 ml of lactated Ringer's solution (group B) in emergency room patients suffering from shock. This prospective, randomized, open, noncrossover study was performed at a medical center university hospital in a surgical resuscitation room in the emergency department. The subjects were 34 patients with either hypovolemic or neurogenic shock who were admitted to the emergency room. A resuscitation protocol according to Advanced Trauma Life Support (ATLS) with an additional central venous line or Swan-Ganz catheters for hemodynamic monitoring was used. Physical parameters and hemodynamic variables were measured at baseline and 15 minutes, 30 minutes, and 1 hour after the infusion of each fluid. In both groups the mean arterial blood pressure (MAP), systolic and diastolic pressure, central venous pressure (CVP), and pulmonary artery occlusion pressure (PAOP) increased significantly. The CVP and PAOP increased significantly more in the modified fluid gelatin resuscitation group. In patients with traumatic or neurogenic shock due to acute volume deficiency, there was significantly better hemodynamic improvement, judged by CVP and PAOP measurements using the modified fluid gelatin for volume replacement than with lactated Ringer's solution during the first hour of resuscitation.     

Evaluation of an intraosseous infusion device for the resuscitation of hypovolemic shock.

An intraosseous infusion device designed for the prehospital administration of hypertonic saline-dextran solutions was evaluated by resuscitating hemorrhaged conscious sheep. Eight animals underwent 2 hours of hemorrhagic hypotension (50 mm Hg, bled volume = 43 +/- 7 ml/kg). This was followed by the intraosseous infusion of 200 ml (4-5 ml/kg) of 7.5% NaCl-6% dextran 70 into the bone marrow of the sternum. Results were compared to seven control animals (bled volume = 31 +/- 6 ml/kg) resuscitated through a central venous catheter. Despite the small volumes infused, mean arterial blood pressure and cardiac output were rapidly normalized in both groups by 10 minutes post resuscitation (p less than 0.01). Plasma sodium concentration increased an average of 12 mEq/L and plasma volume was rapidly expanded regardless of route. The metabolic acidosis of hemorrhagic shock was rapidly corrected, pulmonary pressures remained normal, and hypoxemia did not occur after intraosseous resuscitation. The device provided safe and rapid vascular access via the sternal bone marrow space. The use of intraosseous infusion of hypertonic saline dextran solutions via the sternal bone marrow may allow prehospital rescuers to consistently incorporate fluid replacement therapy into 'scoop and run' policies by avoiding the time delays associated with failures in IV access.     

The dynamics of vascular volume and fluid shifts of lactated Ringer's solution and hypertonic-saline-dextran solutions infused in normovolemic sheep

Infusions of hyperosmotic-hyperoncotic solutions such as hypertonic saline dextran (HSD) are used in Europe for resuscitation of traumatic shock and perioperative volume support as an adjunct to conventional isotonic crystalloids. Whereas plasma volume expansion of HSD has been measured at single time points after the intravascular volume expansion, the detailed time course of fluid shifts during and after infusions have not been reported. We compared the time course of volume expansion during and after 30-min infusions of 4 mL/kg HSD and 25 mL/kg lactated Ringer's solution (LR) in normovolemic conscious splenectomized sheep. Peak plasma volume (Evans blue and hemoglobin dilution) expansion was similar for HSD (7.8 +/- 0.9 mL/kg) and the larger sixfold volume of LR (7.2 +/- 0.5 mL/kg). However, 30 min after the 30-min infusion (T60), plasma expansion remained larger after HSD (5.1 +/- 0.9 mL/kg) than after LR (1.7 +/- 0.6 mL/kg). Both solutions caused an equivalent diuresis. Intravascular volume expansion efficiency (VEE), defined as milliliter plasma expansion/milliliter fluid infused at 0 (T30), 30 (T60), and 60 (T90) min after infusion ended was 1.8, 1.3, and 0.8, respectively for HSD, whereas LR provided a VEE of only 0.27, 0.07, and 0.07. The relative expansion efficiency of HSD versus LR, calculated as the ratio (VEE(HSD)/VEE(LR)), was 7-fold that of LR at the end of infusion T30, and 20-fold at T60, but decreased to 9-fold by T120. Intravascular volume dynamic studies of different volume expanders in animals and patients may provide anesthesiologists with a new tool for monitoring the effectiveness of fluid therapy. IMPLICATIONS: Hypertonic saline dextran (HSD) is a new plasma expander recently approved for clinical use in Europe. We compared the plasma volume expansion of HSD versus lactated Ringers (LR) in normovolemic sheep. After a 30 min infusion, HSD was 7 times as effective at expanding volume as an equal volume of LR, but for the next 90 minutes the relative effectiveness of HSD increased to 10-20 times.     

Lactated Ringer's is superior to normal saline in the resuscitation of uncontrolled hemorrhagic shock

BACKGROUND: Normal saline (NS) and lactated Ringer's solution (LR) continue to be used interchangeably for the resuscitation of hemorrhagic shock in some institutions. We hypothesized that, aside from hyperchloremic acidosis, NS resuscitation would be similar to that of LR in a swine model of uncontrolled hemorrhage. METHODS: Twenty swine weighing a mean of 37 kg underwent invasive line placement, midline celiotomy, and splenectomy. After a 15-minute stabilization period, we recorded a baseline mean arterial pressure (MAP) and created a grade V liver injury. The animals bled freely for 30 minutes after which we measured blood loss. We blindly randomized the swine to receive NS (10 animals) versus LR (10 animals) to achieve and maintain the baseline MAP for 90 minutes postinjury. Laboratory values were obtained at baseline and upon completion of the 2-hour study period. RESULTS: Initial blood loss was 25 mL/kg in the NS group and 22 mL/kg in the LR group (p = 0.54). Animals required 256.3 +/- 145.4 mL/kg of fluid in the NS group as compared with 125.7 +/- 67.3 mL/kg in the LR group (p = 0.04). The urine output was higher in the NS group (46.6 +/- 39.5 mL/kg versus 18.9 +/- 12.9 mL/kg, p = 0.04). Upon study completion, the NS group had a significant hyperchloremia (119 +/- 1.9 mEq/L versus 105 +/- 2.9 mEq/L, p < 0.01) with acidosis (7.28 +/- 0.12 versus 7.45 +/- 0.06, p < 0.01) in comparison to the LR group. In addition, resuscitation with NS resulted in significantly lower fibrinogen levels (99 +/- 21 mg/dL versus 123 +/- 20 mg/dL, p = 0.02). The serum lactate was 4.7 +/- 2.2 in the LR group and 1.7 +/- 1.7 in the NS swine (p < 0.01) at the end of the study. CONCLUSIONS: Resuscitation of uncontrolled hemorrhagic shock with NS requires significantly greater volume and is associated with greater urine output, hyperchloremic acidosis, and dilutional coagulopathy as compared with LR. Resuscitation with LR results in an elevation of the lactate level that is not associated with acidosis. Lactated Ringer's solution is superior to NS for the resuscitation of uncontrolled hemorrhagic shock in swine.     

Methylene blue enhancement of resuscitation after refractory hemorrhagic shock

BACKGROUND: Methylene blue has been used to treat hypovolemic states. This study evaluated prehospital resuscitation after refractory hemorrhagic shock with a combination of methylene blue and limited-volume lactated Ringer's solution. METHODS: After blood loss to a mean arterial pressure of 50 mm Hg in canines, refractory hemorrhagic shock was defined as minimal hemodynamic response to phenylephrine. Differential protocols included no treatment (control), methylene blue bolus, limited-volume lactated Ringer's solution, and combined methylene blue/lactated Ringer's solution therapies. Hemodynamic parameters were collected at baseline, during shock, during refractory hemorrhagic shock, and 30, 60, 90, and 120 minutes after treatment. Radiolabeled microspheres were used to measure end-organ perfusion and oxygen delivery. RESULTS: Methylene blue/lactated Ringer's resuscitation improved prehospital survival (p < 0.05), mean arterial pressure and cardiac output (p < 0.05), vital end-organ blood flow and oxygen delivery (p < 0.05), and decreased serum lactate levels (p < 0.05), as compared with the methylene blue and lactated Ringer's single therapies. CONCLUSIONS: Resuscitation after refractory hemorrhagic shock using a combination of methylene blue and limited-volume lactated Ringer's solution improves prehospital survival and hemodynamic stability and reduces ischemic damage in an acute setting. This form of therapy has been proved useful as a temporizing measure for resuscitation after refractory hemorrhagic shock in a canine model and warrants further study for its application to the hemorrhagic trauma patient.     

Survival after hypertonic saline resuscitation from hemorrhage

There has been recent increased interest in hypertonic saline resuscitation from shock and hemorrhage. This study was performed to evaluate the survival effects of hypertonic saline resuscitation. Fifty male Sprague-Dawley rats of average weight of 325 grams were anesthetized with halothane. Animals were subjected to blood loss of 21 ml/kg over 5 minutes. Intravenous infusion was started 10 minutes after hemorrhage with either lactated Ringer's injection (42 ml/kg) or three per cent NaCl (10.64 ml/kg) chosen randomly. These doses provided equal amounts of sodium. At the end of fluid infusion, blood samples were obtained for electrolyte determination. Rats were observed 3 days for survival. Survival was significantly lower in the three per cent NaCl group compared with the lactated Ringer's group. It is probable that worsened outcome with three per cent NaCl was associated with intracellular dehydration.