Effect of acute hemodilution on intestinal perfusion and intramucosal pH after shock

In vivo performance of a visible wavelength optical sensor for monitoring intestinal perfusion and oxygenation

Traumatic injury resulting in hemorrhage is a prevalent cause of death worldwide. The current standard of care for trauma patients is to restore hemostasis by controlling bleeding and administering intravenous volume resuscitation. Adequate resuscitation to restore tissue blood flow and oxygenation is critical within the first hours following admission to assess severity and avoid complications. However, current clinical methods for guiding resuscitation are not sensitive or specific enough to adequately understand the patient condition. To better address the shortcomings of the current methods, an approach to monitor intestinal perfusion and oxygenation using a multiwavelength (470, 560, and 630 nm) optical sensor has been developed based on photoplethysmography and reflectance spectroscopy. Specifically, two sensors were developed using three wavelengths to measure relative changes in the small intestine. Using vessel occlusion, systemic changes in oxygenation input, and induction of hemorrhagic shock, the capabilities and sensitivity of the sensor were explored in vivo. Pulsatile and nonpulsatile components of the red, blue, and green wavelength signals were analyzed for all three protocols (occlusion, systemic oxygenation changes, and shock) and were shown to differentiate perfusion and oxygenation changes in the jejunum. The blue and green signals produced better correlation to perfusion changes during occlusion and shock, while the red and blue signals, using a new correlation algorithm, produced better data for assessing changes in oxygenation induced both systemically and locally during shock. The conventional modulation ratio method was found to be an ineffective measure of oxygenation in the intestine due to noise and an algorithm was developed based on the Pearson correlation coefficient. The method utilized the difference in phase between two different wavelength signals to assess oxygen content. A combination of measures from the three wavelengths provided verification of oxygenation and perfusion states, and showed promise for the development of a clinical monitor.

In-silico and in-vitro investigation of a photonic monitor for intestinal perfusion and oxygenation

The quantification of visceral organ oxygenation after trauma-related systemic hypovolemia and shock is critical to enable effective resuscitation. In this work, a photoplethysmography-based (PPG) sensor was specifically designed for probing the perfusion and oxygenation condition of intestinal tissue with the ultimate goal to monitor patients post trauma to guide resuscitation. Through Monte Carlo modeling, suitable optofluidic phantoms were determined, the wavelength and separation distance for the sensor was optimized, and sensor performance for the quantification of tissue perfusion and oxygenation was tested on the in-vitro phantom. In particular, the Monte Carlo simulated both a standard block three-layer model and a more realistic model including villi. Measurements were collected on the designed three layer optofluidic phantom and the results taken with the small form factor PPG device showed a marked improvement when using shorter visible wavelengths over the more conventional longer visible wavelengths. Overall, in this work a Monte Carlo model was developed, an optofluidic phantom was built, and a small form factor PPG sensor was developed and characterized using the phantom for perfusion and oxygenation over the visible wavelength range. The results show promise that this small form factor PPG sensor could be used as a future guide to shock-related resuscitation.

Sustained Gastric Mucosal Acidosis After Hemorrhage in Spite of Rapid Hemodynamic Restoration With Blood or Hypertonic/Hyperoncotic Solution

Splanchnic hypoperfusion has been implicated as the motor of multiple organ dysfunction. Hypertonic saline has shown to benefit microcirculatory blood flow. In hemorrhaged animals, we tested the hypothesis that small-volume 3% NaCl/10% dextran 40 (3%HSD) promotes global and regional improvements, including gastric mucosal acidosis reversal. Seventeen dogs (18.8 +/- 1.2 kg) were bled (20 mL/min) to a mean arterial pressure of 40-45 mm Hg, which was maintained at these levels for 15 min. They were randomly assigned to two groups: Blood (n = 9), total shed blood retransfused at 40 mL/min; or a 4-min bolus injection of 3%HSD (n = 8), in a volume equivalent to 25% of total shed blood. All animals were followed for 30 min thereafter. Gastric mucosal PCO2 (gas tonometry), portal vein PCO2, superior mesenteric artery blood flow (SMA, ultrasonic flowprobes), and systemic and regional O2-derived variables were evaluated throughout the protocol. Hemorrhage induced significant reductions of arterial pressure, cardiac output, and SMA blood flow, while portal-arterial and gastric-arterial PCO2 gradients increased. Total shed blood transfusion, as well as 3%HSD bolus injection, promptly restored all parameters, except for the increased gastric-arterial PCO2 gradient. We conclude that persistent gastric mucosal acidosis cannot be adequately predicted by global and splanchnic O2 derived variables in following hemorrhage and resuscitation with total shed blood transfusion or small-volume hypertonic-hyperoncotic solution.

Hydroxyethyl starch is superior to lactated Ringer as a replacement fluid in a pig model of acute normovolaemic haemodilution

BACKGROUND

Tissue tolerance to oxygen privation during acute normovolaemic haemodilution with different fluids remains unclear. We tested the hypothesis that hydroxyethyl starch (HES) is superior to lactated Ringer's solution in pigs for preserving tissue perfusion during acute normovolaemic haemodilution.

METHODS

Twenty-four animals were randomized into control, lactated Ringer's solution and HES groups. All groups, except the control, underwent acute normovolaemic haemodilution. Haemodynamics, oxygen parameter indices, global anaerobic metabolic markers, echocardiographic parameters, gastric tonometry and serum osmolarity were monitored at baseline, immediately after (0 min) and 60 and 120 min after the end of haemodilution. Myocardial, liver, stomach and intestine samples were collected for further evaluation.

RESULTS

Cardiac and oxygen parameter index responses to acute normovolaemic haemodilution were comparable. However, the increment in cardiac index, stroke volume index, and left ventricular stroke work index were more sustained in the starch group. In the lactated Ringer's group, gastric pH decreased significantly and was accompanied by a significant increase in lactate. Myocardial ultrastructure was better preserved in the starch group. The other tissue samples presented no change.

CONCLUSIONS

In this model of ANH, the starch group had a superior haemodynamic response. Minor loss of myocardial cellular integrity and preserved gastric pHi reinforce these findings.

Low hematocrit impairs gastric mucosal CO2 removal during experimental severe normovolemic hemodilution

OBJECTIVE

The net effects of acute normovolemic hemodilution with different hemoglobin levels on splanchnic perfusion have not been elucidated. The hypothesis that during moderate and severe normovolemic hemodilution, systemic and splanchnic hemodynamic parameters, oxygen-derived variables, and biochemical markers of anaerobic metabolism do not reflect the adequacy of gastric mucosa, was tested in this study.

METHODS

Twenty one anesthetized mongrel dogs (16 +/- 1 kg) were randomized to controls (CT, n = 7, no hemodilution), moderate hemodilution (hematocrit 2 5% +/- 3%, n = 7) or severe hemodilution (severe hemodilution, hematocrit 15% +/- 3%, n = 7), through an isovolemic exchange of whole blood and 6% hydroxyethyl starch, at a 20 mL/min rate, to the target hematocrit. The animals were followed for 120 min after hemodilution. Cardiac output (CO, L/min), portal vein blood flow (PVF, mL/min), portal vein-arterial and gastric mucosa-arterial CO2 gradients (PV-artCO2 and PCO2 gap, mm Hg, respectively) were measured throughout the experiment.

RESULTS

Exchange blood volumes were 33.9 +/- 3.3 and 61.5 +/- 5.8 mL/kg for moderate hemodilution and severe hemodilution, respectively. Arterial pressure and systemic and regional lactate levels remained stable in all groups. There were initial increases in cardiac output and portal vein blood flow in both moderate hemodilution and severe hemodilution; systemic and regional oxygen consumption remained stable largely due to increases in oxygen extraction rate. There was a significant increase in the PCO2-gap value only in severe hemodilution animals.

CONCLUSION

Global and regional hemodynamic stability were maintained after moderate and severe hemodilution. However, a very low hematocrit induced gastric mucosal acidosis, suggesting that gastric mucosal CO2 monitoring may be useful during major surgery or following trauma.

Hypertonic saline resuscitation improves intestinal microcirculation in a rat model of hemorrhagic shock

BACKGROUND

Conventional resuscitation (CR) from hemorrhagic shock (HS) often restores and maintains hemodynamics but fails to restore intestinal perfusion. Post-CR intestinal ischemia has been implicated in the initiation of a gut-derived exaggerated systemic inflammatory response and in the progressive organ failure following HS. We propose that intestinal ischemia can be prevented with hypertonic saline resuscitation (HTSR).

METHODS

Anesthetized male Sprague-Dawley rats (200 to 215 g) were hemorrhaged to 50% of mean arterial pressure (MAP) for 60 minutes and randomly assigned to 1 of the resuscitation groups (n = 7 each): Group I: sham operation and no HS; Group II: HS + CR with the return of the shed blood + 2 volumes of normal saline (NS); Group III: HS + return of the shed blood + hypertonic saline (HTS); (7.5 % NaCl, 4 ml/kg); Group IV: HS + HTS, then return of the shed blood after 60 minutes; Group V: HS + HTS, then 1 volume of NS after 60 minutes. Microvascular diameters of inflow (A1) and proximal and distal premucosal arterioles (A3) in terminal ileum and flow in A1 were measured using in vivo videomicroscopy and optical Doppler velocimetry. Hematocrit, plasma osmolarity, and electrolytes were measured in Groups II and III.

RESULTS

HS caused a selective vasoconstriction in A1 arterioles that was not seen in the premucosal arterioles. CR restored and maintained MAP and caused generalized, progressive vasoconstriction at all intestinal arteriolar levels that is associated with hypoperfusion. HTSR failed to restore or maintain MAP or intestinal A1 arteriolar blood flow until the shed blood was returned. However, HTSR prevented the post-resuscitation, premucosal vasoconstriction and produced an insidious selective vasodilation in the A3 arterioles, which was most significant with early blood return (Group III). This selective arteriolar vasoactivity was associated with a significant improvement of endothelial cell function. Plasma hyperosmolality and hypernatremia persisted during the entire 2 hours post-resuscitation with HTS.

CONCLUSIONS

Small-volume HTSR can be used as a resuscitation regimen at the trauma scene and for selective clinical conditions where hypotensive resuscitation is indicated. HTSR improves intestinal perfusion by selective vasodilation of the precapillary arterioles even at MAP close to shock levels.

[Initial evaluation of systemic and regional pCO2 gradients as markers of mesenteric hypoperfusion]

BACKGROUND

Mesenteric ischemia is a life-threatening emergency with a mortality rates still ranging between 60% and 100%.

AIM

To evaluate the systemic and regional pCO2 gradients changes induced by mesenteric ischemia-reperfusion injury. In addition, we sought to determine if other systemic marker of splanchnic hypoperfusion could detect the initial changes in intestinal mucosal microcirculation after superior mesenteric artery occlusion.

METHODS

Seven pentobarbital anesthetized mongrel dogs (20.6 +/- 1.1 kg) were subjected to superior mesenteric artery occlusion for 45 minutes, and followed for an additional 120 minutes. Systemic hemodynamic was evaluated through a Swan-Ganz and arterial catheters, while gastrointestinal tract perfusion by superior mesenteric vein and jejunal serosal blood flows (ultrasonic flowprobe). Intestinal oxygen delivery, extraction and consumption (DO2intest, ERO2intest and VO2intest, respectively), intramucosal pH (gas tonometry), and mesenteric-arterial and mucosal arterial pCO2 gradients (D(vm-a)pCO2 and D(t-a)pCO2, respectively) were calculated.

RESULTS

Superior mesenteric artery occlusion was not associated with significant changes on systemic hemodynamics parameters. A significant increase of D(vm-a)pCO2 (1.7 +/- 0.5 to 5.7 +/- 1.8 mm Hg) and D(t-a)pCO2 (8.2 +/- 4.8 to 48.7 +/- 4.6 mm Hg) were detected. During the reperfusion period a significant decrease on DO2intest (67.7 +/- 9.9 to 38.8 +/- 5.3 mL/min) and a compensatory increase on ERO2intest from 5.0 +/- 1.1% to 12.4 +/- 2.7% was observed.

CONCLUSION

We conclude that gas tonometry can detect the mesenteric blood flow disturbances sooner than other analyzed parameters. Additionally, we demonstrated that changes on systemic or regional pCO2 gradients are not able to detect the magnitude of intestinal mucosal blood flow reduction after mesenteric ischemia-reperfusion injury.

Oxygen consumption, pCO2 gradients and regional blood flow distribution in an alternative model of intestinal autotransplantation

BACKGROUND

Postoperative complications after intestinal transplantation can be attributed to hypothermic storage and reperfusion injury. Our objective was to evaluate, in an alternative model of intestinal autotransplantation, the initial effects of isolated intestinal hypothermic perfusion (at 4 degrees C, IHP) on mucosal and serosal blood flow distribution and correlate these findings with other systemic and regional markers of mesenteric ischemia. In addition, we sought to obtain evidence that intestinal pCO2 measurement can be a useful method for monitoring graft perfusion and early histological changes after small bowel transplantation.

MATERIALS AND METHODS

Eight dogs (23.3+/-1.1 kg) were submitted to a in situ IHP for 30 min, followed by a 180-min reperfusion period. Cardiac output, mesenteric vein, and intestinal serosal blood flows (SMVBF and SBF, ultrasonic flowprobe); intestinal mucosal-arterial pCO2 gradient (Dt-apCO2, tonometry); and O2-derived variables were evaluated.

RESULTS

IHP induced a reduction in SMVBF (579+/-53 to 321+/-10 mL/min) and SBF, (44.7+/-3.2 to 29.1+/-5.3 mL/min), and an increase in Dt-apCO2 (2+/-2.8 to 20.5+/-4.5 mm Hg). No alterations on systemic metabolic or O2-derived variables were observed. The increase of the Dt-apCO2 correlated with the grade of mucosal injury.

CONCLUSION

IHP induces a proportional reduction on blood flow in all layers of the intestine, and none of the systemic markers of splanchnic ischemia predict the intestinal blood flow disturbances during the early phase of intestinal transplantation. In addition, intestinal pCO2 measurement seems to be a useful way for monitoring graft perfusion and histological changes after hypothermic ischemia and reperfusion.

Intramucosal-Arterial Pco2 Gradient Does Not Reflect Intestinal Dysoxia in Anemic Hypoxia

BACKGROUND

An increase in intramucosal-arterial Pco2 gradient (DeltaPco2) might be caused by tissue hypoxia or by diminished blood flow. Our hypothesis was that DeltaPco2 should not be altered in anemic hypoxia with preserved blood flow.

METHODS

In 18 anesthetized, mechanically ventilated sheep, oxygen transport was stepwise reduced by hemorrhage (hypovolemia, n = 9) or by hemorrhage and simultaneous dextran infusion (hemodilution, n = 9).

RESULTS

Hypovolemia and hemodilution produced comparable decreases in systemic and intestinal oxygen transport and uptake. However, mixed venoarterial and mesenteric venoarterial Pco2 gradients and DeltaPco2 were significantly higher in hypovolemia than in hemodilution (25 +/- 5 vs. 10 +/- 2 mm Hg; 21 +/- 6 vs. 10 +/- 5 mm Hg; and 41 +/- 18 vs. 14 +/- 9 mm Hg, respectively; p < 0.01).

CONCLUSION

DeltaPco2 did not reflect intestinal dysoxia during Vo2/Do2 dependency attributable to hemodilution. Blood flow seems to be the main determinant of DeltaPco2.