Target blood pressure in sepsis: between a rock and a hard place

The optimal target blood pressure in septic shock is still unknown. Therefore, in a long-term, resuscitated porcine model of fecal peritonitis-induced septic shock, Corrêa and colleagues tested whether different titrations of mean arterial pressure (50 to 60 and 75 to 85 mm Hg) would produce different effects on sepsis-related organ dysfunction. The higher blood pressure window was associated with increased needs for fluid resuscitation and norepinephrine support. However, titrating the lower blood pressure range coincided with an increased incidence of acute kidney injury. In contrast, neither the inflammatory response nor tissue mitochondrial activity showed any difference. This research paper in a clinically relevant model elegantly demonstrates that any standard resuscitation strategy may be a double-edged sword with respect to various therapeutic endpoints. Furthermore, it adds an important piece to the puzzle of the complex pathophysiology of sepsis-related acute kidney injury.

died within the fi rst 30 hours, 7 out of 8 animals survived in each treatment group at 48 hours after induction of sepsis. Th e high-MAP group had higher requirements for fl uid and, parti cu larly, norepinephrine, whereas low-MAP animals pre sented with a higher incidence of acute kidney injury (AKI).
Although MAP is a cornerstone of the hemodynamic management of patients with septic shock, its optimal target value is still unknown. Clearly, prolonged phases of hypotension (MAP of less than 60 mm Hg) are associated with increased mortality [2,3], and early goal-directed therapy-related improved survival coincided with a higher MAP [4]. Nevertheless, an upper threshold has not been identifi ed: increasing MAP to greater than 70 mm Hg at the expense of a higher vasopressor load coincided with increased mortality in a retrospective analysis [5]. However, in various pros pective trials, no signs of excessive vasoconstriction were detected, although MAP values were frequently higher than recommended targets [6,7]. Moreover, the pros pective studies investigating the eff ects of MAP incre ments (from 60 to 90 mm Hg) on various outcomes, including renal function, studied only small numbers of already hemodynamically stabilized patients (10 and 28 patients) over short periods of time (105 minutes and 4 hours per MAP level) and reported no changes in kidney function [8,9].
What do we learn from the study by Corrêa and colleagues? First of all, the authors have to be commended for using an experimental design that nicely fulfi lls the criteria of a clinically relevant model, namely (a) lacking resuscitation led to 100% mortality, (b) treatment began 12 hours after the initial aggression, and (c) included antibiotics, protocol-guided mechanical ventilation, fl uid resuscitation, and vasopressor treatment. Clearly, the higher incidence of AKI in the low-MAP group agrees well with observational data in patients: Dünser and colleagues [3] observed a direct relation between plasma creatinine and the 'hourly blood pressure time integral' , and Badin and colleagues [10] reported decreased AKI at 72 hours with a MAP of at least 72 mm Hg, when septic shock patients already had AKI at 6 hours after inclusion in the study. Hence, although long-term renal eff ects of

Abstract
The optimal target blood pressure in septic shock is still unknown. Therefore, in a long-term, resuscitated porcine model of fecal peritonitis-induced septic shock, Corrêa and colleagues tested whether diff erent titrations of mean arterial pressure (50 to 60 and 75 to 85 mm Hg) would produce diff erent eff ects on sepsisrelated organ dysfunction. The higher blood pressure window was associated with increased needs for fl uid resuscitation and norepinephrine support. However, titrating the lower blood pressure range coincided with an increased incidence of acute kidney injury. In contrast, neither the infl ammatory response nor tissue mitochondrial activity showed any diff erence. This research paper in a clinically relevant model elegantly demonstrates that any standard resuscitation strategy may be a double-edged sword with respect to various therapeutic endpoints. Furthermore, it adds an important piece to the puzzle of the complex pathophysiology of sepsis-related acute kidney injury.

© 2010 BioMed Central Ltd
Target blood pressure in sepsis: between a rock and a hard place higher MAP remain unknown, the low MAP-related kidney dysfunction is an important fi nding, particularly given the strong association between AKI and poor outcome [11].
Nevertheless, the study cannot defi nitely answer the question of the optimal target MAP in septic shock. As in most experimental models, the pigs studied were young and 'healthy' before the experiment, which is not the case for adult patients admitted for septic shock in intensive care units. Consequently, the optimal MAP derived from such experiments may diff er markedly from the level needed in old patients with comorbidities. Clinical settings require a more subtle balance, especially in patients with arterial hypertension or chronic kidney disease or both. It is well known that, in non-septic conditions, hypertension-related histological changes in the small arteries of the kidney alter renal autoregulation. Th e renal autoregulatory threshold (that is, the threshold MAP, below which renal blood fl ow becomes directly related to perfusion pressure) is higher in spontaneously hypertensive rats than in healthy controls [12]. Moreover, during sepsis, little is known about the renal autoregulatory threshold, and, fi nally, we must keep in mind that autoregulatory thresholds may diff er between organs [13]. Any benefi cial eff ect of high MAP on the kidney may coincide with harmful eff ects in other organs with lower autoregulatory threshold (for example, the brain and heart).
What is the 'take home message' on the relation between blood pressure and sepsis-induced kidney dysfunction? Clearly, Corrêa and colleagues demonstrated that low-MAP levels were associated with a higher incidence of AKI, even under conditions of a sustained increase in cardiac output. However, the link between MAP level and kidney function is probably more complex than usually considered. On the one hand, Di Giantomasso and colleagues [14] reported that renal failure occurred in hypotensive ewes with sepsis despite increased kidney blood fl ow. On the other hand, Benes and colleagues [15] elegantly showed that AKI developed in septic pigs despite well-maintained hyperdynamic and normotensive hemodynamics and that this was most likely because of systemic infl ammation and oxidative stress. Of note, in that study, MAP was close to the values of the high-MAP group in the present study.
Furthermore, although this study was not designed to answer this question, Corrêa and colleagues raised the issue of the specifi c eff ect of norepinephrine. Th e consequences of the systemic eff ect of norepinephrine (that is, maintaining an elevated MAP level) cannot be distinguished from its specifi c intrarenal eff ect (that is, similar vasoconstrictive action on both aff erent and eff erent arterioles) [16]. Moreover, this study does not address the question of whether higher MAP level (or higher norepinephrine doses) could also decrease histo logical injury severity or only improve renal function.
Finally, even in the low-MAP group, severity of shock was moderate (lactate levels did not increase in comparison with baseline, and the arterial base excess decreased to approximately 1 to 2 mmol/L), and only 1 out of 8 animals developed AKI stage 2 (increase in blood creatinine between 2 and 3 times). Unfortunately, as the authors do not report plasma protein or total hemoglobin content, any dilution eff ect of the higher amount of fl uid resuscitation on creatinine concentra tions could not be assessed in the high-MAP group. Th e lacking hemoglobin data leave the reader with another open question: according to the protocol, dobutamine was infused if the mixed venous oxygen saturation (SvO 2 ) was less than 50%. Strikingly, baseline SvO 2 values were only 48% and 50% in the two treatment arms, respectively, despite a stroke volume within the normal range. Th us, a contribution of pre-existing anemia cannot be excluded.
In conclusion, this elegant study adds an important brick in the wall. It nicely demonstrates that early hemodynamic intervention on MAP may attenuate the occurrence of AKI solely by increasing renal perfusion pressure. Th e direct translation to clinical practice is diffi cult because of the limitations acknowledged by the authors. In patients with septic shock, the SEPSISPAM trial (ClinicalTrial.gov NCT01149278), which has completed recruitment, will most likely answer some of the questions raised by the study by Corrêa and colleagues.

Competing interests
PA is the principal investigator of a completed, investigator-led, multicenter randomized controlled trial assessing the target blood pressure in sepsis (SEPSISPAM trial), but he declares that this is a non-fi nancial competing interest. The other authors declare that they have no competing interests.