A simple meningococcal sepsis prognostic score: focusing on the human animal

A simple cheap meningococcal sepsis prognostic score based on readily available, rapid, objective laboratory base excess and platelet count was developed and validated retrospectively. This BEP score should facilitate sepsis clinical trials, allowing study of the relevant human animal model.

A new meningococcal sepsis prognostic score is reported in a previous edition of Critical Care [1]. Meningococcal sepsis in the pediatric intensive care unit (PICU) is often rapidly progressive with signifi cant morbidity and mortality. When complicated by purpura fulminans, children may have permanent sequelae, including limb amputations. Process of care improvements, including early resuscitation and antibiotics, have been associated with improved survival [2]. Nevertheless, despite promising animal experiments leading to many human sepsis trials, no drug has been shown to improve outcomes [3].
Many have examined prediction of outcome from meningococcal sepsis, resulting in variably complex scores. To facilitate risk stratifi cation for clinical trials of novel therapies, and to identify patients at high risk for deterioration, a score based on simple, objective, readily available rapid and low cost variables would be ideal. Alves and colleagues [1] describe such a score. Using databases of prospectively collected data from ongoing studies of children referred to PICU at fi ve European centers from 1996 to 2011, data from children with a clinical diagnosis of meningococcal sepsis were retrospectively reviewed. Th e BEP score ('base excess platelets' from the fi rst recorded laboratory sample) was developed from 309 patients with complete information, validated on the remaining 623 patients, and replicated on 134 retrospective patients referred to the Children's Acute Transport Service. Th e remarkably simple BEP score predicted death, with area under the receiver operating characteristic curve (AUC) of 0.86 (95% confi dence interval 0.80 to 0.91), better than Glasgow Meningococcal Septicaemia Prognostic Score, and similar to Rotterdam and PRISM scores. Th e replication dataset AUC was 0.96 (95% confi dence interval 0.90 to 0.99).
Th e strengths of BEP are its simplicity, based on a relatively large sample with overall mortality 51/623 (8.2%). Th ere are some limitations. First, the score is not accurate enough to apply to individual patient decisions, with a validation set AUC of 0.86, sensitivity 72%, specifi city 82%, and positive predictive value 23% (Table S1 in [1]). Second, the score should be prospectively validated in an independent large cohort referred to PICU over a shorter time period (this study occurred over 15 years) and not necessarily enrolled in other clinical studies (which may have introduced selection bias in this study). Th ird, it is unclear whether BEP performs better than clinical variables often used to include patients in sepsis trials, such as ventilation and volume-refractory septic shock treated with inotropes. Finally, whether BEP predicts morbidity, particularly limb amputations, is unknown.
Th e authors claim that 'previous clinical trials of specifi c novel therapies in meningococcal sepsis, targeting pathways of infl ammation and coagulation such as recombinant bactericidal/permeability inducing protein (rBPI) and activated protein C (rhAPC), have failed for reasons which are not clear'; however, a main reason 'may have been a failure to select a study population in whom neither death nor survival was inevitable' [1]. We hypothesize that this is unlikely the reason for the disappointing results of these (and all other) sepsis clinical trials. In the rBPI trial, the placebo mortality was 9.9%, with severe amputations in 7.4% [4]. In the rhAPC trial, all patients had respiratory and cardiovascular organ dysfunction, a median of 4 (interquartile range 3 to 4) organ failures, and placebo mortality 17.1% [5]. It is more likely that the reason trials have failed is because animal models in sepsis do not model human sepsis, despite some superfi cial phenotypic similarities [6,7]. Animals, including humans, are com plex biological systems; their nonlinear dynamics and responses are extremely sensitive to initial conditions [6][7][8][9]. Despite superfi cial physiologic and genetic similarity between species, it is simply not to be expected that responses to similar perturbations or disease will be relevantly similar [6][7][8][9]. Th is has been the experience in biomedical animal research in general, not just sepsis research [6,7,10]. Of interest, the genomic responses to diff erent acute infl ammatory stresses, including trauma, burns, endotoxemia, sepsis, ARDS, and infection, are highly similar in humans; however, these responses are not reproduced in mouse models [11]. Among genes changed signifi cantly in humans in these diseases, 'the murine orthologs are close to random in matching their human counterparts' [11]. Lethal toxicity to bacterial lipopolysaccharide varies almost 10,000-fold in diff erent species [12]. Of 120 essential human genes with mouse orthologs, 17 (22.5%) were nonessential in mice, suggest ing that 'it is possible that mouse models of a large number of human diseases will not yield suffi ciently accurate information' [13]. Th e ENCODE project suggests that over 80% of the genome is functionally important for gene expression; it is likely there are 'critical sequence changes in the newly identifi ed regulatory elements that drive functional diff erences between humans and other species' [14]. Th is may explain 'the specifi c organ biology [from lineagespecifi c gene expression switches] of various mammals' [15].

Conclusion
With further validation, the BEP score may be useful to stratify enrolment in human meningococcal sepsis trials. More research into human sepsis is required, and, we believe, not yet more sepsis research using the failed animal modeling paradigm.
Abbreviations AUC, area under the receiver operating characteristic curve; BEP, base excess platelets; PICU, pediatric intensive care unit.