Sepsis is a significant cause of morbidity and mortality in neonates and adults, and the mortality rate from sepsis doubles in patients who develop cardiovascular dysfunction and septic shock 1. Annual combined deaths from sepsis of patients of all ages equal the number of deaths from myocardial infarction 2, and 7% of all childhood deaths result from sepsis alone 3. Sepsis is especially devastating in the neonatal population, as it is responsible for 45% of late deaths in the neonatal intensive care unit, making it one of the leading causes of death for hospitalized infants 4.

The incidence of sepsis is age-related, and is highest in infants (5.3/1,000) and the elderly over 65 years of age (26.2/1,000) 2. Although the incidence is highest in the elderly, both the intensive care unit admission rates (58.5% versus 40%) and the average costs ($54,300 versus $14,600) are higher in infants 2. Twenty-one percent of very low birthweight infants will develop at least one episode of culture-proven bloodstream sepsis after the first 3 days of life 5, and the septic episode will probably be more severe than in adults 3. In very low birthweight infants, sepsis increases the hospital stay by 30% and increases mortality 2.5 times 5.

Unlike adults, little is known about the cardiovascular response to sepsis in the neonate. Baseline neonatal cardiovascular function has not been well defined, and studies of inotrope use to treat hypotension in neonates have failed to show any improvement in short-term or long-term clinical outcomes 6. In addition, recent research has demonstrated that the clinical presentation, mechanisms, inflammatory response, response to treatment and outcome of neonatal sepsis vary not only from that of adults, but vary among neonates based on gestational age. The goal of the present article is to review key pathophysiologic aspects of sepsis-related cardiovascular dysfunction, with an emphasis on defining known differences between adult and neonatal populations. The potential impact of these differences on therapeutic strategies is also discussed.

Underlying the differences in neonatal and adult sepsis are alterations in the developing immune system. These differences include innate and acquired immunity, immune cell numbers and function, cytokine elaboration and the inflammatory response.

The influence of perinatal factors on the development and response to sepsis is unique to newborns. Challenges to the maternal immune system before and during pregnancy have been associated with modulation of the neonatal immune response, and this modulation occurs in both humoral and cell-mediated immunity 7. Although proinflammatory cytokines such as TNFα, IL-1β and IL-6 have not been shown to cross the human term placenta 8, certain immunoglobulins and lymphoid cells can cross the placenta and change fetal and postnatal immune development 7. The transplacental transfer of immunoglobulins, however, does not occur until 32 weeks gestation 9, leading to a relative immune deficiency in extremely premature infants. Labor of any duration may be immunologically beneficial to the neonate, with improved neutrophil survival and lipopolysaccharide (LPS) responsiveness 10. Labor itself is a mild pro-inflammatory state and has been associated with delayed neutrophil apoptosis, fetal leukocytosis and elevation of the systemic neutrophil count when compared with cesarean section without labor 10. In addition, respiratory burst, CD11b/CD18 and IL-8 receptors have all been shown to be increased after vaginal delivery in comparison with cesarean section 11.

Sepsis is clinically characterized by systemic inflammation, cardiovascular dysfunction, an inability of oxygen delivery to meet oxygen demand, an altered substrate metabolism and, ultimately, multiorgan failure and death 30. The mortality rate from sepsis doubles in patients who develop cardiovascular dysfunction and septic shock 1. Little is known about the cardiovascular effects of sepsis in the neonate, but the developing cardiomyocyte differs from that of the adult and may lead to differences in the cardiac response to sepsis and inflammation. In addition to underlying differences in the structure of the neonatal cardiomyocyte, functional alterations in proliferative activity 31 and excitation–contraction coupling 32 have been identified. These differences may be mediated by alterations in calcium channel expression and activity 3334, in ATP-sensitive potassium channel function 35 and in β-receptor coupling 36, and may contribute to differences in sepsis outcomes and therapeutic responses in neonates versus adults.

Cardiac dysfunction and cardiovascular collapse during sepsis result from increased levels of TNFα 37 and from increased cardiac myocyte production of nitric oxide and peroxynitrite 38, which leads to further DNA damage and ATP depletion 39, resulting in secondary energy failure 40. In addition, serum from patients with septic shock directly causes a decreased maximum extent and peak velocity of contraction, activates transcription factors for proinflammatory cytokines and induces apoptosis in cultured myocytes 41. LPS-induced production of TNFα has been associated with increased apoptosis and cell death in adult cultured cardiomyocytes 42, and this ventricular myocyte apoptosis has been linked to cardiovascular dysfunction in adult whole animal experiments 43. Neonatal cardiomyocytes, however, do not exhibit an increase in apoptosis despite an increase in TNFα production after LPS exposure, suggesting another mechanism for sepsis-associated cardiovascular dysfunction in neonates 44.

Septic shock is characterized in adults by a hyperdynamic phase with decreased left ventricular ejection fraction, decreased systemic vascular resistance and an increased cardiac index 4546. Underlying coronary artery disease, cardiomyopathy and congestive heart failure may contribute to the systolic and diastolic ventricular dysfunction described in the setting of adult sepsis. The resultant myocardial depression does not appear to be related to ischemia, however, as the coronary blood flow and coronary sinus lactate levels have been found to be normal in patients with septic shock 4748.

Myocardial dysfunction in childhood septic shock reaches its maximum within hours and is the main cause of mortality 3049. In comparison with adults, children more often present in a nonhyperdynamic state with decreased cardiac output and increased systemic vascular resistance 4650 and can develop this nonhyperdynamic septic shock even after fluid resuscitation 51. This low cardiac output is associated with an increase in mortality 5253. Owing to a limited number of research studies in the very young, the hemodynamic response of premature infants and neonates is not well understood, and the presenting hemodynamic abnormalities are more variable than in older children and adults 50. Complicating the clinical evaluation of these patients is the observation that blood pressure is a poor indicator of systemic blood flow in neonates 654.

In both premature and full-term infants, left ventricular systolic performance is highly dependent on afterload, which may increase the susceptibility of neonates to sudden cardiac deterioration in the setting of shock and vasoconstriction 5556. Newborn infants also have a relatively decreased left ventricular muscle mass 57 and an increased ratio of type I collagen (determinant of tissue rigidity) to type III collagen (provides elasticity) in myocardial tissue 58, which may account for the impaired left ventricular diastolic function and the alterations in mid-wall left ventricular fractional shortening seen in premature infants 59. These physiologic abnormalities, coupled with the finding that the neonatal left ventricular myocardium already functions at a higher baseline contractile state 55, may limit the neonate's ability to increase the stroke volume or myocardial contractility in the setting of sepsis. Complicating the cardiovascular response to sepsis in the neonate are additional morbidities, including reopening of a patent ductus arteriosus and the development of persistent pulmonary hypertension of the newborn due to cytokine elaboration, acidosis and hypoxia in the setting of sepsis 52. These underlying differences in anatomy, physiology and adaptive cardiovascular function exemplify the need to more specifically identify and understand the cardiovascular response to sepsis in the neonate in order to develop successful therapeutic strategies.

The short-term goal of treatment is to optimize the perfusion and delivery of oxygen and nutrients, to correct and/or prevent metabolic derangements resulting from cellular hypo-perfusion and to support organ and body functions until homeostasis is achieved 3060. Although our understanding of the pathophysiologic mechanisms of sepsis and septic shock has improved over the past 10 years, the mortality and morbidity associated with sepsis continues to be high 23046. Proinflammatory cytokines have been implicated in the pathogenesis of organ dysfunction during sepsis, but the modulation of single gene products (TNFα, IL-1β, inducible nitric oxide synthase) and nonpeptide mediators (platelet-activating factor, prostaglandin or leukotriene inhibitors) has not been shown to improve mortality in sepsis and septic shock 41.

Unlike adult and pediatric critical medicine, where there are extensively studied multiple organ dysfunction scores and well-defined algorhythmic guidelines for treatment 61, there is a large amount of practice variability in neonatal sepsis. The American College of Critical Care Medicine concluded that the adult guidelines for hemodynamic support of septic shock are not applicable to children and neonates, and published guidelines for these younger age groups 52. Premature neonates, however, were not specifically addressed.

The incidence of neonatal sepsis is significant, with suspected sepsis being the most common diagnosis on admission to the neonatal intensive care unit in the United States 99. Research regarding neonatal sepsis, and the cardiovascular effects of sepsis in particular, is relatively lacking. The cost of neonatal sepsis is high, with very low birthweight infants and low birthweight infants with sepsis consuming twice as much financial resource than do infants with respiratory distress syndrome 3. Future medical and social resource utilization is also increased, as there is a significant increase in the morbidity of infants surviving severe infection, with a 30–400% odds increase of later neuro-developmental impairment 100.

In the neonate, there are multiple developmental alterations in both the response to pathogens and the response to treatment that distinguish this age group from adults. Differences in innate immunity and cytokine response may predispose neonates to the harmful effects of proinflammatory cytokines and oxidative stress, leading to severe organ dysfunction and sequelae during infection and inflammation 14. Underlying differences in cardiovascular anatomy, function and response to treatment may further alter the neonate's response to pathogen exposure. We must therefore gain a greater understanding of these developmental changes in order to adequately understand and treat immune and inflammatory-related cardiovascular compromise in the neonatal population. This remarkably unstudied area of neonatal sepsis is paramount, as cardiac failure remains a main cause of death in this disease state. Translational research will be the cornerstone of this research initiative, as therapeutic agents will need to be developmentally targeted in order to be effective.

IL = interleukin; LPS = lipopolysaccharide; TNF = tissue necrosis factor.

The authors declare that they have no competing interests.

WAL was primarily responsible for the conception and design of the present review, as well as the intellectual content, drafting and revision of the manuscript. TMH and JAB also contributed significantly to the design of the review, added important intellectual content and participated in the drafting and revision of the manuscript. All three authors gave final approval of the version to be published.