Evaluation and management of suspected sepsis and septic shock in adults - UpToDate.pdf

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Evaluation and management of suspected sepsis and septic shock in adults - UpToDate

Official reprint from UpToDate®
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Evaluation and management of suspected sepsis and
septic shock in adults
AUTHORS: Gregory A Schmidt, MD, Jess Mandel, MD, MACP, ATSF, FRCP
SECTION EDITORS: Daniel J Sexton, MD, Korilyn S Zachrison, MD, MSc, Michelle Ng Gong, MD, MS
DEPUTY EDITOR: Geraldine Finlay, MD
All topics are updated as new evidence becomes available and our peer review process is complete.
Literature review current through: Sep 2023.
This topic last updated: Sep 21, 2023.

INTRODUCTION
Sepsis is a clinical syndrome characterized by systemic inflammation due to infection. There
is a continuum of severity ranging from sepsis to septic shock. Although wide-ranging and
dependent upon the population studied, mortality has been estimated to be ≥10 percent
and ≥40 percent when shock is present [1,2].
In this topic review, the management of sepsis and septic shock is discussed. Our approach
is consistent for the most-part with 2021 guidelines issued by the Surviving Sepsis Campaign
[3,4].
While we use the Society of Critical Care Medicine (SCCM)/European Society of Intensive Care
Medicine (ESICM) definitions, such definitions are not unanimously accepted. For example,
the Center for Medicare and Medicaid Services (CMS) still continues to support the previous
definition of systemic inflammatory response syndrome, sepsis, and severe sepsis. In
addition, the Infectious Diseases Society of America (IDSA) has pointed out that use of such
definitions, while lifesaving for those with shock, may lead to overtreatment with broadspectrum antibiotics for those with milder variants of sepsis [5].
Definitions, diagnosis, pathophysiology, and investigational therapies for sepsis, as well as
management of sepsis in the asplenic patient are reviewed separately. (See "Sepsis
syndromes in adults: Epidemiology, definitions, clinical presentation, diagnosis, and
prognosis" and "Pathophysiology of sepsis" and "Investigational and ineffective

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pharmacologic therapies for sepsis" and "Clinical features, evaluation, and management of
fever in patients with impaired splenic function".)

IMMEDIATE EVALUATION AND MANAGEMENT
Securing the airway (if indicated) and correcting hypoxemia, and establishing venous access
for the early administration of fluids and antibiotics are priorities in the management of
patients with sepsis and septic shock [3,4].
Stabilize respiration — Supplemental oxygen should be supplied to all patients with sepsis
who have indications for oxygenation, and oxygenation should be monitored continuously
with pulse oximetry. Ideal target values for peripheral saturation are unknown, but we
typically target values between 90 and 96 percent. Intubation and mechanical ventilation
may be required to support the increased work of breathing that frequently accompanies
sepsis or for airway protection since encephalopathy and a depressed level of consciousness
frequently complicate sepsis [6,7]. Target values for oxygenation, techniques and sedative
and induction agents for intubation are discussed separately. (See "Overview of initiating
invasive mechanical ventilation in adults in the intensive care unit", section on 'Fraction of
inspired oxygen' and "Induction agents for rapid sequence intubation in adults for
emergency medicine and critical care" and "Overview of advanced airway management in
adults for emergency medicine and critical care" and "Rapid sequence intubation in adults
for emergency medicine and critical care" and "The decision to intubate" and "Direct
laryngoscopy and endotracheal intubation in adults".)
Establish venous access — Venous access should be established as soon as possible in
patients with suspected sepsis. While peripheral venous or intraosseous access may be
sufficient in some patients, particularly for initial resuscitation, the majority will require
central venous access at some point during their course. However, the insertion of a central
line should not delay the administration of resuscitative fluids and antibiotics. A central
venous catheter (CVC) can be used to infuse intravenous fluids, medications (particularly
vasopressors), and blood products, as well as to draw blood for frequent laboratory studies.
While a CVC can be used to monitor the therapeutic response by measuring the central
venous pressure (CVP) and the central venous oxyhemoglobin saturation (ScvO2), evidence
from randomized trials suggest that their value is limited [8-13]. (See "Central venous
catheters: Overview of complications and prevention in adults" and 'Monitor response'
below.)
Initial investigations — An initial brief history and examination, as well as laboratory,
microbiologic (including blood cultures), and imaging studies are often obtained
simultaneously while access is being established and the airway stabilized. This brief
assessment yields clues to the suspected source and complications of sepsis, and therefore,
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helps guide empiric therapy and additional testing (

table 1). (See "Sepsis syndromes in

adults: Epidemiology, definitions, clinical presentation, diagnosis, and prognosis", section on
'Clinical presentation' and 'Empiric antibiotic therapy (first hour)' below.)
Quickly obtaining the following is preferable (within 45 minutes of presentation) but should
not delay the administration of fluids and antibiotics:
●

Complete blood counts with differential, chemistries, liver function tests, and
coagulation studies including D-dimer level. Results from these studies may support
the diagnosis, indicate the severity of sepsis, and provide baseline to follow the
therapeutic response.

●

Serum lactate – An elevated serum lactate (eg, >2 mmol/L or greater than the
laboratory upper limit of normal) may indicate the severity of sepsis and is used to
follow the therapeutic response [3,4,14-16].

●

Peripheral blood cultures (aerobic and anaerobic cultures from at least two different
sites), urinalysis, and microbiologic cultures from suspected sources (eg, sputum, urine,
intravascular catheter, wound or surgical site, body fluids, rapid antigen or polymerase
chain reaction tests) from readily accessible sites. Drawing blood for cultures through
an indwelling or central intravascular catheter should be avoided whenever possible
since ports are frequently colonized with skin flora, thereby increasing the likelihood of
a false-positive blood culture. If blood cultures are drawn from an intravenous line, a
second specimen should be drawn from a peripheral venipuncture site.
The importance of early blood cultures was best illustrated in a multicenter
randomized trial of 325 patients with a presumed or confirmed source of infection and
hypotension or elevated lactate >4 mmol/L [17]. All patients had two sets of blood
cultures drawn from two separate sites before antimicrobial administration and a
second set of blood cultures was obtained from zero to four hours after antimicrobial
administration. Pre-antimicrobial cultures were positive in 31.4 percent compared with
19.4 percent post-antimicrobial administration. When pre-antimicrobial cultures were
considered the reference gold standard, the sensitivity of post-antimicrobial blood
cultures was 53 percent. When other cultures were included with post-antimicrobial
blood cultures, pathogens were identified in approximately two-thirds of patients.
Although some methodologic issues (eg, in some patients only one blood culture or
one venipuncture was obtained instead of two), this study nonetheless highlights the
importance of taking blood cultures prior to antimicrobial administration. Importantly,
both the collection of cultures and the initiation of antimicrobial therapy should be
prompt in those with the signs of severe sepsis.

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●

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Arterial blood gas (ABG) analysis – ABGs may reveal acidosis, hypoxemia, or
hypercapnia.

●

Imaging targeted at the suspected site of infection is warranted (eg, chest radiography,
computed tomography of chest and/or abdomen).

●

Procalcitonin – While the diagnostic value of procalcitonin in patients with sepsis is
poorly supported by evidence, its value in de-escalating antibiotic therapy is well
established in populations, in particular, those with community acquired pneumonia
and respiratory tract infections; measurement of procalcitonin to guide duration of
antibiotic use is appropriate in those populations with sepsis, while its role in other
groups is unclear. While one meta-analysis of 5158 critically ill patients reported a
mortality benefit associated with procalcitonin use a survival benefit was not noted in
the subset of patients with sepsis [18]. In contrast, a randomized trial of 266 patients
with sepsis from lower respiratory tract infections, acute pyelonephritis, or primary
bloodstream infection, procalcitonin guided therapy was associated with a reduction in
28-day mortality (28 versus 15 percent) and length of antibiotic therapy (5 versus 10
days) [19]. While encouraging, additional data from well-conducted randomized trials in
patients with sepsis are required before we can routinely recommend procalcitonin use
all patients with sepsis. Detailed evidence to support the use of procalcitonin is
provided separately. (See "Procalcitonin use in lower respiratory tract infections" and
"Clinical evaluation and diagnostic testing for community-acquired pneumonia in
adults", section on 'Serum biomarkers'.)

INITIAL RESUSCITATIVE THERAPY
The cornerstone of initial resuscitation is the rapid restoration of perfusion and the early
administration of antibiotics.
●

Tissue perfusion is predominantly achieved by the aggressive administration of
intravenous fluids (IVF), usually crystalloids (balanced crystalloids or normal saline)
given at 30 mL/kg (actual body weight), started by one hour and completed within the
first three hours following presentation.

●

Empiric antibiotic therapy is targeted at the suspected organism(s) and site(s) of
infection and preferably administered within the first hour.

Our approach is based upon several major randomized trials that used a protocol-based
approach (ie, early goal-directed therapy [EGDT]) to treating sepsis [8-13]. Components of
the protocols usually included the early administration of fluids and antibiotics (within one to
six hours) using the following targets to measure the response: central venous
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oxyhemoglobin saturation (ScvO2) ≥70 percent, central venous pressure (CVP) 8 to 12 mmHg,
mean arterial pressure (MAP) ≥65 mmHg, and urine output ≥0.5 mL/kg/hour. Although all
trials [9-11] (except for one [8]) did not show a mortality benefit to EGDT, it is thought that
the lack of benefit was explained by an overall improved outcome in both control and
treatment groups and to improved clinical performance by trained clinicians in academic
centers during an era that followed an aggressive sepsis education and management
campaign. In support of this hypothesis is that central line placement was common (>50
percent) in control groups so it is likely that CVP, ScvO2, and/or lactate clearance were
targeted in these patients. Furthermore, the mortality in studies that did not report a benefit
to EGDT [9-11] approximated that of the treatment arm in the only study that reported
benefit [8].
●

One single center randomized trial of 263 patients with suspected sepsis reported a
lower mortality in patients when ScvO2, CVP, MAP, and urine output were used to direct
therapy compared with those in whom only CVP, MAP, and urine output were targeted
(31 versus 47 percent) [8]. Both groups initiated therapy, including antibiotics, within six
hours of presentation. There was a heavy emphasis on the use of red cell transfusion
(for a hematocrit >30) and dobutamine to reach the ScvO2 target in this trial.

●

Three subsequent multicenter randomized trials of patients with septic shock, ProCESS
[9], ARISE [10], and ProMISE [11] and two meta-analyses [12,13] all reported no
mortality benefit (mortality ranged from 20 to 30 percent), associated with an identical
protocol compared with protocols that used some of these targets or usual care. In
contrast, one meta-analysis of 13 trials reported a mortality benefit from early-goal
directed therapy within the first six hours [20].

●

A lack of benefit of resuscitation protocols has also been reported in resource-limited
settings. As an example, in a randomized trial of 212 patients with sepsis (defined as
suspected infection plus two systemic inflammatory response syndrome criteria) and
hypotension (systolic blood pressure ≤90 mmHg or MAP <65 mmHg) in Zambia, a
protocolized approach of aggressive fluid resuscitation, monitoring, blood, and
vasopressor transfusion within the first six hours of presentation resulted in a higher
rate of death (48 versus 33 percent) when compared with usual care [21]. However,
several flaws including crude measurements of monitoring, lower than usual rates of
lactate elevation, larger than typical volumes of fluid resuscitation, and use of
dopamine (as opposed to norepinephrine) in a population with a high percentage of
patients with human immunodeficiency virus may have biased the results.

●

Another analysis from a cohort of 1871 Canadian patients reported that prehospital
administration of fluids by paramedics to patients with hypotension from sepsis may
be of benefit, although it was associated with increased prehospital time [22].

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A post-hoc analysis of the ANROMEDA-SHOCK trial [23] suggested that peripheral
perfusion-targeted resuscitation (using capillary refill time [CRT]) may be associated
with a lower mortality and faster resolution of organ dysfunction than lactate-targeted
resuscitation [24]. Additional studies suggest a poor correlation between MAP and CRT
[25]. Further study is required before clinicians should use CRT routinely as a marker of
resuscitation.

The importance of timely treatment, particularly with antibiotics, was illustrated in a
database study of nearly 50,000 patients with sepsis and septic shock who were treated with
various types of protocolized treatment bundles (that included fluids and antibiotics, blood
cultures, and serum lactate measurements) [26]. Compared with those in whom a threehour bundle (blood cultures before broad spectrum antibiotics, serum lactate level) was
completed within the three-hour time frame, a higher in-hospital mortality was reported
when a three-hour bundle was completed later than three hours (odds ratio [OR] 1.04 per
hour). Increased mortality was associated with the delayed administration of antibiotics but
not with a longer time to completion of a fluid bolus (as part of a six hour bundle) (OR 1.04
per hour versus 1.10 per hour).
Intravenous fluids (first three hours) — In patients with sepsis, intravascular hypovolemia
is typical and may be severe, requiring rapid fluid resuscitation. (See "Treatment of severe
hypovolemia or hypovolemic shock in adults".)
Volume — Intravascular hypovolemia is typical and may be severe in sepsis. Rapid, large
volume infusions of IVF (30 mL/kg) are indicated as initial therapy for severe sepsis or septic
shock, unless there is convincing evidence of significant pulmonary edema. This approach is
based upon several randomized trials that reported no difference in mortality when mean
infusion volumes of 2 to 3 liters were administered in the first three hours [9-11] compared
with larger volumes of three to five liters, which was considered standard therapy at the time
[8]. However, some patients may require higher than recommended volumes, particularly
those who demonstrate clinical and/or hemodynamic indicators of fluid-responsiveness.
(See 'Monitor response' below.)
Fluid therapy should be administered in well-defined (eg, 500 mL), rapidly infused boluses.
The clinical and hemodynamic response and the presence or absence of pulmonary edema
must be assessed before and after each bolus. Intravenous fluid challenges can be repeated
until blood pressure and tissue perfusion are acceptable, pulmonary edema ensues, or fluid
fails to augment perfusion.
In one trial, over 1500 patients with sepsis-induced hypotension refractory to initial
resuscitation with 1 to 3 L of IVF were randomized to receive either a restrictive fluid regimen
(prioritizing vasopressors and lower intravenous fluid volumes) or liberal fluid regimen
(prioritizing higher volumes of intravenous fluids before vasopressor use). The restrictive
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strategy entailed early administration of vasopressors after infusion of up to 2 L of fluid
including prerandomization fluid, if needed. The liberal regimen prioritized infusion of an
additional 2 L at randomization in addition to prerandomized fluid and additional boluses as
needed [27]. Despite more fluid administration in the liberal group compared with the
restrictive group (3400 versus 1267mL at 24 hours), there was no difference in 90-day
mortality (15 versus 14 percent) or any other outcome measured. Vasopressors were
administered earlier and for longer periods in those who received the restrictive regimen
but did not appear to be associated with excess adverse effects. However, results may have
been impacted by greater than intended fluid volumes administered in some patients in the
restrictive group and lower than intended volumes in some patients in the liberal group,
perhaps limiting the ability of the study to detect a meaningful difference between the
interventions. In addition, the median volume administered in the liberal group is
reasonably close to that which is widely practiced and both arms of this trial led to
administration of significantly less fluid than would have been typical a decade ago; this
suggests that adopting a more aggressive restrictive approach than currently practiced may
not be associated with additional benefit.
Choice of fluid — Evidence from randomized trials and meta-analyses have found no
convincing difference between using albumin solutions and crystalloid solutions (eg,
Ringer's lactate, normal saline) in the treatment of sepsis or septic shock, but they have
identified potential harm from using pentastarch or hydroxyethyl starch [28-37]. There is no
role for hypertonic saline [38].
In our practice, we generally use a balanced crystalloid solution, and less commonly, normal
saline, instead of an albumin solution because of the lack of clear benefit and higher cost of
albumin. Balanced crystalloid rather than normal saline is preferred if there is a perceived
need to avoid or treat the hyperchloremia that occurs when large volumes of nonbuffered
crystalloid (eg, normal saline) are administered, although the data to support this practice
are weak (and discussed separately). (See "Treatment of severe hypovolemia or hypovolemic
shock in adults", section on 'Choice of replacement fluid'.)
Data discussing IVF choice among patients with sepsis include the following:
●

Crystalloid versus albumin – Among patients with sepsis, several randomized trials
and meta-analyses have reported no difference in mortality when albumin was
compared with crystalloids, although one meta-analysis suggested benefit in those
with septic shock [29,36,37]. In the Saline versus Albumin Fluid Evaluation (SAFE) trial
performed in critically ill patients, there was no benefit to albumin compared with
saline even in the subgroup with severe sepsis, who comprised 18 percent of the total
group [28]. Among the crystalloids, there are no guidelines to suggest that one form is
more beneficial than the other.

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Crystalloid versus hydroxyethyl starch (HES) – In the Scandinavian Starch for Severe
Sepsis and Septic Shock (6S) trial, compared with Ringer's acetate, use of HES resulted
in increased mortality (51 versus 43 percent) and renal replacement therapy (22 versus
16 percent) [30]. Similar results were found in additional trials of patients without
sepsis.

●

Crystalloid versus pentastarch – The Efficacy of Volume Substitution and Insulin
Therapy in Severe Sepsis (VISEP) trial compared pentastarch to modified Ringer's
lactate in patients with severe sepsis and found no difference in 28-day mortality [31].
The trial was stopped early because there was a trend toward increased 90-day
mortality among patients who received pentastarch.

●

Balanced salt solutions – Evidence to support the use of a balanced crystalloid
solution or 0.9 percent saline in patients with sepsis is indirect and mostly derived from
studies performed in a mixed population of critically ill patients. Further details are
provided separately. (See "Treatment of severe hypovolemia or hypovolemic shock in
adults", section on 'Choosing between 0.9 percent saline and buffered crystalloid'.)

Treating metabolic acidosis — Whether metabolic acidosis associated with sepsis should
be treated with bicarbonate is discussed separately. (See "Bicarbonate therapy in lactic
acidosis".)
Empiric antibiotic therapy (first hour) — Prompt identification and treatment of the site(s)
of infection is the primary therapeutic intervention, with most other interventions being
purely supportive.
Identification of suspected source — Empiric antibiotics should be targeted at the
suspected source(s) of infection which is typically identified from the initial history, physical
examination, and preliminary laboratory findings and imaging (

table 1) (see 'Initial

investigations' above). However, additional diagnostic testing or interventions may be
required to identify the anatomic site(s) of infection. In particular, in addition to antibiotics,
closed-space infections should be promptly drained or debrided (eg, empyema, abscess) for
effective source control. (See 'Septic focus identification and source control' below.)
Timing — Once a presumed diagnosis of sepsis or septic shock has been made, optimal
doses of appropriate intravenous antibiotic therapy should be initiated, preferably within
one hour of presentation and after cultures have been obtained (see 'Initial investigations'
above). The early administration of antimicrobials is often challenging because various
patient- and institutional-related factors may lead to delays in timely treatment [39].
Institutional protocols should address timeliness as a quality improvement measure [40].
However, several clinician groups including the Infectious Diseases Society of America (IDSA)
criticized the Society of Critical Care Medicine (SCCM) for promoting standards defining rigid
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time frames for initiation of antibiotics as it is often difficult to determine the actual onset of
sepsis in individual patients; in addition, the one hour time frame could lead to overuse and
inappropriate administration of unwarranted antimicrobials [5,41]. The IDSA favors removal
of a recommendation for specific minimum time frames for initiating antibiotic therapy and
instead advocates replacing these recommendations with the statement that prompt
administration of antibiotics is recommended once a presumed diagnosis of sepsis or shock
has been made by the treating clinician [5].
Although the feasibility of a one hour target for initiating antibiotics has not been assessed,
the rationale for choosing it is based upon observational studies that report poor outcomes
with delayed (even beyond one hour), inadequately dosed, or inappropriate (ie, treatment
with antibiotics to which the pathogen was later shown to be resistant in vitro) antimicrobial
therapy [42-52].
●

In a retrospective analysis of over 17,000 patient with sepsis and septic shock, delay in
first antibiotic administration was associated with increased in-hospital mortality with a
linear increase in the risk of mortality for each hour delay in antibiotic administration
[50]. Similar results were reported in an emergency department cohort of 35,000
patients [52].

●

A prospective cohort study of 2124 patients demonstrated that inappropriate antibiotic
selection was surprisingly common (32 percent) [46]. Mortality was markedly increased
in these patients compared with those who had received appropriate antibiotics (34
versus 18 percent).

Choosing a regimen — The choice of antimicrobials can be complex and should consider
the patient's history (eg, recent antibiotics received, previous organisms), comorbidities (eg,
diabetes, organ failures), immune defects (eg, human immune deficiency virus), clinical
context (eg, community- or hospital-acquired), suspected site of infection, presence of
invasive devices, Gram stain data, and local prevalence and resistance patterns [53-57]. The
general principles and examples of potential empiric regimens are given in this section but
antimicrobial choice should be tailored to each individual.
For most patients with sepsis without shock, we recommend empiric broad spectrum
therapy with one or more antimicrobials to cover all likely pathogens. Coverage should be
directed against both gram-positive and gram-negative bacteria and, if indicated, against
fungi (eg, Candida) and occasionally viruses (eg, influenza, coronavirus disease 2019 [COVID19]). Broad spectrum is defined as therapeutic agent(s) with sufficient activity to cover a
range of gram-negative and gram-positive organisms (eg, carbapenem, piperacillintazobactam). In order to ensure treatment with an effective antibiotic, many patients with
septic shock suspected to be due to gram-negative organisms may require initial therapy
with two antimicrobials from two different classes (ie, combination therapy), although this
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practice depends upon the organisms that are considered likely pathogens and local
antibiotic susceptibilities.
Empiric therapy for patients with sepsis should be directed at the most common organisms
causing sepsis in specific patient populations. Among organisms isolated from patients with
sepsis, the most common include Escherichia coli, Staphylococcus aureus, Klebsiella
pneumoniae, and Streptococcus pneumoniae, such that coverage of these organisms should
be kept in mind when choosing an agent [58].
However, when the organism is unknown, the clinician should be mindful of other potential
pathogens when risk factors are present and consider the following:
●

Methicillin-resistant S. aureus – Methicillin-resistant S. aureus (MRSA) is a cause of sepsis
not only in hospitalized patients but also in community dwelling individuals without
recent hospitalization [59,60]. For these reasons, we suggest empiric intravenous
vancomycin (adjusted for renal function) be added to empiric regimens, particularly in
those with shock or those at risk for MRSA. Potential alternative agents to vancomycin
(eg, daptomycin for nonpulmonary MRSA, linezolid) should be considered for patients
with refractory or virulent MRSA or with a contraindication to vancomycin. (See
"Methicillin-resistant Staphylococcus aureus (MRSA) in adults: Treatment of bacteremia"
and "Treatment of hospital-acquired and ventilator-associated pneumonia in adults".)
In our practice, if Pseudomonas is an unlikely pathogen, we favor combining
vancomycin with one of the following:

• A third generation (eg, ceftriaxone or cefotaxime) or fourth generation
cephalosporin (cefepime), or

• A beta-lactam/beta-lactamase inhibitor (eg, piperacillin-tazobactam), or
• A carbapenem (eg, imipenem or meropenem)
●

Pseudomonas – Alternatively, if Pseudomonas is a likely pathogen, we favor combining
vancomycin with one to two of the following, depending on local antibiotic
susceptibility patterns (see "Principles of antimicrobial therapy of Pseudomonas
aeruginosa infections"):

• Antipseudomonal cephalosporin (eg, ceftazidime, cefepime), or
• Antipseudomonal carbapenem (eg, imipenem, meropenem), or
• Antipseudomonal beta-lactam/beta-lactamase inhibitor (eg, piperacillintazobactam), or

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• Fluoroquinolone with good anti-pseudomonal activity (eg, ciprofloxacin), or
• Aminoglycoside (eg, gentamicin, amikacin), or
• Monobactam (eg, aztreonam)
●

Non pseudomonal gram-negative organisms (eg, E. coli, K. pneumoniae) – In the past,
gram-negative pathogens routinely were covered with two agents from different
antibiotic classes. However, several clinical trials and two meta-analyses failed to
demonstrate superior overall efficacy of combination therapy compared to
monotherapy with a third generation cephalosporin or a carbapenem [46,61-65].
Furthermore, one meta-analysis found double coverage that included an
aminoglycoside was associated with an increased incidence of adverse events
(nephrotoxicity) [64,65]. For this reason, in patients with suspected gram-negative
pathogens, we recommend use of a single agent with proven efficacy and the least
possible toxicity, except in patients who are either neutropenic or whose sepsis is due
to a known or suspected Pseudomonas infection, where combination therapy can be
considered [63]. (See "Pseudomonas aeruginosa bacteremia and endocarditis" and
"Principles of antimicrobial therapy of Pseudomonas aeruginosa infections".)

●

Invasive fungal infections – The routine administration of empirical antifungal therapy
is not generally warranted in nonneutropenic critically ill patients. Invasive fungal
infections occasionally complicate the course of critical illness, especially when the
following risk factors are present: surgery, parenteral nutrition, prolonged
antimicrobial treatment or hospitalization (especially in the intensive care unit [ICU]),
chemotherapy, transplant, chronic liver or renal failure, diabetes, major abdominal
surgery, vascular devices, septic shock or multisite colonization with Candida spp.
However, studies do not support the routine use of empiric antifungals in this
population:

• In a meta-analysis of 22 studies (most often comparing fluconazole to placebo, but
also using ketoconazole, anidulafungin, caspofungin, micafungin, and amphotericin
B), untargeted empiric antifungal therapy possibly reduced fungal colonization and
the risk of invasive fungal infection but did not reduce all-cause mortality [66].

• In a study of critically ill patients ventilated at least five days, empiric antifungal
treatment (mostly fluconazole) was not associated with a decreased risk of mortality
or occurrence of invasive candidiasis [67].

• In a multicenter randomized trial (EMPIRICUS) of 260 nonneutropenic critically ill
patients with Candida colonization (at multiple sites), multiple organ failure, and
ICU-acquired sepsis, empiric treatment for 14 days with micafungin did not result in
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improved infection-free survival at 28 days but did decrease the rate of new fungal
infection [68].
However, if Candida or Aspergillus is strongly suspected or if neutropenia is present, an
echinocandin (for Candida) or voriconazole (for Aspergillus) are often appropriate. (See
"Treatment and prevention of invasive aspergillosis" and "Management of candidemia
and invasive candidiasis in adults".)
●

Other – Other regimens should consider the inclusion of agents for specific organisms
such as Legionella (macrolide or fluoroquinolone) or difficult to treat organisms (eg,
Stenotrophomonas), or for specific conditions (eg, neutropenic bacteremia)

Dosing — Clinicians should pay attention to maximizing the dose in patients with sepsis
and septic shock using a full "high-end" loading dose where possible. This strategy is based
upon the known increased volume of distribution that can occur in patients with sepsis due
to the administration of fluid [69-71] and that higher clinical success rates have been
reported in patients with higher peak concentrations of antimicrobials [72-74].
Continuous infusions of antibiotics as compared with intermittent dosing regimens remains
investigational at this time [75]. Continuous infusions of beta lactam antimicrobials have
been shown to provide higher and sustained drug levels above the minimum inhibitory
concentration compared with the peaks and trough of intermittent dosing [76-78]. In a
double-blind randomized trial of 607 patients prescribed meropenem for sepsis, outcomes
were compared when meropenem was administered as a continuous infusion or
intermittent infusion [79]. The mode of administration did not affect the composite outcome
of 28-day mortality and the emergence of pandrug-resistant bacteria (47 versus 49 percent).
In addition, there also was no difference in the length of ICU or hospital stay, days alive and
free from the ICU, or 90-day mortality. However, therapeutic monitoring was not performed
and the prescription of other microbials was common, both of which may limit the ability to
detect a difference between the groups. Further study is needed before continuous
infusions can be recommended.
Location of admission — Whether patients should be admitted to an ICU or ward is unclear
and likely varies with the individual presenting characteristics as well as available
institutional services and policy, which also may vary from state to state and country to
country. For example, patients with septic shock who require mechanical ventilation and
vasopressors clearly require ICU admission while those without shock who quickly respond
to fluid and antibiotics may be safely transferred to the floor. For those in between these
extremes, close observation and a low threshold to admit to the ICU is prudent.
Use of a systematic approach to ICU admission has been studied. One study of 3037 critically
ill French patients aged 75 years or older, randomized patients to hospitals that promoted a
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systematic approach to ICU admission (interventional group) or to hospitals that did not use
this approach (usual care) [80]. Despite a doubling of the admission rate to the ICU and an
increased risk of in-hospital death, there was no difference in mortality at six months after
adjustment for age, illness severity, initial clinical diagnosis, seniority of the emergency
department clinician, time of ICU admission, baseline functional status, living situation, and
type of home support. However, several flaws including, higher severity of illness in the
intervention group, lack of blinding, and a strategy that was underpowered to detect a
mortality difference may have influenced these results. In addition, international differences
in the care of patients with sepsis may also explain an opposing outcome reported by a
United States cohort [81].

MONITOR RESPONSE
After fluids and empiric antibiotics have been administered, the therapeutic response should
be assessed frequently. We suggest that clinical, hemodynamic, and laboratory parameters
be followed as outlined in the sections below. In our experience, most patients respond
within the first 6 to 24 hours to initial fluid therapy, however, resolution can be protracted
and take days or weeks. The response mostly influences further fluid management but can
also affect antimicrobial therapy and source control.
Monitoring catheters — For many patients, a central venous catheter (CVC) and an arterial
catheter are placed, although they are not always necessary. For example, an arterial
catheter may be inserted if blood pressure is labile, sphygmomanometer readings are
unreliable, restoration of perfusion is expected to be protracted (especially when
vasopressors are administered), or dynamic measures of fluid responsiveness are selected
to follow the hemodynamic response. A CVC may be placed if the infusion of large volumes
of fluids or vasopressors are anticipated, peripheral access is poor, or the central venous
pressure (CVP) or the central venous oxyhemoglobin saturation (ScvO2) are chosen as
methods of monitoring the hemodynamic response. (See "Intra-arterial catheterization for
invasive monitoring: Indications, insertion techniques, and interpretation" and "Novel tools
for hemodynamic monitoring in critically ill patients with shock" and "Central venous access
in adults: General principles".)
We believe that pulmonary artery catheters (PACs) should not be used in the routine
management of patients with sepsis or septic shock since they have not been shown to
improve outcome [82-84]. PACs can measure the pulmonary artery occlusion pressure
(PAOP) and mixed venous oxyhemoglobin saturation (SvO2). However, the PAOP has proven
to be a poor predictor of fluid responsiveness in sepsis and the SvO2 is similar to the ScvO2,
which can be obtained from a CVC [85,86]. (See "Pulmonary artery catheterization:
Indications, contraindications, and complications in adults".)
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Clinical — All patients should be followed clinically for improved mean arterial pressure
(MAP), urine output, heart rate, respiratory rate, skin color, temperature, pulse oximetry, and
mental status. Among these, a MAP ≥65 mmHg (MAP = [(2 x diastolic) + systolic]/3)
(calculator 1), and urine output ≥0.5 mL/kg per hour are common targets used in clinical
practice. They have not been compared to each other nor have they been proven to be
superior to any other target or to clinical assessment. Data supporting the use of these
clinical parameters are discussed above. (See 'Initial resuscitative therapy' above.)
Most clinicians target a MAP ≥65 mmHg based upon data from large randomized trials that
demonstrated benefit when using this target MAP (see 'Initial resuscitative therapy' above).
However, the ideal target for MAP, is unknown. Furthermore, data since then suggest that
higher MAPs (eg, ≥70 mmHg) may be harmful, while targeting lower MAPs (eg, 60 to 65
mmHg) may be appropriate. Thus, a reasonable goal may be to individualize targets within a
range (eg, 60 to 70 mmHg) rather than targeting one specific numeric goal. Further trials are
pending that should help elucidate an optimal range for a target MAP for patients with
hypotension from sepsis.
●

One trial that randomized patients to a target MAP of 65 to 70 mmHg (low target MAP)
or 80 to 85 mmHg (high target MAP) reported no mortality benefit to targeting a higher
MAP [87]. Patients with a higher MAP had a greater incidence of atrial fibrillation (7
versus 3 percent), suggesting that targeting a MAP >80 mmHg is potentially harmful.

●

A pilot randomized trial reported that among patients aged 75 years or older, a higher
MAP target (75 to 80 mmHg) was associated with increased hospital mortality
compared with a lower MAP target (60 to 65 mmHg; 60 versus 13 percent) [88]. The
same group subsequently reported outcomes in a nonblinded randomized trial of 2600
volume-repleted patients with vasodilatory shock who were older than 65 years and 80
percent of whom had sepsis (the "65 trial") [89]. Patients in whom vasopressors were
used to target a MAP 60 to 65 mmHg ("permissive hypotension"; median mean MAP
66.7 mmHg) were compared with patients who received "usual care" (MAP at the
discretion of the treating clinician; median MAP 72.6 mmHg). Fluid balance, rates of
corticosteroid use (roughly one-third), and urine output were similar among the
groups. Although the 90 day mortality was no different, the point estimate favored the
permissive hypotension treatment strategy (41 versus 44 percent; adjusted odds ratio
0.82, 95% CI 0.68-0.98) and patients in the permissive hypotension group received
lower doses of vasopressors for shorter duration. Importantly, there were no
differences in the rates of cognitive dysfunction, cardiac arrhythmias, or acute renal
failure. Although the prespecified outcome of superiority was not met, this trial
suggests that at minimum, permissive hypotension was not harmful and supports the
use of lower than usual target MAPs. It also suggests that similar to observations in
other trials, clinicians tend to "overshoot" the target when a target MAP is set. However,

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several flaws including bias due to lack of blinding and a higher than usual mortality in
the usual care group may limit interpretation of this study.
●

Two meta-analyses that did not include the "65 trial" above [89] reported increased
mortality in patients in whom a higher MAP was targeted with vasopressor use for
greater than six hours [90] and a greater risk of supraventricular cardiac arrhythmias
[91]. Another meta-analysis found no difference in mortality or the need for renal
replacement therapy when higher versus lower MAP targets were used [92].

Hemodynamic — Static or dynamic predictors of fluid responsiveness should be employed
in order to determine further fluid management. Guidelines state a preference for dynamic
measures [3] since they are more accurate than static measures (eg, CVP) at predicting fluid
responsiveness. However whether the use of dynamic predictors improve clinically impactful
outcomes such as mortality remains unproven.
●

Static – Traditionally, in addition to MAP, the following static CVC measurements were
used to determine adequate fluid management:

• CVP at a target of 8 to 12 mmHg
• ScvO2 ≥70 percent (≥65 percent if sample is drawn off a PAC)
While one early trial of patients with septic shock reported a mortality benefit to these
static parameters in a protocol-based therapy, trials published since then (ProCESS,
ARISE, ProMISe) have reported no mortality benefit in association with their use [8-11].
(See 'Initial resuscitative therapy' above.)
●

Dynamic – Respiratory changes in the vena caval diameter, radial artery pulse
pressure, aortic blood flow peak velocity, left ventricular outflow tract velocity-time
integral, and brachial artery blood flow velocity are considered dynamic measures of
fluid responsiveness. There is increasing evidence that dynamic measures are more
accurate predictors of fluid responsiveness than static measures, as long as the
patients are in sinus rhythm and passively ventilated with a sufficient tidal volume. For
actively breathing patients or those with irregular cardiac rhythms, an increase in the
cardiac output in response to a passive leg-raising maneuver (measured by
echocardiography, arterial pulse waveform analysis, or pulmonary artery
catheterization) also predicts fluid responsiveness. Choosing among these is
dependent upon availability and technical expertise, but a passive leg raising maneuver
may be the most accurate and broadly available. Future studies that report improved
outcomes (eg, mortality, ventilator free days) in association with their use are needed.
Further details are provided separately. (See "Novel tools for hemodynamic monitoring
in critically ill patients with shock".)

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Laboratory
●

Lactate clearance – Although the optimal frequency of measuring serum lactate is
unknown, we follow serum lactate (eg, every six hours) in patients with sepsis until the
lactate value has clearly fallen. While guidelines promote normalization of lactate [3],
lactate-guided resuscitation has not been convincingly associated with improved
outcomes.
The lactate clearance is defined by the equation [(initial lactate – lactate >2 hours
later)/initial lactate] x 100. The lactate clearance and interval change in lactate over the
first 12 hours of resuscitation has been evaluated as a potential marker for effective
resuscitation [14,93-98]. One meta-analysis of five low quality trials reported that
lactate–guided resuscitation resulted in a reduction in mortality compared with
resuscitation without lactate [3]. Other meta-analyses reported modest mortality
benefit when lactate clearance strategies were used compared with usual care or ScvO2
normalization [96,97]. However, many of the trials included in these meta-analyses
studied heterogeneous populations and used varying definitions of lactate clearance as
well as additional variables that potentially affected the outcome.
In addition, lactate is a poor marker of tissue perfusion after the restoration of
perfusion [99]. As a result, lactate values are generally unhelpful following restoration
of perfusion, with one exception: a rising serum lactate level should prompt
reevaluation of the adequacy of perfusion. (See "Venous blood gases and other
alternatives to arterial blood gases".)
Devices that allow measurement of serum lactate levels at the bedside are now
available and their use may increase the practicality and utility of serial monitoring of
serum lactate levels [100-102].

●

Routine laboratories – Follow up laboratory studies, in particular platelet count,
serum chemistries, and liver function tests are often performed (eg, every six hours)
until values have reached normal or baseline. Hyperchloremia should be avoided, but if
it is occurs, switching to low chloride-containing (ie, buffered) solutions may be
indicated. (See "Treatment of severe hypovolemia or hypovolemic shock in adults",
section on 'Buffered crystalloid'.)

●

Microbiology – Follow up indices of infection are also indicated, including complete
blood count and additional cultures. Results should prompt alteration of antibiotic
choice if a better and safer regimen can be substituted and/or investigations directed
toward source control. (See 'Septic focus identification and source control' below.)

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●

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Arterial blood gases – It is prudent to follow worsening or resolution of gas exchange
abnormalities, as well as the severity and type of acidosis (eg, resolution of metabolic
acidosis and development of hyperchloremic acidosis). Worsening gas exchange may
be a clue to the presence of pulmonary edema from excessive fluid resuscitation and
also help detect other complications including pneumothorax from central catheter
placement, acute respiratory distress syndrome, or venous thromboembolism.

SEPTIC FOCUS IDENTIFICATION AND SOURCE CONTROL
In our experience, a focused history and physical examination is the most valuable method
for source detection. Following initial investigations and empiric antimicrobial therapy,
further efforts aimed at identifying and controlling the source(s) of infection should be
performed in all patients with sepsis. In addition, for those who fail despite therapy or those
who fail having initially responded to therapy, further investigations aimed at adequacy of
the antimicrobial regimen or nosocomial super infection should be considered.
●

Identification – Additional investigations targeted at the suspected source(s) should
be considered in patients with sepsis as promptly as is feasible (eg, within the first 12
hours). This investigation may include imaging (eg, computed tomography,
ultrasonography) and sample acquisition (cultures or further diagnostic samples [eg,
bronchoalveolar lavage, aspirating fluid collections or joints]); performing additional
investigations depends upon the risk, if an intervention is involved, and patient
stability. If invasive Candida or Aspergillus infection is suspected, serologic assays for 1,3
beta-D-glucan, galactomannan, and anti-mannan antibodies, if available, may provide
early evidence of these fungal infections. These assays are discussed separately. (See
"Clinical manifestations and diagnosis of candidemia and invasive candidiasis in
adults", section on 'Nonculture methods' and "Diagnosis of invasive aspergillosis",
section on 'Galactomannan antigen detection' and "Diagnosis of invasive aspergillosis",
section on 'Beta-D-glucan assay'.)

●

Source control – Source control (ie, physical measures to eradicate a focus of infection
and eliminate or treat microbial proliferation and infection) should be undertaken in
timely manner when they feasible since undrained foci of infection may not respond to
antibiotics alone (

table 2). As examples, potentially infected vascular access devices

should be removed (after other vascular access has been established). Other examples
include removing other infected implantable devices/hardware, when feasible, abscess
drainage (including thoracic empyema and joint), percutaneous nephrostomy, soft
tissue debridement or amputation, colectomy (eg, for fulminant Clostridium difficileassociated colitis), and cholecystostomy.

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The optimal timing of source control is unknown but guidelines suggest no more than
6 to 12 hours after diagnosis since survival is negatively impacted by inadequate source
control [3]. Although the general rule of thumb is that source control should occur as
soon as possible [103-105], this is not always practical or feasible. In addition, decisions
about the type and timing of source control should take into consideration the risk of a
specific intervention and its potential risk of complications (eg, death, fistula formation)
and the likelihood of success, particularly when there is diagnostic uncertainty
regarding the source.

PATIENTS WHO FAIL INITIAL THERAPY
Patients having persistent hypoperfusion despite adequate fluid resuscitation and
antimicrobial treatment should be reassessed for fluid responsiveness (see 'Hemodynamic'
above) adequacy of the antimicrobial regimen and septic focus control (see 'Septic focus
identification and source control' above) as well as the accuracy of the diagnosis of sepsis
and/or its source and the possibility that unexpected complications or coexisting problems
have occurred (eg, pneumothorax following central venous catheter insertion) (see
"Evaluation of and initial approach to the adult patient with undifferentiated hypotension
and shock"). Other options for treatment of persistent hypoperfusion such as the use of
vasopressors, glucocorticoids, inotropic therapy, and blood transfusion are discussed in this
section.
Vasopressors — Intravenous vasopressors are useful in patients who remain hypotensive
despite adequate fluid resuscitation or who develop cardiogenic pulmonary edema. Based
upon meta-analyses of small randomized trials and observational studies, a paradigm shift
in practice has occurred such that most experts prefer to avoid dopamine in this population
and favor norepinephrine as the first-choice agent (

table 3 and

table 4). Although

guidelines suggest additional agents including vasopressin (up to 0.03 units/minute to
reduce the dose of norepinephrine) or epinephrine (for refractory hypotension), practice
varies considerably. Guidelines state a preference for central venous and arterial access
especially when vasopressor administration is prolonged or high dose, or multiple
vasopressors are administered through the same catheter [3]; while this is appropriate,
waiting for placement should not delay their administration via a peripheral catheter.
●

First agent – Data that support norepinephrine as the first-line single agent in septic
shock are derived from numerous trials that compared the use of one vasopressor to
another [106-112]. These trials studied norepinephrine versus phenylephrine [113],
norepinephrine versus vasopressin [114-117], norepinephrine versus terlipressin [118120], norepinephrine versus epinephrine [121], and vasopressin versus terlipressin
[122]. While some of the comparisons found no convincing difference in mortality,

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length of stay in the intensive care unit or hospital, or incidence of kidney failure
[117,123], two meta-analyses reported increased mortality among patients who
received dopamine during septic shock compared with those who received
norepinephrine (53 to 54 percent versus 48 to 49 percent) [109,124]. Although the
causes of death in the two groups were not directly compared, both meta-analyses
identified arrhythmic events about twice as often with dopamine than with
norepinephrine.
However, we believe the initial choice of vasopressor in patients with sepsis is often
individualized and determined by additional factors including the presence of
coexistent conditions contributing shock (eg, heart failure), arrhythmias, organ
ischemia, or agent availability. For example, in patients with significant tachycardia (eg,
fast atrial fibrillation, sinus tachycardia >160/minute), agents that completely lack beta
adrenergic effects (eg, vasopressin) may be preferred if it is believed that worsening
tachycardia may prompt further decompensation. Similarly, dopamine (DA) may be
acceptable in those with significant bradycardia; but low dose DA should not be used
for the purposes of "renal protection."
The impact of agent availability was highlighted by one study of nearly 28,000 patients
from 26 hospitals, which reported that during periods of norepinephrine shortages,
phenylephrine was the most frequent alternative agent chosen by intensivists (use rose
from 36 to 54 percent) [125]. During the same period, mortality rates from septic shock
rose from 36 to 40 percent. Whether this was directly related to phenylephrine use
remains unknown.
●

Additional agents – The addition of a second or third agent to norepinephrine may be
required (eg, epinephrine, dobutamine, or vasopressin).

• For patients with distributive shock from sepsis, vasopressin may be added. In a
meta-analysis of 23 trials, the addition of vasopressin to catecholamine
vasopressors (eg, epinephrine, norepinephrine) resulted in a lower rate of atrial
fibrillation (relative risk 0.77, 95% CI 0.67-0.88) [126]. However, when including only
studies at low risk of bias, no mortality benefit, reduced requirement for renal
replacement therapy, or rate of myocardial injury, stroke, ventricular arrhythmias or
length of hospital stay was reported. Although not studied, this effect is likely due to
a reduced need for catecholamines which increase the risk of cardiac arrhythmias.
This analysis is consistent with other trials and meta-analyses that have
demonstrated no mortality benefit from vasopressin and selepressin in patients
with septic shock [127-131].

• For patients with refractory septic shock associated with a low cardiac output,
addition of an inotropic agent may be useful. In a retrospective series of 234
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patients with septic shock, among several vasopressor agents added to
norepinephrine (dobutamine, dopamine, phenylephrine, vasopressin), inotropic
support with dobutamine was associated with a survival advantage (epinephrine
was not studied) [132]. (See "Use of vasopressors and inotropes", section on
'Epinephrine' and "Use of vasopressors and inotropes", section on 'Dobutamine'.)
Whether lower vasopressor use is associated with lower mortality is unclear [133].
Additional information regarding vasopressor use including angiotensin II is provided
separately. (See "Use of vasopressors and inotropes".)
Additional therapies — Most clinicians agree that additional therapies such as
glucocorticoids, inotropic agents, or red blood cell (RBC) transfusion are not routinely
warranted in patients with sepsis or septic shock but the use of these therapies maybe
useful in refractory cases of septic shock or in special circumstances.
Glucocorticoids — Guidelines recommend against the routine use of glucocorticoids in
patients with sepsis. However, corticosteroid therapy may be appropriate in patients with
septic shock that is refractory to adequate fluid resuscitation and vasopressor
administration. This topic is discussed in detail separately. (See "Glucocorticoid therapy in
septic shock in adults".)
Inotropic therapy — A trial of inotropic therapy may be warranted in patients who fa