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Bacteremia
Smith DA, Nehring SM.
Continuing Education Activity
Bacteremia, in the strictest sense, refers to viable bacteria in the blood. Asymptomatic bacteremia can occur in normal daily
activities such as conducting oral hygiene and after minor medical procedures. In a healthy person, these clinically benign
infections are transient and cause no further sequelae. However, when immune response mechanisms fail or become
overwhelmed, bacteremia becomes a bloodstream infection that can evolve into many clinical spectrums and is differentiated
as septicemia. This activity describes the causes and presentation of bacteremia and highlights the role of the interprofessional
team in its management.
Objectives:
Identify the etiology of bacteremia.
Outline the workup of a patient with bacteremia.
Review the treatment and management options available for bacteremia.
Explain the interprofessional team strategies for improving care coordination and communication regarding the
management of patients with bacteremia.
Access free multiple choice questions on this topic.
Introduction
Bacteremia, in the strictest sense, refers to viable bacteria in the blood. Asymptomatic bacteremia can occur in normal daily
activities such as conducting oral hygiene and after minor medical procedures. In a healthy person, these clinically benign
infections are transient and cause no further sequelae. However, when immune response mechanisms fail or become
overwhelmed, bacteremia becomes a bloodstream infection that can evolve into many clinical spectrums and is differentiated
as septicemia. Untreated and clinically significant bacteremia progresses to systemic inflammatory response syndrome (SIRS),
sepsis, septic shock, and multiple organ dysfunction syndrome (MODS). [1][2][3]
Etiology
Determining the primary source of infection is critical in the management of a patient with bacteremia, as well as in the
identification of the affected patient population. Common sources in hospitalized patients include the respiratory tract and
indwelling catheters, specifically central venous catheters. Untreated urinary tract infections most commonly cause
community-acquired bacteremia. Soft tissue and intraabdominal infections are not as common and are more prevalent in the
post-operative surgical setting. Escherichia coli is the most common cause of gram-negative associated bacteremia, while
Staphylococcus aureus is the most common gram-positive organism.[4][5][6]
Epidemiology
Geographic region, patient population, drug resistance, and infection prevention practices at each institution drive the
causative organisms of bloodstream infections. Taking into account that older patients with multiple comorbidities are more
likely to reside in community centers and be hospitalized, it is no surprise that they are at an increased risk of developing
bacteremia. Traditionally gram-negative bacilli were the driving force for most hospital-acquired bloodstream infections in
the United States and are still the most common organism associated with community-acquired bacteremia. However, with the
onset of an aging population and device-related procedures, gram-positive aerobes have seen an increase in prevalence over
the last two decades. [3][7][8]
Pathophysiology
All bacterial infections are dependent on the host immune system, which is affected by their genetic signature, as well as
congenital and acquired deficiencies. Cellular innate and adaptive immune responses are responsible for initial microbe
clearance, while the liver and spleen filter active bacteria in the circulating blood. In its most basic form, bacteria will begin
to colonize at its primary source of location. At this point, the bacteria may become transient and clinically insignificant or can
escape the host immune response and increase in number and become a local infection that can eventually migrate to other
parts of the body. If the bacteria are viable and enter the circulating bloodstream, the infection still may spontaneously clear
or progress to septicemia. The first barrier to bacterial invasion is the skin and mucosal surfaces. Conditions that interfere
with these natural defense barriers commonly include medical procedures that pass through the skin and anatomical lumina.
Additionally, events can precipitate defense breakdown via trauma, burns, ulcers, and the natural elements of aging.[6]
History and Physical
The classical presentation in a bacteremic patient is the presence of a fever. Chills and/or rigors do not need to present;
however, the presence of such signs should clue the provider that a febrile patient is now bacteremic. The development of
septicemia leading to sepsis and septic shock will commonly cause hypotension, altered mental status, and decreased urine
output due to hypovolemia from leaking capillaries. As the infection disseminates, other organs can become affected, causing
acute respiratory distress syndrome (ARDS) and acute kidney injury (AKI).
Evaluation
Identifying or presuming the source of infection will dictate the diagnostic measures taken. There should be a low threshold
for ordering labs and imaging since time is of the essence in preventing septicemia. Initial labs in all presumed bacteremic
patients should include a lactate level and blood cultures; ideally, two sets assessing for aerobic and anaerobic organisms from
each arm. In the hospital setting, most patients, at a minimum, will require a chest x-ray and urinalysis with culture. A surgical
patient may require CT imaging of the location of their surgery to assess for abscess or collection formation, as well as wound
cultures for surgical site infections. Likewise, an intubated or patient presenting with pulmonary disease will require sputum
cultures. Patients with indwelling venous catheters, hemodialysis catheters, or ports should have their lines removed and tips
cultured.[9][10]
Treatment / Management
Bacteremia requires urgent and appropriate antibiotics. Delay in the administration of appropriate antibiotics is associated
with increased morbidity and mortality. Empiric antibiotics should follow a logical approach based on the patient's history and
current disposition. For example, is the infection community or hospital-acquired, what is the patient's recent healthcare
exposure, recent medical or surgical treatment, and what is the local antibiotic resistance? Before a Gram stain is finalized, all
patients should receive broad-spectrum antibiotics covering gram-positive and gram-negative bacteria, which include
extended-generation cephalosporins or a beta-lactamase inhibitor. Pseudomonas coverage is applicable for hospital-acquired
bacteremia, as well as in a patient with recent health care exposure. Additionally, vancomycin should be added to cover
resistant gram-positive organisms, most notably methicillin-resistant resistant Staphylococcus aureus (MRSA). When the
practitioner obtains the final cultures, antibiotics should be titrated to directed therapy starting with the gram stain, and
eventually, antimicrobial susceptibility. There is no optimal duration of treatment. In most cases, antibiotic treatment should
continue for seven to 14 days and should always be administered parenterally. Oral agents are recommended when patients
have been afebrile for at least 48 hours and are otherwise clinically stable.[11][12][13]
Differential Diagnosis
Acute prostatitis / abscess
Community-acquired pneumonia (with asplenia)
Deep neck space infection abscess
Empyema
Instrumentation in patients with bacteriuria
Intra- or perinephric abscess
Lung abscess
Peritonitis abscess
Pyelonephritis
Renal calculi
Renal insufficiency
Urinary tract obstruction
Complications
Meningitis
Endocarditis
Osteomyelitis
Sepsis
Cellulitis
Peritonitis
Consultations
Infectious disease consultation is usually indicated.
Enhancing Healthcare Team Outcomes
As with most infectious diseases, preventive practice is critical in the outpatient and inpatient setting. All healthcare workers
play an important role in the prevention of bacterial infections in the workplace. At the most rudimentary level, basic hand
hygiene and the adherence to clean and sterile techniques are critical in preventing and decreasing the prevalence of
bloodstream infections. Preventative practice starts not only at the beginning of a procedure but also throughout daily
maintenance of line care. Even with strict adherence to infection control, many patients will succumb to a bloodstream
infection. Recognizing the predominant organisms associated with each clinical setting can prevent mortality as bloodstream
pathogens such as S. aureus, Pseudomonas aeruginosa, and Enterobacter species are associated with a higher mortality rate.
Prevention also includes the judicious use of antibiotics, which must take into effect the risk and reward of antibiotic
use. The rising prevalence of multi-drug-resistant bacteria has complicated treatment over the years and will continue to do
so. This rise makes education, prevention, and adherence to protocol a necessity to counter the debilitating effects of
bloodstream infections. Patient isolation, preventing airborne, and contact infections are also key factors that must be
controlled. Today, all healthcare facilities have an infectious disease committee that oversees the use of antibiotics, prescribing
habits of healthcare providers, and ensures that invasive and other bedside procedures are done under sterile conditions. The
key to lowering the morbidity of bacteremia is the education of the healthcare provider. an interprofessional team consisting
of physicians, nurse practitioners, specialty care nurses, and pharmacists will improve outcomes. Pharmacists evaluate drug
selection, doses, and interactions. Critical care and medical-surgical nurses administer treatments, monitor patients, and are
crucial in the notification of the team as to changes in status. Infection control nurses often follow up to ensure the quality of
care. [3][14][15][Level V]
Outcomes
Patients with bacteremia who are treated with antibiotics or observed have good outcomes. But rarely the bacteremia may
cause endocarditis, osteomyelitis, pneumonia, cellulitis, meningitis sepsis and multiorgan dysfunction, followed by death. Over
the past four decades, the availability of better antibiotics and vaccination has resulted in lower mortality rates in people of all
ages. Prior to the era of vaccination, the mortality rates from bacteremia were over 20%. Today, the biggest concern in the
development of antibiotic resistance which is now common against most organisms. Many guidelines have been developed to
manage children and seniors with fever and bacteremia, but the bottom line is that one should always be aware of the
potential of harm if the observation is selected as a method of treatment.[16][17][18] [Level 5]
Review Questions
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Comment on this article.
References
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Publication Details
Author Information and Affiliations
Authors
David A. Smith1; Sara M. Nehring2.
Affiliations
1
Salus University/PVAMC
2
St Bernards Medical Center
Publication History
Last Update: July 31, 2022.
Copyright
Copyright © 2022, StatPearls Publishing LLC.
This book is distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0) (
http://creativecommons.org/licenses/by-nc-nd/4.0/ ), which permits others to distribute the work, provided that the article is not altered or used commercially. You are not
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Publisher
StatPearls Publishing, Treasure Island (FL)
NLM Citation
Smith DA, Nehring SM. Bacteremia. [Updated 2022 Jul 31]. In: StatPearls [Internet]. Treasure Island (FL): StatPearls Publishing; 2022 Jan-.
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