STRATEGIES FOR MANAGING CLOSTRIDIOIDES DIFFICILE

INFECTIONS

Liz Fredrickson, PharmD, BCPS

Liz Fredrickson is an Associate Professor of Pharmacy Practice and Pharmaceutical Sciences at the Northeast Ohio Medical University (NEOMED) College of Pharmacy.

 

Topic Overview

Clostridioides difficile infection (CDI) is among the most prevalent hospital- acquired infections. It continues to pose significant challenges in healthcare settings, with subsequent increases in morbidity, mortality, and healthcare costs. Pharmacy teams play pivotal roles in CDI management through the application of antimicrobial stewardship and infection control and the provision of patient and caregiver education. This continuing education activity aims to provide pharmacists and pharmacy technicians with comprehensive knowledge and practical strategies for effectively managing CDI. The pathophysiology and epidemiology of CDI will be reviewed, and detailed diagnostic, prevention, and management strategies will be discussed in depth.

 

Accreditation Statement

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RxCe.com LLC is accredited by the Accreditation Council for Pharmacy Education (ACPE) as a provider of continuing pharmacy education.

 

Universal Activity Number (UAN): The ACPE Universal Activity Number assigned to this activity is 

Pharmacist  0669-0000-24-101-H01-P

Pharmacy Technician  0669-0000-24-102-H01-T

Credits: 2 contact hour(s) (0.2 CEU(s)) of continuing education credit

 

Type of Activity: Knowledge

Media: Internet/Home study Fee Information: $6.99

 

Estimated time to complete activity: 2 contact hour(s) (0.2 CEU(s)), including Course Test and course evaluation

Release Date: July 17, 2024 Expiration Date: July 17, 2027

Target Audience: This educational activity is for pharmacists and pharmacy technicians

 

How to Earn Credit: From July 17, 2024, through July 17, 2027, participants must:

Read the “learning objectives” and “author and planning team disclosures;”

Study the section entitled “Educational Activity;” and

Complete the Course Test and Evaluation form. The Course Test will be graded automatically. Following successful completion of the Course Test with a score of 70% or higher, a statement of participation will be made available immediately. (No partial credit will be given.)

Credit for this course will be uploaded to CPE Monitor®.

 

Learning Objectives: Upon completion of this educational activity, participants should be able to:

Describe the underlying pathophysiology of and risk factors for Clostridioides difficile infection (CDI)

Identify methods by which to prevent CDI

Compare and Contrast management strategies for CDI

Recall methods by which to educate patients and caregivers on the prevention and treatment of CDI

 

Disclosures

The following individuals were involved in developing this activity: Liz Fredrickson, PharmD, BPCS, and Pamela Sardo, PharmD, BS. Pamela Sardo and Liz Fredrickson have no conflicts of interest or financial relationships regarding the subject matter discussed. There are no financial relationships or commercial or financial support relevant to this activity to report or disclose by RxCe.com or any of the individuals involved in the development of this activity.

© RxCe.com LLC 2024: All rights reserved. No reproduction of all or part of any content herein is allowed without the prior, written permission of RxCe.com LLC.

Educational Activity

Strategies for Managing Clostridioides difficile Infections Introduction

 

Clostridioides difficile infection is a hospital-acquired infection. It continues to pose significant challenges in healthcare settings, with subsequent increases in morbidity, mortality, and healthcare costs. Pharmacy teams play pivotal roles in Clostridioides difficile infection management through the application of antimicrobial stewardship and infection control and the provision of patient education. This continuing education activity aims to provide pharmacists and pharmacy technicians with comprehensive knowledge and practical strategies for effectively preventing and managing Clostridioides difficile infection. The pathophysiology and epidemiology of Clostridioides difficile infection will be reviewed, and detailed diagnostic and management strategies will be discussed.

 

Epidemiology and Etiology

 

Clostridioides difficile infection (CDI) is among the most prevalent hospital-acquired infections.1 It leads to increases in morbidity, mortality, and healthcare costs.1,2 These infections are so serious that the Centers for Disease Control and Prevention (CDC) has deemed Clostridioides difficile (C. difficile) an urgent threat to public health which requires aggressive action.1,2 The most recent guidelines for managing CDI were updated in 2021 by the American College of Gastroenterology (ACG) and the Infectious Diseases Society of America/Society for Healthcare Epidemiology of America (IDSA- SHEA).3,4

 

Clostridioides difficile is a gram-positive, obligately anaerobic, spore- forming bacterium commonly found in hospitals and long-term care facilities due to high antimicrobial use and contamination with C. difficile spores.5,6 In these settings, CDIs account for approximately 15-20% of all cases of

antibiotic-associated diarrhea.6 This includes conditions ranging from mild diarrhea to severe pseudomembranous colitis (PMC).6

 

In 2017, over 460,000 cases of CDI were documented in the United States (US).5 While the incidence of healthcare-associated CDI has decreased in recent years, the incidence of community-acquired CDI has risen, now accounting for up to 40% of all cases.5,6 Multiple recurrent CDI has increased disproportionately, with an 189% increase in the US between 2001 and 2012; in contrast, CDI increased by 46% at this time.6 The emergence of more virulent strains, such as ribotype 027, has contributed significantly to the CDI epidemic, leading to more severe illness and higher relapse rates.6

 

Clostridioides difficile is most commonly transmitted via the fecal-oral route when spores are ingested.7 Initially linked to clindamycin, ampicillin, and cephalosporins, CDI is often associated with second and third-generation cephalosporins and fluoroquinolones.5 Some antimicrobials, including piperacillin/tazobactam, are associated with fewer cases.5 However, all antibiotics put patients at some risk of CDI, as they can upset normal gut flora.2,5 Infections are mostly likely to occur during antibiotic therapy or shortly after treatments end.7 However, even after therapy, patients remain at risk and can develop C. difficile for up to three months following antibiotic exposure.2 Despite the overall decline in CDI rates, the persistence of these virulent strains underscores the importance of infection prevention programs and the reduction of modifiable risk factors, such as fluoroquinolone use, to mitigate the spread of resistant C. difficile strains.6

 

Risk Factors

 

Numerous host—and therapy-related factors may put patients at risk of developing CDI. The most pertinent risks include older age (65 years or older), exposure to the healthcare environment, and exposure to antibiotics.2 CDI risk factors are summarized in Table 1 and described in more detail below.2,5,7,8

Table 1

CDI Risk Factors2,5,7,8

Initial CDI InfectionsRecurrent CDI Infections
Recent healthcare exposureAntibiotic exposure after initial CDI episode
Advanced age (65+ years old)Advanced age (65+ years old)
HospitalizationProlonged or recent stay in healthcare facility
Acid-suppression therapyAcid-suppression therapy
ImmunosuppressionInfection with a hypervirulent strain
Abdominal surgery/nasogastric tubePrior episode of CDI
Diabetes mellitus 
End-stage renal disease 
Inflammatory bowel disease 

 

Antibiotic Use

 

Meta-analyses show differences in CDI risk based on the setting and region of antibiotic use.8 Clindamycin, cephalosporins, carbapenems, fluoroquinolones, and trimethoprim/sulphonamides minimally double the CDI risk in hospital settings.8 In community settings, clindamycin increases CDI risk by 8 to 20 times and cephalosporins and quinolones by 3 to 5 times.8 Macrolides significantly increase community-associated CDI risk but not hospital-associated CDI risk.8 Tetracyclines and aminoglycosides are not significantly associated with CDI in either setting.8

 

Use of Gastric Acid Suppressors and Other Drugs

 

Proton pump inhibitors (PPIs), commonly used for acid-related gastrointestinal disorders, have been linked to CDI and recurrent CDI (rCDI).8 Systematic reviews and meta-analyses report significant associations between PPI use and CDI, with varying strengths of association.8 Causality cannot be determined due to confounding variables surrounding gastric acid suppressor use, including polypharmacy and comorbidities.8 While it is recommended to avoid the unnecessary use of PPIs, patients do not need to stop acid suppression therapy solely to prevent CDI.2 The role of NSAIDs in CDI risk is

inconsistent.8 While aspirin is not significantly associated with CDI in the community, corticosteroids are, as noted in one meta-analysis.8 Non-selective NSAIDs (not including COX-2 inhibitors) have been associated with CDI.8

 

Age

 

Increased age is a significant risk factor for both incident CDI and recurrent CDI.8 In 2011, CDI rates in the USA were four times higher among adults aged 65 and older than those aged 45–65 and thirteen times higher than those aged 18–44.8 Older age has also been linked to a higher risk of CDI with the virulent BI/NAP1/027 strain and rCDI.8

 

Comorbidities

 

Various comorbidities increase the risk of community-associated CDI, including inflammatory bowel disease, diabetes, leukemia or lymphoma, renal failure, and solid cancer.8 Lower 25-hydroxyvitamin D (25(OH)D) levels are linked to increased susceptibility to infectious diseases, but the evidence for an association with CDI is limited.8 Some studies suggest a significant link between low 25(OH)D and rCDI, but this is based on a few studies and does not differentiate between hospital and community settings.8

 

Clinical Characteristics and Interventions

 

Exposure to healthcare settings is a well-known risk factor for CDI.8 Longer hospital stays are strongly associated with exposure to C. difficile spores and colonization. However, study results on the length of stay as a determinant for CDI are inconsistent.8 Some studies show that CDI patients have hospital stays 2–4 times longer than non-CDI patients, while others find no difference.8 Invasive procedures such as abdominal surgery, nasogastric tube placement, and mechanical ventilation are associated with prolonged hospitalization and increased CDI risk.8 Age, systemic antibiotic treatment, leukocyte count, albumin levels, and temperature at diagnosis are prognostic factors associated with poor outcomes.8

Pathophysiology of CDI

 

Three key events are required for CDI development: exposure to antimicrobial agents (which disrupt normal gut flora), exposure to toxigenic

C. difficile, and a third factor, such as a virulent strain, specific antimicrobial exposure, or inadequate immune response.5 The host immune response, especially the serum IgG antibody response to toxin A, significantly influences susceptibility to CDI.5 Individuals with higher antibody levels tend to be asymptomatic carriers, while those with lower levels are more likely to develop symptomatic CDI and experience higher recurrence rates.1

 

When toxigenic C. difficile spores are ingested, they can survive the stomach's acidity, germinate in the small intestine, and colonize the lower intestinal tract.5 Two major toxins are then produced, toxin A (an enterotoxin) and toxin B (a cytotoxin), that disrupt the epithelial-cell barrier, leading to diarrhea and pseudomembrane formation.5 Toxin A is a potent neutrophil chemoattractant.5 Studies indicate that toxin B is the more crucial virulence factor, as clinical disease can occur with toxin A-negative but not toxin B- negative strains.5 Cytoskeleton disruption results in loss of cell shape, adherence, and tight junctions, causing fluid leakage.5

 

Clinical Presentation and Diagnosis Clinical Manifestations

Diarrhea is the most common symptom of CDI, characterized by stools that are rarely bloody and may be unformed, watery, or mucoid.5 CDI is often associated with a distinctive odor.5 Other clinical signs include fever (28% of cases), abdominal pain (22%), and leukocytosis (50%).5 It is important that patients who present with new and unexplained diarrhea be evaluated for potential CDI.2 CDI recurs in about 15-30% of treated cases, either as relapses with the same strain or reinfections with a new strain, largely due to antibiotics' continued disruption of the normal fecal microbiota.5

Diagnosis

 

Per the ACG guidelines, only individuals with symptoms that suggest active CDI should be tested.3 This includes unexplained, new-onset diarrhea.2 CDI testing algorithms should include a highly sensitive and specific testing modality to differentiate between colonization and active infection.5 CDI diagnosis combines clinical criteria and laboratory tests.5 The criteria include

(1) diarrhea (≥3 unformed stools per 24 hours for ≥2 days) without another known cause and (2) detection of toxin A or B, toxin-producing C. difficile by nucleic acid amplification testing (NAAT, such as PCR), or by culture, or visualization of pseudomembranes in the colon.5 Endoscopy can rapidly diagnose suspected PMC in severely ill patients, but a negative result does not rule out CDI.5

 

Table 2 provides the sensitivity and specificity of diagnostic tests for CDI.5 Clinicians should note that no single test for C. difficile and its toxins offers high sensitivity, specificity, and rapid results.1 Enzyme immunoassays (EIAs) for toxins often lack sensitivity, and repeated stool testing is not recommended.5 NAATs are rapid and sensitive but may detect colonization without active CDI.5 If a NAAT is negative, the patient does not have CDI, but testing should be done to confirm CDI if this test is positive.2 Empirical treatment is advised if CDI is strongly suspected and stool testing is delayed. Testing asymptomatic patients is generally discouraged, and "tests of cure" post-treatment are not recommended since many patients remain carriers without active disease.5

 

Table 2

Relative Sensitivity and Specificity of Diagnostic Tests for Clostridioides difficile Infection (CDI)5

Type of TestRelative SensitivityRelative SpecificityNotes
Stool culture for C. difficile+++++++

Most sensitive test; specificity of

++++ if the C. difficile isolate tests positive for toxin; turnaround time

too slow for practical use

Type of TestRelative SensitivityRelative SpecificityNotes
Cell culture cytotoxin test on stool+++++++

With clinical data, it is diagnostic of CDI; highly specific but not as sensitive as stool culture; slow

turnaround time

Enzyme immunoassay for toxins A and

B in stool

++ to ++++++

With clinical data, it is diagnostic of CDI; rapid results, but not as sensitive as stool culture or cell

culture cytotoxin test

Enzyme immunoassay for C.

difficile common antigen in stool

+++ to

++++

+++

Detects glutamate dehydrogenase found in toxigenic and nontoxigenic strains of C. difficile and other stool organisms; more sensitive and less specific than enzyme immunoassay for toxins; requires confirmation

with a toxin test; rapid results

Nucleic acid amplification tests for C. difficile toxin A or B gene in

stool

+++++++

Detects toxigenic C. difficile in stool; widely used in the United States for clinical testing; more sensitive than enzyme immunoassay toxin testing; a marked increase in CDI diagnoses

when implemented

Colonoscopy or sigmoidoscopy+++++Highly specific if pseudomembranes are seen; insensitive compared with other tests

Note: ++++, >90%; +++, 71–90%; ++, 51–70%; +, ~50%.

 

Classification of CDI

 

The ACG guidelines recommend various criteria for classifying severe CDI infection, including a white blood cell count >/ 15,000 or a serum creatinine >1.5 mg/dL.5 Additionally, they define fulminant infections as occurring in patients who meet the criteria for a severe CDI and have hypotension, shock, ileus, or megacolon.5 Criteria to determine CDI severity are detailed in Table 3.2

Table 3

Criteria for CDI Severity2

DefinitionSupportive Data
Nonsevere infectionWBC </15,000 cells/mL and SCr <1.5 mg/dL
Severe infectionWBC >15,000 cells/mL or SCr >1.5 mg/dL
Fulminant infectionHypotension, shock, ileus, or megacolon

 

Prevention and Management of CDI

 

Prevention

 

Probiotics are live microorganisms that offer the host health benefits when consumed in adequate amounts.5 They work by colonizing and normalizing disturbed intestinal microbial communities, competitively excluding pathogens, producing bacteriocins (antibiotics), and modulating the immune system and various metabolic functions to maintain gut mucosa integrity.5 The ACG guidelines do not recommend that probiotics be used to prevent CDI in patients being treated with antibiotics as primary prevention or to use them as secondary prevention in patients with a previous case(s) of CDI.3 Probiotics are sold as dietary supplements with claims to improve gut health, without stringent Food and Drug Administration (FDA) oversight required for manufactured drugs.3 Consequently, manufacturers often avoid conducting clinical trials to support specific uses, leading to suboptimal quality control, product labeling, and efficacy inconsistencies.3 Furthermore, recent microbiome analyses suggest that probiotics may hinder normal colon recolonization after antibiotic treatment.3

 

Primary Prevention

 

A 2017 Cochrane review examined 31 studies on probiotics for primary CDI prevention in adults and children receiving antibiotics, involving 8,672 participants.9 Most studies (27 out of 31) had a high or unclear risk of bias and missing data.9 The review concluded that probiotics offer a modest benefit (number needed to benefit = 42), but post hoc subgroup analysis showed benefits only in trials with baseline CDI risk >5%.9 Five studies were found to

heavily influence results, with CDI baseline risk >15%, questioning their applicability to typical hospital settings.9

 

A meta-analysis by McFarland, et al., focused on a specific probiotic combination comprising three lactobacilli strains.10 Out of three randomized controlled trials (RCTs), only one showed efficacy for primary CDI prevention.10 Another recent meta-analysis of 19 RCTs found that probiotics reduced CDI risk in hospitalized patients, particularly when started within two days of beginning antibiotics, showing a 70% risk reduction.11 However, this benefit dropped to 30% if probiotics were started after two days.11 Notably, these studies excluded immunocompromised patients, those undergoing cancer treatments, ICU patients, and individuals with preexisting gastrointestinal conditions.11

 

Secondary Prevention

 

The 2017 PICO trial included 33 patients with initial mild-to-moderate CDI.12 Patients were randomized to receive either a 28-day course of either a 4-strain probiotic or placebo alongside standard anti-CDI therapy.9 The trial found no significant difference in CDI recurrence rates between the two groups.12 A 2000 study included 168 patients with recurrent CDI who received a 28-day course of S. boulardii or placebo in addition to anti-CDI therapy.13 Benefits were observed only in the subgroup treated with high-dose vancomycin and S. boulardii (16.7% recurrence vs. 50% with placebo).13 Due to the small sample size, firm conclusions could not be drawn.13

 

Guideline-Based Management of CDI

 

The American College of Gastroenterologists (ACG) and jointly the Infectious Diseases Society of America (IDSA) and Society for Healthcare Epidemiology of America (SHEA) offer guidelines for the management of CDI in adult patients.3,4 Both sets of guidelines were published in 2021.3,4

Treatment of Nonsevere CDI

 

In treating CDI, it is important that any antibiotics that may have caused the infection be stopped if feasible to reduce the risk of recurrent CDI.2 The ACG guidelines make three recommendations pertaining to the treatment of nonsevere CDI:3

 

Oral vancomycin 125 mg 4 times daily for 10 days to treat initial episodes of nonsevere CDI

Oral fidaxomicin 200 mg twice daily for 10 days to treat initial episodes of nonsevere CDI

Oral metronidazole 500 mg three times daily for 10 days to be considered for treatment of initial nonsevere CDI in low-risk patients

 

The IDSA/SHEA guidelines recommend fidaxomicin for a first episode over a standard course of vancomycin.4 They state vancomycin is acceptable, but fidaxomicin is preferred, given its safety and efficacy.4

 

Fidaxomicin and vancomycin have shown efficacy in treating nonsevere CDI.3 One double-blind, randomized controlled trial (RCT) found fidaxomicin 200 mg twice daily for 10 days was non-inferior to vancomycin 125 mg four times daily for 10 days.14 In this study, the rate of recurrence within 30 days was significantly lower with the use of fidaxomicin.15 A second study found no difference in clinical failure or recurrence between fidaxomicin and vancomycin treatments.15 In contrast, the role of metronidazole is less definitive.3 A 2017 review of 22 trials of patients with nonsevere disease found vancomycin was more effective than metronidazole for symptomatic cure, and fidaxomicin was more effective than vancomycin.16 Vancomycin has the benefit of being relatively inexpensive, while fidaxomicin leads to lower rates of recurrence, which ultimately can result in lower costs.3 Patients who are younger and have few to no comorbidities may be able to utilize metronidazole.3

 

Other antibiotics, including rifaximin and tigecycline, are not recommended for treating CDI.3 Additionally, loperamide without concurrent antibiotic use is not recommended.3 In some studies, patients either

experienced complications of therapy or died after receiving antimotility agents without concurrent antibiotics.3 The guidelines state that loperamide or antimotility agents could be used as needed in patients who have been started on anti-CDI therapy.3 However, they should be avoided in fulminant CDI.3 Other agents that may be helpful in the recovery phase include psyllium husk, as fiber helps to regulate intestinal barrier function and inflammation and has shown benefits for post-infection IBS symptoms.3

 

Treating Severe CDI

 

The following treatment options are recommended by the ACG guidelines:3

 

As initial therapy for severe CDI, we recommend vancomycin 125 mg 4 times a day for 10 days

As initial therapy for severe CDI, we recommend fidaxomicin 200 mg twice daily or 10 days

 

One meta-analysis aimed to compare treatments for non-multiple recurrent CDI in adults, examining both primary cure and recurrence rates.17 This study included 24 randomized controlled trials with 5,361 patients, assessing 13 different treatments. Fidaxomicin had higher sustained cure rates than vancomycin, but vancomycin was more cost-effective.18 In terms of medication dosing, another study that included 46 hospitalized patients with

C. diff colitis showed no differences in rates of cure, response time, or recurrence rates between vancomycin 125 mg and 500 mg given four times daily for 10 days.18

 

Fidaxomicin was shown to not be inferior to vancomycin for clinical cure at the end of therapy in patients with severe C. difficile infections.19 A retrospective study of critically ill patients indicated a similar response to fidaxomicin as in general medical wards, but one-third of the 36 patients with severe or fulminant CDI experienced treatment failure.20 A larger retrospective chart review comparing fidaxomicin and oral vancomycin found no significant difference in clinical failure or recurrence rates and no

differences in mortality at 30 or 180 days.21 Most studies utilized 10-day treatment courses for both drugs, which seems adequate for the majority of patients.3

 

Metronidazole is not recommended for severe CDI as it is inferior to vancomycin in multiple randomized controlled trials and cohort studies.3 A retrospective study revealed that patients with severe CDI who received vancomycin only after failing metronidazole had longer hospital stays, higher rates of acute kidney injury, and lower cure rates compared to those who received vancomycin from the start.22 Additionally, a large cohort study found that vancomycin reduced the 30-day all-cause mortality rate from 19.8% to 15.3% compared to metronidazole.23

 

Fulminant CDI

 

The following are ACG guidelines for the management of fulminant CDI:3

 

Patients with fulminant CDI should receive medical therapy that includes adequate volume resuscitation and treatment with 500 mg of oral vancomycin every 6 hours daily for the first 48–72 hours. Combination therapy with parenteral metronidazole 500 mg every 8 hours can be considered

For patients with ileus, the addition of vancomycin enemas (500 mg every 6 hours) may be beneficial

 

A multidisciplinary care team is necessary to ensure optimal patient outcomes when caring for patients with fulminant CDI. This team should include the following specialties: critical care, gastroenterology, and infectious disease, among others.3 A dearth of evidence recommends vancomycin 500 mg every 6 hours to treat fulminant CDI, but numerous guidelines have suggested this.3 The guidelines suggest treating with this higher dosage for 48-72 hours is reasonable.3 If clinical improvement is achieved, the dose of vancomycin can be decreased to 125 mg every 6 hours for 10 more days.3 Patients who do not respond should be reevaluated for a different approach.3

Vancomycin enema at a concentration of 500 mg per 100 mL saline is recommended for patients with ileus.3 However, there is little literature to support this decision.3 Theoretically, delivering the drug via enema is beneficial over orally administered medications as these may not pass beyond the upper GI tract.3

 

While vancomycin monotherapy is superior to metronidazole for severe CDI, guidelines recommend adding intravenous metronidazole to oral vancomycin for fulminant disease.3 A single-center retrospective study found lower mortality rates in ICU patients with fulminant CDI who received vancomycin and metronidazole compared to vancomycin alone.3 However, a more recent multicenter study found no added benefit of intravenous metronidazole regarding colectomy, death, or recurrence rates.3 Intravenous metronidazole may still be beneficial in cases of paralytic ileus, where oral vancomycin transit is impaired, as it can achieve therapeutic concentrations in the inflamed colon.3

 

Fidaxomicin is not inferior to vancomycin for severe CDI, but no data supports its use in fulminant CDI.3 While case reports suggest that adjunctive intravenous immunoglobulin might help in refractory fulminant CDI, a larger study showed no improvement in outcomes.3 Additionally, a retrospective cohort study indicated that bedside colonic lavage with polyethylene glycol solution might reduce in-hospital mortality compared to colectomy, although this is not recommended for routine use.3 Table 4 summarizes the IDSA-SHEA treatment recommendations for various CDI conditions.

 

Table 4

IDSA-SHEA Treatment Recommendations

 

Infection TypePreferred RegimenAlternativ e RegimenAdditional RecommendationsADEs and Use Considerations
InitialFidaxomicinVancomyciFor nonsevere CDI:Fidaxomicin:
 : 200 mgn: 125 mgmetronidazole 500minimal systemic
 PO BID xPO QID xmg PO TID x 10-14absorption;
 10 days10 daysdays (if otherhypersensitivity
   agents notpotential if
   available) 
    

macrolide allergy present

Oral vancomycin: Minimal systemic absorption; consider monitoring trough levels for systemic absorption and drug accumulation in patients with renal failure or duration of use more than 10 days Metronidazole: avoid repeated or prolonged courses owing to the risk of neurotoxicity. Avoid alcohol during treatment and for 3 days after therapy

completion

First Recurrence

Fidaxomicin

: 200 mg PO BID x

10 days or Fidaxomicin 200 mg PO

BID x 5

days, then once every other day for 20 days

Vancomyci n: 125 mg PO BID x

10 days or vancomycin 125 mg PO

QID x 10-

14 days, then BID x 7 days, then once daily x 7 days, then every 2-3

days for 2-

8 weeks

Adjunctive bezlotoxumab 10 mg/kg IV given once during antibiotic therapy in select patientsBezlotoxumab: use only in patients with a history of CHF when benefits > risks.
Second Recurrence

Fidaxomicin

: 200 mg PO BID x

10 days or Fidaxomicin 200 mg PO

BID x 5

days, then

 

Reserve FMT for patients who received appropriate antibiotics for 2+ episodes of recurrence (or 3 CDI)

Adjunctive bezlotoxumab 10

 
 

once every other day for 20 days or Vancomycin

: 125 mg PO BID x

10 days or vancomycin 125 mg PO

QUID x 10-

14 days, then BID x 7 days, then once daily x 7 days, then every 2-3

days for 2-

8 weeks

 mg/kg IV given once during antibiotic therapy in select patients 
Fulminant

Vancomycin 500 mg PO

or via nasogastric tube QID and metronidaz ole 500 mg

IV Q8H

 Surgical intervention may be neededRectal vancomycin may be systemically absorbed in cases of inflamed intestinal mucosa

 

Surgical Options and Fecal Microbiota Transplantation for Severe and Fulminant CDI

 

The ACG guidelines suggest that for patients who require surgical intervention, either a total colectomy with an end ileostomy and a stapled rectal stump or a diverting loop ileostomy with colonic lavage and intraluminal vancomycin be used depending on clinical circumstances, the patient's estimated tolerance to surgery, and the surgeon's clinical judgment.3 Fecal microbiota transplant (FMT) be considered for patients with severe and fulminant CDI refractory to antibiotic therapy, in particular when patients are deemed poor surgical candidates.3

Data from surgical registries suggest that diversion does not provide a clear survival advantage over total colectomy for fulminant CDI.3 It is crucial to avoid delayed surgical intervention, which increases postoperative mortality and premature surgery, assuming that diversion is low risk.3 Institutions should review their outcomes with diversion to ensure mortality or recurrence rates do not exceed those for total colectomy.3

 

For patients with fulminant CDI, after pseudomembrane resolution is confirmed by colonoscopy, a final FMT should complete therapy.3 If hospital discharge occurs before complete resolution, oral vancomycin or fidaxomicin should continue for at least five days, followed by outpatient FMT.3 The availability of donor stool from stool banks has improved treatment promptness.3 Clinical response to FMT can be monitored by stool form, frequency, presence of pseudomembrane, leukocytosis, and C-reactive protein levels. FMT should be considered after 48–72 hours of maximum medical therapy for severe and fulminant CDI, as it is less invasive and avoids surgical risks.3 Nonetheless, surgery remains standard for refractory cases, especially with colonic toxic megacolon, ischemia, or perforation.3

 

Antimicrobial Stewardship and Prevention Strategies

 

The following are recommendations to assist hospital facilities with CDI prevention:24

 

Essential Practices for CDI Prevention: Conduct and analyze CDI surveillance data, provide regular reports to key stakeholders, reduce the risk of CDI by recommending they avoid unnecessary antibiotic exposure, and select lower-risk antibiotics.

 

Antimicrobial Stewardship: Implement programs that require approval before administering high-risk antibiotics, such as fluoroquinolones and cephalosporins, particularly during CDI outbreaks. Target patients with a history of CDI for special attention.

Diagnostic Stewardship: Develop criteria for C. difficile testing, avoid testing in patients without significant diarrhea or recent testing, and educate healthcare providers on appropriate test use and interpretation.

 

Contact Precautions: Use hand hygiene, gowns, gloves, and private rooms for CDI patients. Cohort patients when private rooms are unavailable and ensure proper cleaning and disinfection of shared equipment.

 

Environmental Cleaning: Implement protocols for cleaning and disinfecting patient environments and equipment. Consider using sporicidal agents in outbreak settings and monitor the adequacy of cleaning practices.

 

Alert System: Establish a laboratory-based alert system for immediate notification of CDI cases to infection preventionists and clinical personnel to ensure timely contact precautions.

 

CDI Surveillance: Conduct and analyze CDI surveillance data, providing regular reports to key stakeholders to inform and improve prevention efforts.

 

Education: Educate healthcare personnel, environmental service staff, patients, and their families about CDI, including its risks, transmission, and prevention measures.

 

Hand Hygiene Compliance: Measure and ensure compliance with hand hygiene practices according to CDC or WHO guidelines, emphasizing glove use and appropriate hand cleaning methods after patient contact.

 

The Role of the Pharmacist and Pharmacy Technicians

 

Pharmacists and pharmacy technicians play important roles in caring for patients with CDI. One study assessed whether a pharmacist-led antimicrobial

stewardship program (ASP) could improve adherence to CDI treatment guidelines and clinical outcomes.25 Conducted at a single center, the retrospective, quasi-experimental study analyzed patients with CDI before and after implementing an ASP initiative, which involved prospective audits and feedback.26 Guideline-based treatment recommendations were communicated to treatment teams and documented in pharmacy progress notes for all CDI patients.26 The primary goal was to measure the proportion of patients receiving guideline-compliant treatments within 72 hours of diagnosis. Secondary objectives included evaluating clinical outcomes such as length of stay (LOS), infection-related LOS, 30-day readmission rates, and in- hospital mortality.2 Out of 233 patients evaluated, the post-intervention group showed a significant increase in guideline-adherent treatments within 72 hours (42% before vs. 58% after, p=0.02).26 However, there were no differences in clinical outcomes or the use of laxatives, promotility agents, or proton pump inhibitors within 72 hours of diagnosis. The authors concluded that a pharmacist-led stewardship initiative successfully improved adherence to CDI treatment guidelines.26

 

Pharmacists can provide education on proper hand hygiene, emphasizing the importance of washing with soap and water to reduce transmission.26 Another role is promoting gut health through dietary advice and cautious use of probiotics.26 Pharmacists can also advocate for targeted antibiotic therapy, recommend discontinuing unnecessary PPIs, and stress the importance of completing prescribed courses.26 Additionally, they can help patients access affordable medication regimens and facilitate smooth transitions between different phases of care by educating post-acute facilities and caretakers on proper medication management and adherence.26 Pharmacy technicians can help pharmacists identify patients with diarrhea who may need to be referred to their primary care provider. They can also encourage proper hand hygiene for patients presenting with symptoms of diarrhea.

Summary

 

Clostridioides difficile infection is among the most prevalent hospital- acquired infections. It continues to pose significant challenges in healthcare settings, with subsequent increases in morbidity, mortality, and healthcare costs. Pharmacy teams play pivotal roles in CDI management through the application of antimicrobial stewardship and infection control and the provision of patient and caregiver education.

Course Test

Which of the following is true regarding the most pertinent risk factors for developing Clostridioides difficile infection (CDI)?

 

Individuals younger than 35 years of age are at the greatest risk

Tetracycline use increases the risk of CDI in community settings

Diabetes mellitus is a risk factor for developing an initial CDI infection

Use of proton pump inhibitors has not been shown to significantly increase the risk of CDI

 

Which toxin is the most crucial virulent factor for the development of CDI?

Toxin A

Toxin B

Toxin C

Toxin D

Which of the following is true regarding the role of probiotics in preventing CDI?

The American College of Gastroenterology recommends use of probiotics for primary but not secondary prevention

There is ample data to support the efficacy and safety of probiotics to prevent CDI

Probiotics are associated with inconsistencies in product efficacy, quality control, and product labeling and are not recommended for primary or secondary CDI prevention

A large meta-analysis found probiotics decrease the risk of CDI for patients with any level of baseline risk

Which of the following strategies can be used to prevent CDI in hospital settings?

Allow healthcare providers to order high-risk antibiotics without approval

Avoid using private rooms for patients with CDI

Test all patients in the hospital for CDI, even those without significant diarrhea

Conduct and analyze CDI surveillance data, providing regular reports to key stakeholders

Which of the following is recommended by the American College of Gastroenterology for treating nonsevere CDI infections?

IV vancomycin 20 mg/kg Q12H for 7 days

Oral vancomycin 125 mg four times a day for 10 days

Oral fidaxomicin 1000 mg once daily for 7 days

IV metronidazole 500 mg twice daily for 10 days

 

The IDSA/SHEA guidelines prefer                     to be used to treat a first episode of CDI, given its safety and efficacy.

fidaxomicin

rifamycin

vancomycin

metronidazole

 

Which of the following medications is recommended by the IDSA/SHEA guidelines as adjunctive therapy in select patients for those with a first or second recurrence of CDI?

Metronidazole

Rifaximin

Vancomycin

Bezlotoxumab

 

For patients being treated for fulminant CDI, their provider should consider adding                       to their regimen, per the ACG guidelines.

 

IV fidaxomicin

IV metronidazole

IV vancomycin

IV rifaximin

 

The IDSA/SHEA guidelines recommend fecal microbiota transplant be used for patients

who have an initial course of nonsevere CDI.

with a first recurrence of CDI in place of fidaxomicin therapy.

with a second recurrence of CDI who received appropriate antibiotics for two or more CDI episodes.

with an intolerance to bezlotoxumab therapy.

Which of the following is an appropriate counseling point pharmacists can provide patients regarding preventing CDI?

Ensure hands are washed properly with soap and water

Begin taking probiotics on a daily basis

Discontinue antibiotic therapies as soon as you begin feeling better

Take shorter courses of antibiotics that are not affordable to save money

References

Centers for Disease Control and Prevention. Antibiotic Resistance in the United States. CDC. 2019. https://ndc.services.cdc.gov/wp- content/uploads/Antibiotic-Resistance-Threats-in-the-United-States- 2019.pdf. Accessed July 16, 2024.

Sucher et al. Updated Clinical Practice Guidelines for C difficile Infection in Adults. US Pharm. 2021;46(12):HS10-HS16

Kelly CR, Fischer M, Allegretti JR, et al. ACG Clinical Guidelines: Prevention, Diagnosis, and Treatment of Clostridioides difficile Infections [published correction appears in Am J Gastroenterol. 2022 Feb 1;117(2):358]. Am J Gastroenterol. 2021;116(6):1124-1147. doi:10.14309/ajg.0000000000001278

Johnson S, Lavergne V, Skinner AM, et al. Clinical Practice Guideline by the Infectious Diseases Society of America (IDSA) and Society for Healthcare Epidemiology of America (SHEA): 2021 Focused Update Guidelines on Management of Clostridioides difficile Infection in Adults. Clin Infect Dis. 2021;73(5):e1029-e1044. doi:10.1093/cid/ciab549

Gerding DN, Johnson S. Clostridioides difficile Infection, Including Pseudomembranous Colitis. In: Loscalzo J, Fauci A, Kasper D, Hauser S, Longo D, Jameson J. eds. Harrison's Principles of Internal Medicine, 21e. McGraw-Hill Education; 2022.

Liu C, Monaghan T, Yadegar A, Louie T, Kao D. Insights into the Evolving Epidemiology of Clostridioides difficile Infection and Treatment: A Global Perspective. Antibiotics (Basel). 2023;12(7):1141. Published 2023 Jul 1. doi:10.3390/antibiotics12071141

Roecker AM, Bates BN. Gastrointestinal Infections and Enterotoxigenic Poisonings. In: DiPiro JT, Yee GC, Haines ST, Nolin TD, Ellingrod VL, Posey L. eds. DiPiro’s Pharmacotherapy: A Pathophysiologic Approach, 12th Edition. McGraw Hill; 2023.

Eze P, Balsells E, Kyaw MH, Nair H. Risk factors for Clostridium difficile infections - an overview of the evidence base and challenges in data synthesis. J Glob Health. 2017;7(1):010417. doi:10.7189/jogh.07.010417

Goldenberg JZ, Yap C, Lytvyn L, et al. Probiotics for the prevention of Clostridium difficile-associated diarrhea in adults and children. Cochrane Database Syst Rev. 2017;12(12):CD006095. Published 2017 Dec 19. doi:10.1002/14651858.CD006095.pub4

McFarland LV, Ship N, Auclair J, Millette M. Primary prevention of Clostridium difficile infections with a specific probiotic combining Lactobacillus acidophilus, L. casei, and L. rhamnosus strains: assessing the evidence. J Hosp Infect. 2018;99(4):443-452. doi:10.1016/j.jhin.2018.04.017

Viggars AP, Gracie DJ, Ford AC. Use of Probiotics in Hospitalized Adults to Prevent Clostridium difficile Infection: DownGRADE the Quality of Evidence?. Gastroenterology. 2017;153(5):1451-1452. doi:10.1053/j.gastro.2017.05.067

Barker AK, Duster M, Valentine S, et al. A randomized controlled trial of probiotics for Clostridium difficile infection in adults (PICO). J Antimicrob Chemother. 2017;72(11):3177-3180. doi:10.1093/jac/dkx254

Surawicz CM, McFarland LV, Greenberg RN, et al. The search for a better treatment for recurrent Clostridium difficile disease: Use of high- dose vancomycin combined with Saccharomyces boulardii. Clin Infect Dis. 2000;31:1012–7.

Louie TJ, Miller MA, Mullane KM, et al. Fidaxomicin versus vancomycin for Clostridium difficile infection. N Engl J Med. 2011;364:422–31.

Gentry CA, Nguyen PK, Thind S, et al. Fidaxomicin versus oral vancomycin for severe Clostridium difficile infection: A retrospective cohort study. Clin Microbiol Infect. 2019;25:987–93.

Nelson RL, Suda KJ, Evans CT. Antibiotic treatment for Clostridium difficile-associated diarrhoea in adults. Cochrane Database Syst Rev. 2017;3:CD004610.

Beinortas T, Burr NE, Wilcox MH, Subramanian V. Comparative efficacy of treatments for Clostridium difficile infection: a systematic review and network meta-analysis. Lancet Infect Dis. 2018;18(9):1035-1044. doi:10.1016/S1473-3099(18)30285-8

Fekety R, Silva J, Kauffman C, et al. Treatment of antibiotic-associated Clostridium difficile colitis with oral vancomycin: Comparison of two dosage regimens. Am J Med. 1989;86:15–9.

Louie TJ, Miller MA, Mullane KM, et al. Fidaxomicin versus vancomycin for Clostridium difficile infection. N Engl J Med. 2011;364(5):422-431. doi:10.1056/NEJMoa0910812

Penziner S, Dubrovskaya Y, Press R, Safdar A. Fidaxomicin therapy in critically ill patients with Clostridium difficile infection. Antimicrob Agents Chemother. 2015;59(3):1776-1781. doi:10.1128/AAC.04268-14

Gentry CA, Nguyen PK, Thind S, Kurdgelashvili G, Skrepnek GH, Williams RJ 2nd. Fidaxomicin versus oral vancomycin for severe Clostridium difficile infection: a retrospective cohort study. Clin Microbiol Infect. 2019;25(8):987-993. doi:10.1016/j.cmi.2018.12.007

Zar FA, Bakkanagari SR, Moorthi KM, Davis MB. A comparison of vancomycin and metronidazole for the treatment of Clostridium difficile- associated diarrhea, stratified by disease severity. Clin Infect Dis. 2007;45(3):302-307. doi:10.1086/519265

Stevens VW, Nelson RE, Schwab-Daugherty EM, et al. Comparative Effectiveness of Vancomycin and Metronidazole for the Prevention of Recurrence and Death in Patients With Clostridium difficile Infection.

JAMA Intern Med. 2017;177(4):546-553.

doi:10.1001/jamainternmed.2016.9045

Kociolek LK, Gerding DN, Carrico R, et al. Strategies to prevent Clostridioides difficile infections in acute-care hospitals: 2022 Update. Infect Control Hosp Epidemiol. 2023;44(4):527-549. doi: 10.1017/ice.2023.18

Bishop PA, Isache C, McCarter YS, Smotherman C, Gautam S, Jankowski CA. Clinical impact of a pharmacist-led antimicrobial stewardship initiative evaluating patients with Clostridioides difficile colitis. J Investig Med. 2020;68(4):888-892. doi:10.1136/jim-2019- 001173

Preston M. Management of Clostridoides Difficile: A Focus on the Pharmacist's Role in the Care Continuum. Pharmacy Times. 2023. https://www.pharmacytimes.com/view/management-of-clostridoides- difficile-a-focus-on-the-pharmacist-s-role-in-the-care-continuum. Accessed July 16, 2024.

 

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