Prevention of Central Line–Associated Bloodstream Infections

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Division of Infectious Diseases, Department of Internal Medicine, VA Ann Arbor Healthcare System and University of Michigan Health System, Ann Arbor, MI.

 

Abstract

  • Objective: To review prevention of central line–associated bloodstream infection (CLABSI).
  • Method: Review of the literature.
  • Results: Evidence-based prevention practices include ensuring hand hygiene before the procedure, using maximal sterile barrier precautions, cleaning the skin with alcoholic chlorhexidine before central line insertion, avoiding the femoral site for insertion, and removing unneeded catheters.
  • Conclusion: For continued success in CLABSI prevention, best practices should be followed and patient safety should be emphasized.

Health care–associated infections (HAIs) are a preventable cause of morbidity and mortality in the United States and internationally. A Centers for Disease Control and Prevention (CDC) report estimates that in acute care hospitals, 1 in 25 patients end up with at least one HAI during their hospital stay [1]. HAIs can also be costly; in the United States, the indirect and direct cost has been estimated to be between $96 to $147 billion dollars [2]. National initiatives to prevent these types of infections have included efforts from the Department of Health and Human Services (HHS), the Institute of Medicine (IOM), the Institute for Healthcare Improvement (IHI) and the Centers for Medicare and Medicaid Services (CMS). This work has led to particular success in preventing central line–associated bloodstream infection (CLABSI).

CLABSI can lead to considerable mortality, morbidity, and cost. An estimated 250,000 CLABSIs occur in patients yearly, and about 80,000 of those are estimated to occur in the intensive care unit (ICU) setting [3]. Since central venous catheters (CVCs), or central lines, are most often used in the ICU setting, much of the work on prevention and management of CLABSI has been within the ICU population [4,5]. The increased use of peripherally inserted central catheters (PICCs) in the non-ICU setting and recognition of CLABSI in non-ICU settings has led to new efforts to understand the best way to prevent CLABSI in the non-ICU setting [4,6]. Regardless of setting, the annual cost of these infections has been estimated to be as high as $2.3 billion [7]. One episode is estimated to cost a hospital up to $46,485 per episode with components of excess length of stay, antibiotic cost, and cost of care [8]. In this review, selected best practices in CLABSI prevention are identified and described.

Elements of CLABSI Prevention

One of the key papers in the CLABSI literature was the Keystone ICU project in Michigan [9]. This state-wide effort grew out of a successful pilot patient-safety program that was trialed at Johns Hopkins Medical Institutions to reduce CLABSI in the ICU setting. In 2003, the Agency for Healthcare Research and Quality (AHRQ) funded a study to examine the intervention in ICUs in the state of Michigan. A total of 108 ICUs from 67 individual hospitals participated in the pre-intervention/post-intervention study [9]. A combination of technical and socio-adaptive interventions to prevent CLABSI included clinician education on best practices in insertion of central lines, having a central-line cart in each ICU, an insertion checklist of best practices, empowering nursing staff to stop the procedure if best practices were not being followed, discussing removal of catheters daily, and providing feedback to units regarding rates of CLABSI [10]. Executive administration of each hospital was also involved and there were monthly phone calls for hospital teams to share successes and barriers.

In the pre-intervention phase, the median catheter- related bloodstream infection rate was 2.7 infections per 1000 catheter days for the sum of hospitals. After the interventions were put in place, the median rate of catheter related bloodstream infections was down to 0.34 at 18 months. The study showed that results from a relatively inexpensive and straightforward intervention could be effective and could last in the long term. This study led to many other single center and multicenter studies, nationally and internationally, to replicate results in efforts to decrease CLABSI in ICU populations [5]. The CDC and AHRQ have continued to partner with regional, state and national efforts to focus on CLABSI prevention.

The Bundle Approach

A number of interventions have been proven to be effective at preventing CLABSI. Combining more than one intervention can often have additive effects. This effect has been recognized in numerous quality improvement studies on CLABSI and has been termed using the “bundle” approach. 

A CVC insertion bundle often uses 3 to 5 interventions together. The Keystone study used a bundled approach and many patient safety interventions employ this approach to improve patient care processes [11]. The IHI’s “central line bundle” is shown in the Table.

 

 

Hand Hygiene

Poor hand hygiene by health care workers is generally thought to be the most common cause of HAIs [12]. Guidelines recommend an alcohol-based waterless product or antiseptic soap and water prior to catheter insertion [13]. The most common underlying etiology of CLABSI is through microorganisms introduced at time of insertion of catheter. This can be extraluminally mediated via skin flora of the patient, or due to lack of hand washing on the inserter’s part and can lead to CLABSI [14]. While a randomized controlled trial would be unethical, several studies have shown when targeted hand hygiene campaigns are held, CLABSI rates tend to decrease [15–17].

Maximal Barrier Precautions

The use of maximal sterile barrier precautions has been associated with less mortality, decreasing catheter colonization, incidence of HAI and cost savings [18–20]. Like most components of the bundle, maximal sterile barrier precautions have rarely been studied alone, but are often a part of a “bundle” or number of interventions [21]. Like hand hygiene, while regularly a part of many hospital’s checklist or bundle process, compliance with this key part of infection prevention can be deficient; one study noted measured maximal sterile barriers compliance to be 44% [22].

Chlorhexidine Skin Antisepsis

Chlorhexidine skin preparation decreases bacterial burden at site of insertion and is thought to reduce infection from this mechanism. Chlorhexidine-alcohol skin preparation has been proven in randomized controlled trials to outperform povidone iodine-alcohol in preventing CLABSI [23,24]. Chlorhexidine skin preparation is considered a technical element of checklists and is thought to be a straightforward and easily implementable action [25]. If a hospital supplies only alcoholic chlorhexidine and doesn’t provide povidone-iodine for skin preparation, then clinicians can be “nudged” towards performing this part of the bundle.

Optimal Catheter Site Selection

For all sites of insertion of CVC, the risk of mechanical and infectious complications depends on the skill and proficiency of operators, the clinical situation, and the availability of ultrasound to help guide placement. These factors are important in determining which anatomical site is best for each patient [26]. The femoral site has been associated with a greater risk of catheter-related infection and catheter-related thrombosis and is not recommended as the initial choice for non-emergent CVC insertion according to national guidelines [13,27]. The internal jugular vein site is associated with a lower risk of severe mechanical complications such as pneumothorax when compared to subclavian vein site [27]. The subclavian vein site is associated with a lower risk of catheter-related blood stream infection and lower rate of thrombosis, but this greatly depends on experience of operator. Experts have proposed that the subclavian site has a lower burden of colonization by bacteria than other sites and is anatomically more protected by catheter dressing; also the subcutaneous course of the central line itself is longer for the subclavian site than other sites and these reasons could contribute to the lower risk of infection [28]. The subclavian site is, however, associated with a higher risk of mechanical complications that can be serious for ICU patients. In general, the femoral vein site should be avoided in non-emergent line placement situations, particularly if the patient is an obese adult [13]. Using ultrasound as a guidance for catheter insertion has also been shown to reduce risk of CLABSI and other mechanical complications and is recommended [29,30].

Daily Review of Line Necessity

Removing unnecessary catheters as soon as possible decreases catheter dwell time and risk of infection. Few studies have concentrated on this step alone in CLABSI prevention, but the studies that have focused on catheter removal usually implement electronic reminders or multidisciplinary catheter rounds (where need for catheter is incorporated into daily rounds or discussed separately by a multidisciplinary group) [5,31].

Additional Considerations

Other basic practices that all hospitals should adopt include the above strategies and providing all inclusive catheter carts or kits, disinfecting hubs in maintenance care of catheters, covering the CVC site with sterile dressings, having recurrent educational interventions and using checklists to assure adherence to the evidence-based bundle (Table) [4,13]. As prevalence of non-ICU central lines has also grown, maintenance care is particularly important in reducing CLABSI. Maintenance bundles that highlight best practices such as aseptic technique, correct hand hygiene, chlorhexidine skin disinfection scrub, antimicrobial bandage application, and catheter hub disinfection have been used with success [32]. Specialized CVC insertion teams with trained personnel have also been recommended [4]. When these basic evidence-based practices are still unable to bring down CLABSI rates for select populations or during an outbreak, supplemental strategies can be tried to reduce CLABSI. These include antimicrobial-impregnated catheters, chlorhexidine-impregnated dressings, and chlorhexidine bathing, which is increasingly being used in the ICU setting [5,13,33].

 

 

Epidemiology/Risk Factors

At-risk Populations

ICU patients are at risk for CLABSI because of frequent use of multiple catheters, and the comorbidities and acuity of care that these patients have. ICU patients also tend to have lots of manipulation of their catheters and often these catheters are placed in emergent situations [13]. Patients in the non-ICU and outpatient setting are also at risk for CLABSI when they have a central venous catheter. Long courses of antibiotics for disease states such as osteomyelitis and endocarditis often entail central venous catheters. Recent work has shown that PICCs carry as high of a CLABSI risk as short-term CVCs in hospitalized patients [34]. Patients with end-stage renal disease, especially those undergoing maintenance hemodialysis via a tunneled dialysis catheter are particularly vulnerable to CLABSI [13,35].

Risk Factors for CLABSI

A number of studies have reviewed risk factors and epidemiology of CLABSI in the adult and pediatric population. Factors that have been associated with risk of CLABSI in more than one study include prolonged hospitalization before placement of the central line, prolonged duration of the central line, heavy microbial colonization at the site of insertion, heavy microbial colonization of the catheter hub, multiple lumens, internal jugular site catheterization, femoral vein site catheterization, neutropenia of the patient, a reduced nurse to patient ratio in the ICU setting, presence of total parenteral nutrition, and poor maintenance care of the catheter [4,13,36–40]. One study [41] that calculated a score to help predict risk of PICC-CLABSI found that previous CLABSI (within 3 months of PICC insertion) significantly increases risk of repeat CLABSI.

Conclusion

CLABSI is an important cause of morbidity, mortality and cost. There has been remarkable success in prevention of these infections in recent years due to focused efforts on patient safety. As efforts have multiplied to put into place interventions to decrease CLABSI nationally, the CDC published a Vital Signs report discussing the impact of these efforts [42]. It was estimated that over one decade, infection prevention efforts had avoided 25,000 CLABSIs in U.S. ICUs, a 58% reduction in this infection [42]. CLABSI has served as the best example of using evidence-based interventions through an infection prevention bundle or framework to reduce HAIs. Similar approaches are being used to try to reduce catheter-associated urinary tract infection, Clostridium difficile infection, surgical site infection, and ventilator-associated pneumonia, but there have been less distinct successes nationally and internationally for these other HAIs.

The literature emphasizes that there are several evidence-based measures that can prevent CLABSI. These include hand hygiene, using alcoholic chlorhexidine for skin preparation prior to insertion, maximal sterile barrier precautions, avoiding the femoral site for CVC insertion, and removing unnecessary catheters as soon as possible. Support from administration in emphasizing patient safety and HAI prevention along with following evidence-based practice could lead to long-term improvement in CLABSI prevention across hospital systems.

Corresponding author: Payal K. Patel, MD, MPH, Div of Infectious Diseases, Dept of Internal Medicine, VA Ann Arbor Healthcare System, 2215 Fuller Rd, Ann Arbor, MI 48105, [email protected].

Financial disclosures: None.

References

1. Magill SS, Edwards JR, Bamberg W, et al; Emerging Infections Program Healthcare-Associated Infections and Antimicrobial Use Prevalence Survey Team. Multistate point-prevalence survey of health care-associated infections. N Engl J Med 2014;370:1198–208.

2. Marchetti A, Rossiter R. Economic burden of healthcare-associated infection in US acute care hospitals: societal perspective. J Med Econ 2013;16:1399–404.

3. O’Neil C, Ball K, Wood H, et al. A central line care maintenance bundle for the prevention of central line-associated bloodstream infection in non-intensive care unit settings. Infect Control Hosp Epidemiol 2016;37:1–7.

4. Shekelle PG, Wachter RM, Pronovost PJ, et al. Making health care safer II: an updated critical analysis of the evidence for patient safety practices. Evid Rep Technol Assess (Full Rep) 2013:1–945.

5. Patel PK, Gupta A, Vaughn VM, Mann JD, Ameling JM, Meddings J. Review of strategies to reduce central line-associated bloodstream infection (CLABSI) and catheter-associated urinary tract infection (CAUTI) in adult ICUs. J Hosp Med 2018;13:105–16.

6. Chopra V, Ratz D, Kuhn L, et al. PICC-associated bloodstream infections: prevalence, patterns, and predictors. Am J Med 2014;127:319–28.

7. Sagana R, Hyzy RC. Achieving zero central line-associated bloodstream infection rates in your intensive care unit. Crit Care Clin 2013;29:1–9.

8. Nelson RE, Angelovic AW, Nelson SD, Gleed JR, Drews FA. An economic analysis of adherence engineering to improve use of best practices during central line maintenance procedures. Infect Control Hosp Epidemiol 2015;36:550–6.

9. Pronovost P, Needham D, Berenholtz S, et al. An intervention to decrease catheter-related bloodstream infections in the ICU. N Engl J Med 2006;355:2725–32.

10. Dumyati G, Concannon C, van Wijngaarden E, et al. Sustained reduction of central line-associated bloodstream infections outside the intensive care unit with a multimodal intervention focusing on central line maintenance. Am J Infect Control 2014;42:723–30.

11. Sacks GD, Diggs BS, Hadjizacharia P, et al. Reducing the rate of catheter-associated bloodstream infections in a surgical intensive care unit using the Institute for Healthcare Improvement Central Line Bundle. Am J Surg 2014;207:817–23.

12. Boyce JM, Pittet D; Healthcare Infection Control Practices Advisory Committee; HICPAC/SHEA/APIC/IDSA Hand Hygiene Task Force. Guideline for hand hygiene in health-care settings: recommendations of the Healthcare Infection Control Practices Advisory Committee and the HICPAC/SHEA/APIC/IDSA Hand Hygiene Task Force. Society for Healthcare Epidemiology of America/Association for Professionals in Infection Control/Infectious Diseases Society of America. MMWR Recomm Rep 2002; 51:1-45, quiz CE1–4.

13. Marschall J, Mermel LA, et al; Society for Healthcare Epidemiology of America. Strategies to prevent central line-associated bloodstream infections in acute care hospitals: 2014 update. Infect Control Hosp Epidemiol 2014;35:753–71.

14. Safdar N, Maki DG. The pathogenesis of catheter-related bloodstream infection with noncuffed short-term central venous catheters. Intensive Care Med 2004;30:62–7.

15. Shabot MM, Chassin MR, France AC, et al. Using the targeted solutions tool(R) to improve hand hygiene compliance is associated with decreased health care-associated infections. Jt Comm J Qual Patient Saf 2016;42:6–17.

16. Johnson L, Grueber S, Schlotzhauer C, et al. A multifactorial action plan improves hand hygiene adherence and significantly reduces central line-associated bloodstream infections. Am J Infect Control 2014;42:1146–51.

17. Barrera L, Zingg W, Mendez F, Pittet D. Effectiveness of a hand hygiene promotion strategy using alcohol-based handrub in 6 intensive care units in Colombia. Am J Infect Control 2011;39:633–9.

18. Hu KK, Lipsky BA, Veenstra DL, Saint S. Using maximal sterile barriers to prevent central venous catheter-related infection: a systematic evidence-based review. Am J Infect Control 2004;32:142–6.

19. Hu KK, Veenstra DL, Lipsky BA, Saint S. Use of maximal sterile barriers during central venous catheter insertion: clinical and economic outcomes. Clin Infect Dis 2004;39:1441–5.

20. Raad II, Hohn DC, Gilbreath BJ, et al. Prevention of central venous catheter-related infections by using maximal sterile barrier precautions during insertion. Infect Control Hosp Epidemiol 1994;15:231–8.

21. Furuya EY, Dick AW, Herzig CT, Pogorzelska-Maziarz M, Larson EL, Stone PW. Central line-associated bloodstream infection reduction and bundle compliance in intensive care units: a national study. Infect Control Hosp Epidemiol 2016;37:805–10.

22. Sherertz RJ, Ely EW, Westbrook DM, et al. Education of physicians-in-training can decrease the risk for vascular catheter infection. Ann Intern Med 2000;132:641–8.

23. Mimoz O, Lucet JC, Kerforne T, Pascal J, et al. Skin antisepsis with chlorhexidine-alcohol versus povidone iodine-alcohol, with and without skin scrubbing, for prevention of intravascular-catheter-related infection (CLEAN): an open-label, multicentre, randomised, controlled, two-by-two factorial trial. Lancet 2015;386:2069–77.

24. Lai NM, Lai NA, O’Riordan E, et al. Skin antisepsis for reducing central venous catheter-related infections. Cochrane Database Syst Rev 2016;7:CD010140.

25. Chopra V, Shojania KG. Recipes for checklists and bundles: one part active ingredient, two parts measurement. BMJ Qual Saf 2013;22:93–6.

26. Marik PE, Flemmer M, Harrison W. The risk of catheter-related bloodstream infection with femoral venous catheters as compared to subclavian and internal jugular venous catheters: a systematic review of the literature and meta-analysis. Crit Care Med 2012;40:2479–85.

27. Timsit JF. What is the best site for central venous catheter insertion in critically ill patients? Crit Care 2003;7:397–99.

28. Parienti JJ, Mongardon N, Megarbane B, et al; 3SITES Study Group. Intravascular complications of central venous catheterization by insertion site. N Engl J Med 2015;373:1220–9.

29. Hind D, Calvert N, McWilliams R, et al. Ultrasonic locating devices for central venous cannulation: meta-analysis. BMJ 2003;327:361.

30. Fragou M, Gravvanis A, Dimitriou V, et al. Real-time ultrasound-guided subclavian vein cannulation versus the landmark method in critical care patients: a prospective randomized study. Crit Care Med 2011;39:1607–12.

31. Pageler NM, Longhurst CA, Wood M, et al. Use of electronic medical record-enhanced checklist and electronic dashboard to decrease CLABSIs. Pediatrics 2014;133:e738–46.

32. Drews FA, Bakdash JZ, Gleed JR. Improving central line maintenance to reduce central line-associated bloodstream infections. Am J Infect Control 2017;45:1224–30.

33. Frost SA, Alogso MC, Metcalfe L, et al. Chlorhexidine bathing and health care-associated infections among adult intensive care patients: a systematic review and meta-analysis. Crit Care 2016;20:379.

34. Chopra V, O’Horo JC, Rogers MA, et al. The risk of bloodstream infection associated with peripherally inserted central catheters compared with central venous catheters in adults: a systematic review and meta-analysis. Infect Control Hosp Epidemiol 2013;34:908–18.

35. Xue H, Ix JH, Wang W, et al. Hemodialysis access usage patterns in the incident dialysis year and associated catheter-related complications. Am J Kidney Dis 2013;61:123–30.

36. Almuneef MA, Memish ZA, Balkhy HH, et al. Rate, risk factors and outcomes of catheter-related bloodstream infection in a paediatric intensive care unit in Saudi Arabia. J Hosp Infect 2006;62:207–13.

37. Alonso-Echanove J, Edwards JR, Richards MJ, et al. Effect of nurse staffing and antimicrobial-impregnated central venous catheters on the risk for bloodstream infections in intensive care units. Infect Control Hosp Epidemiol 2003;24:916–25.

38. Lorente L, Henry C, Martin MM, et al. Central venous catheter-related infection in a prospective and observational study of 2,595 catheters. Crit Care 2005;9:R631–5.

39. Rey C, Alvarez F, De-La-Rua V, et al. Intervention to reduce catheter-related bloodstream infections in a pediatric intensive care unit. Intensive Care Med 2011;37:678–85.

40. O’Brien J, Paquet F, Lindsay R, Valenti D. Insertion of PICCs with minimum number of lumens reduces complications and costs. J Am Coll Radiol. 2013;10:864–8.

41. Herc E, Patel P, Washer LL, et al. A model to predict central-line-associated bloodstream infection among patients with peripherally inserted central catheters: the MPC score. Infect Control Hosp Epidemiol 2017;38:1155–66.

42. Centers for Disease Control and Prevention. Vital signs: central line-associated blood stream infections--United States, 2001, 2008, and 2009. MMWR Morb Mortal Wkly Rep 2011;60:243–8.

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Division of Infectious Diseases, Department of Internal Medicine, VA Ann Arbor Healthcare System and University of Michigan Health System, Ann Arbor, MI.

 

Abstract

  • Objective: To review prevention of central line–associated bloodstream infection (CLABSI).
  • Method: Review of the literature.
  • Results: Evidence-based prevention practices include ensuring hand hygiene before the procedure, using maximal sterile barrier precautions, cleaning the skin with alcoholic chlorhexidine before central line insertion, avoiding the femoral site for insertion, and removing unneeded catheters.
  • Conclusion: For continued success in CLABSI prevention, best practices should be followed and patient safety should be emphasized.

Health care–associated infections (HAIs) are a preventable cause of morbidity and mortality in the United States and internationally. A Centers for Disease Control and Prevention (CDC) report estimates that in acute care hospitals, 1 in 25 patients end up with at least one HAI during their hospital stay [1]. HAIs can also be costly; in the United States, the indirect and direct cost has been estimated to be between $96 to $147 billion dollars [2]. National initiatives to prevent these types of infections have included efforts from the Department of Health and Human Services (HHS), the Institute of Medicine (IOM), the Institute for Healthcare Improvement (IHI) and the Centers for Medicare and Medicaid Services (CMS). This work has led to particular success in preventing central line–associated bloodstream infection (CLABSI).

CLABSI can lead to considerable mortality, morbidity, and cost. An estimated 250,000 CLABSIs occur in patients yearly, and about 80,000 of those are estimated to occur in the intensive care unit (ICU) setting [3]. Since central venous catheters (CVCs), or central lines, are most often used in the ICU setting, much of the work on prevention and management of CLABSI has been within the ICU population [4,5]. The increased use of peripherally inserted central catheters (PICCs) in the non-ICU setting and recognition of CLABSI in non-ICU settings has led to new efforts to understand the best way to prevent CLABSI in the non-ICU setting [4,6]. Regardless of setting, the annual cost of these infections has been estimated to be as high as $2.3 billion [7]. One episode is estimated to cost a hospital up to $46,485 per episode with components of excess length of stay, antibiotic cost, and cost of care [8]. In this review, selected best practices in CLABSI prevention are identified and described.

Elements of CLABSI Prevention

One of the key papers in the CLABSI literature was the Keystone ICU project in Michigan [9]. This state-wide effort grew out of a successful pilot patient-safety program that was trialed at Johns Hopkins Medical Institutions to reduce CLABSI in the ICU setting. In 2003, the Agency for Healthcare Research and Quality (AHRQ) funded a study to examine the intervention in ICUs in the state of Michigan. A total of 108 ICUs from 67 individual hospitals participated in the pre-intervention/post-intervention study [9]. A combination of technical and socio-adaptive interventions to prevent CLABSI included clinician education on best practices in insertion of central lines, having a central-line cart in each ICU, an insertion checklist of best practices, empowering nursing staff to stop the procedure if best practices were not being followed, discussing removal of catheters daily, and providing feedback to units regarding rates of CLABSI [10]. Executive administration of each hospital was also involved and there were monthly phone calls for hospital teams to share successes and barriers.

In the pre-intervention phase, the median catheter- related bloodstream infection rate was 2.7 infections per 1000 catheter days for the sum of hospitals. After the interventions were put in place, the median rate of catheter related bloodstream infections was down to 0.34 at 18 months. The study showed that results from a relatively inexpensive and straightforward intervention could be effective and could last in the long term. This study led to many other single center and multicenter studies, nationally and internationally, to replicate results in efforts to decrease CLABSI in ICU populations [5]. The CDC and AHRQ have continued to partner with regional, state and national efforts to focus on CLABSI prevention.

The Bundle Approach

A number of interventions have been proven to be effective at preventing CLABSI. Combining more than one intervention can often have additive effects. This effect has been recognized in numerous quality improvement studies on CLABSI and has been termed using the “bundle” approach. 

A CVC insertion bundle often uses 3 to 5 interventions together. The Keystone study used a bundled approach and many patient safety interventions employ this approach to improve patient care processes [11]. The IHI’s “central line bundle” is shown in the Table.

 

 

Hand Hygiene

Poor hand hygiene by health care workers is generally thought to be the most common cause of HAIs [12]. Guidelines recommend an alcohol-based waterless product or antiseptic soap and water prior to catheter insertion [13]. The most common underlying etiology of CLABSI is through microorganisms introduced at time of insertion of catheter. This can be extraluminally mediated via skin flora of the patient, or due to lack of hand washing on the inserter’s part and can lead to CLABSI [14]. While a randomized controlled trial would be unethical, several studies have shown when targeted hand hygiene campaigns are held, CLABSI rates tend to decrease [15–17].

Maximal Barrier Precautions

The use of maximal sterile barrier precautions has been associated with less mortality, decreasing catheter colonization, incidence of HAI and cost savings [18–20]. Like most components of the bundle, maximal sterile barrier precautions have rarely been studied alone, but are often a part of a “bundle” or number of interventions [21]. Like hand hygiene, while regularly a part of many hospital’s checklist or bundle process, compliance with this key part of infection prevention can be deficient; one study noted measured maximal sterile barriers compliance to be 44% [22].

Chlorhexidine Skin Antisepsis

Chlorhexidine skin preparation decreases bacterial burden at site of insertion and is thought to reduce infection from this mechanism. Chlorhexidine-alcohol skin preparation has been proven in randomized controlled trials to outperform povidone iodine-alcohol in preventing CLABSI [23,24]. Chlorhexidine skin preparation is considered a technical element of checklists and is thought to be a straightforward and easily implementable action [25]. If a hospital supplies only alcoholic chlorhexidine and doesn’t provide povidone-iodine for skin preparation, then clinicians can be “nudged” towards performing this part of the bundle.

Optimal Catheter Site Selection

For all sites of insertion of CVC, the risk of mechanical and infectious complications depends on the skill and proficiency of operators, the clinical situation, and the availability of ultrasound to help guide placement. These factors are important in determining which anatomical site is best for each patient [26]. The femoral site has been associated with a greater risk of catheter-related infection and catheter-related thrombosis and is not recommended as the initial choice for non-emergent CVC insertion according to national guidelines [13,27]. The internal jugular vein site is associated with a lower risk of severe mechanical complications such as pneumothorax when compared to subclavian vein site [27]. The subclavian vein site is associated with a lower risk of catheter-related blood stream infection and lower rate of thrombosis, but this greatly depends on experience of operator. Experts have proposed that the subclavian site has a lower burden of colonization by bacteria than other sites and is anatomically more protected by catheter dressing; also the subcutaneous course of the central line itself is longer for the subclavian site than other sites and these reasons could contribute to the lower risk of infection [28]. The subclavian site is, however, associated with a higher risk of mechanical complications that can be serious for ICU patients. In general, the femoral vein site should be avoided in non-emergent line placement situations, particularly if the patient is an obese adult [13]. Using ultrasound as a guidance for catheter insertion has also been shown to reduce risk of CLABSI and other mechanical complications and is recommended [29,30].

Daily Review of Line Necessity

Removing unnecessary catheters as soon as possible decreases catheter dwell time and risk of infection. Few studies have concentrated on this step alone in CLABSI prevention, but the studies that have focused on catheter removal usually implement electronic reminders or multidisciplinary catheter rounds (where need for catheter is incorporated into daily rounds or discussed separately by a multidisciplinary group) [5,31].

Additional Considerations

Other basic practices that all hospitals should adopt include the above strategies and providing all inclusive catheter carts or kits, disinfecting hubs in maintenance care of catheters, covering the CVC site with sterile dressings, having recurrent educational interventions and using checklists to assure adherence to the evidence-based bundle (Table) [4,13]. As prevalence of non-ICU central lines has also grown, maintenance care is particularly important in reducing CLABSI. Maintenance bundles that highlight best practices such as aseptic technique, correct hand hygiene, chlorhexidine skin disinfection scrub, antimicrobial bandage application, and catheter hub disinfection have been used with success [32]. Specialized CVC insertion teams with trained personnel have also been recommended [4]. When these basic evidence-based practices are still unable to bring down CLABSI rates for select populations or during an outbreak, supplemental strategies can be tried to reduce CLABSI. These include antimicrobial-impregnated catheters, chlorhexidine-impregnated dressings, and chlorhexidine bathing, which is increasingly being used in the ICU setting [5,13,33].

 

 

Epidemiology/Risk Factors

At-risk Populations

ICU patients are at risk for CLABSI because of frequent use of multiple catheters, and the comorbidities and acuity of care that these patients have. ICU patients also tend to have lots of manipulation of their catheters and often these catheters are placed in emergent situations [13]. Patients in the non-ICU and outpatient setting are also at risk for CLABSI when they have a central venous catheter. Long courses of antibiotics for disease states such as osteomyelitis and endocarditis often entail central venous catheters. Recent work has shown that PICCs carry as high of a CLABSI risk as short-term CVCs in hospitalized patients [34]. Patients with end-stage renal disease, especially those undergoing maintenance hemodialysis via a tunneled dialysis catheter are particularly vulnerable to CLABSI [13,35].

Risk Factors for CLABSI

A number of studies have reviewed risk factors and epidemiology of CLABSI in the adult and pediatric population. Factors that have been associated with risk of CLABSI in more than one study include prolonged hospitalization before placement of the central line, prolonged duration of the central line, heavy microbial colonization at the site of insertion, heavy microbial colonization of the catheter hub, multiple lumens, internal jugular site catheterization, femoral vein site catheterization, neutropenia of the patient, a reduced nurse to patient ratio in the ICU setting, presence of total parenteral nutrition, and poor maintenance care of the catheter [4,13,36–40]. One study [41] that calculated a score to help predict risk of PICC-CLABSI found that previous CLABSI (within 3 months of PICC insertion) significantly increases risk of repeat CLABSI.

Conclusion

CLABSI is an important cause of morbidity, mortality and cost. There has been remarkable success in prevention of these infections in recent years due to focused efforts on patient safety. As efforts have multiplied to put into place interventions to decrease CLABSI nationally, the CDC published a Vital Signs report discussing the impact of these efforts [42]. It was estimated that over one decade, infection prevention efforts had avoided 25,000 CLABSIs in U.S. ICUs, a 58% reduction in this infection [42]. CLABSI has served as the best example of using evidence-based interventions through an infection prevention bundle or framework to reduce HAIs. Similar approaches are being used to try to reduce catheter-associated urinary tract infection, Clostridium difficile infection, surgical site infection, and ventilator-associated pneumonia, but there have been less distinct successes nationally and internationally for these other HAIs.

The literature emphasizes that there are several evidence-based measures that can prevent CLABSI. These include hand hygiene, using alcoholic chlorhexidine for skin preparation prior to insertion, maximal sterile barrier precautions, avoiding the femoral site for CVC insertion, and removing unnecessary catheters as soon as possible. Support from administration in emphasizing patient safety and HAI prevention along with following evidence-based practice could lead to long-term improvement in CLABSI prevention across hospital systems.

Corresponding author: Payal K. Patel, MD, MPH, Div of Infectious Diseases, Dept of Internal Medicine, VA Ann Arbor Healthcare System, 2215 Fuller Rd, Ann Arbor, MI 48105, [email protected].

Financial disclosures: None.

Division of Infectious Diseases, Department of Internal Medicine, VA Ann Arbor Healthcare System and University of Michigan Health System, Ann Arbor, MI.

 

Abstract

  • Objective: To review prevention of central line–associated bloodstream infection (CLABSI).
  • Method: Review of the literature.
  • Results: Evidence-based prevention practices include ensuring hand hygiene before the procedure, using maximal sterile barrier precautions, cleaning the skin with alcoholic chlorhexidine before central line insertion, avoiding the femoral site for insertion, and removing unneeded catheters.
  • Conclusion: For continued success in CLABSI prevention, best practices should be followed and patient safety should be emphasized.

Health care–associated infections (HAIs) are a preventable cause of morbidity and mortality in the United States and internationally. A Centers for Disease Control and Prevention (CDC) report estimates that in acute care hospitals, 1 in 25 patients end up with at least one HAI during their hospital stay [1]. HAIs can also be costly; in the United States, the indirect and direct cost has been estimated to be between $96 to $147 billion dollars [2]. National initiatives to prevent these types of infections have included efforts from the Department of Health and Human Services (HHS), the Institute of Medicine (IOM), the Institute for Healthcare Improvement (IHI) and the Centers for Medicare and Medicaid Services (CMS). This work has led to particular success in preventing central line–associated bloodstream infection (CLABSI).

CLABSI can lead to considerable mortality, morbidity, and cost. An estimated 250,000 CLABSIs occur in patients yearly, and about 80,000 of those are estimated to occur in the intensive care unit (ICU) setting [3]. Since central venous catheters (CVCs), or central lines, are most often used in the ICU setting, much of the work on prevention and management of CLABSI has been within the ICU population [4,5]. The increased use of peripherally inserted central catheters (PICCs) in the non-ICU setting and recognition of CLABSI in non-ICU settings has led to new efforts to understand the best way to prevent CLABSI in the non-ICU setting [4,6]. Regardless of setting, the annual cost of these infections has been estimated to be as high as $2.3 billion [7]. One episode is estimated to cost a hospital up to $46,485 per episode with components of excess length of stay, antibiotic cost, and cost of care [8]. In this review, selected best practices in CLABSI prevention are identified and described.

Elements of CLABSI Prevention

One of the key papers in the CLABSI literature was the Keystone ICU project in Michigan [9]. This state-wide effort grew out of a successful pilot patient-safety program that was trialed at Johns Hopkins Medical Institutions to reduce CLABSI in the ICU setting. In 2003, the Agency for Healthcare Research and Quality (AHRQ) funded a study to examine the intervention in ICUs in the state of Michigan. A total of 108 ICUs from 67 individual hospitals participated in the pre-intervention/post-intervention study [9]. A combination of technical and socio-adaptive interventions to prevent CLABSI included clinician education on best practices in insertion of central lines, having a central-line cart in each ICU, an insertion checklist of best practices, empowering nursing staff to stop the procedure if best practices were not being followed, discussing removal of catheters daily, and providing feedback to units regarding rates of CLABSI [10]. Executive administration of each hospital was also involved and there were monthly phone calls for hospital teams to share successes and barriers.

In the pre-intervention phase, the median catheter- related bloodstream infection rate was 2.7 infections per 1000 catheter days for the sum of hospitals. After the interventions were put in place, the median rate of catheter related bloodstream infections was down to 0.34 at 18 months. The study showed that results from a relatively inexpensive and straightforward intervention could be effective and could last in the long term. This study led to many other single center and multicenter studies, nationally and internationally, to replicate results in efforts to decrease CLABSI in ICU populations [5]. The CDC and AHRQ have continued to partner with regional, state and national efforts to focus on CLABSI prevention.

The Bundle Approach

A number of interventions have been proven to be effective at preventing CLABSI. Combining more than one intervention can often have additive effects. This effect has been recognized in numerous quality improvement studies on CLABSI and has been termed using the “bundle” approach. 

A CVC insertion bundle often uses 3 to 5 interventions together. The Keystone study used a bundled approach and many patient safety interventions employ this approach to improve patient care processes [11]. The IHI’s “central line bundle” is shown in the Table.

 

 

Hand Hygiene

Poor hand hygiene by health care workers is generally thought to be the most common cause of HAIs [12]. Guidelines recommend an alcohol-based waterless product or antiseptic soap and water prior to catheter insertion [13]. The most common underlying etiology of CLABSI is through microorganisms introduced at time of insertion of catheter. This can be extraluminally mediated via skin flora of the patient, or due to lack of hand washing on the inserter’s part and can lead to CLABSI [14]. While a randomized controlled trial would be unethical, several studies have shown when targeted hand hygiene campaigns are held, CLABSI rates tend to decrease [15–17].

Maximal Barrier Precautions

The use of maximal sterile barrier precautions has been associated with less mortality, decreasing catheter colonization, incidence of HAI and cost savings [18–20]. Like most components of the bundle, maximal sterile barrier precautions have rarely been studied alone, but are often a part of a “bundle” or number of interventions [21]. Like hand hygiene, while regularly a part of many hospital’s checklist or bundle process, compliance with this key part of infection prevention can be deficient; one study noted measured maximal sterile barriers compliance to be 44% [22].

Chlorhexidine Skin Antisepsis

Chlorhexidine skin preparation decreases bacterial burden at site of insertion and is thought to reduce infection from this mechanism. Chlorhexidine-alcohol skin preparation has been proven in randomized controlled trials to outperform povidone iodine-alcohol in preventing CLABSI [23,24]. Chlorhexidine skin preparation is considered a technical element of checklists and is thought to be a straightforward and easily implementable action [25]. If a hospital supplies only alcoholic chlorhexidine and doesn’t provide povidone-iodine for skin preparation, then clinicians can be “nudged” towards performing this part of the bundle.

Optimal Catheter Site Selection

For all sites of insertion of CVC, the risk of mechanical and infectious complications depends on the skill and proficiency of operators, the clinical situation, and the availability of ultrasound to help guide placement. These factors are important in determining which anatomical site is best for each patient [26]. The femoral site has been associated with a greater risk of catheter-related infection and catheter-related thrombosis and is not recommended as the initial choice for non-emergent CVC insertion according to national guidelines [13,27]. The internal jugular vein site is associated with a lower risk of severe mechanical complications such as pneumothorax when compared to subclavian vein site [27]. The subclavian vein site is associated with a lower risk of catheter-related blood stream infection and lower rate of thrombosis, but this greatly depends on experience of operator. Experts have proposed that the subclavian site has a lower burden of colonization by bacteria than other sites and is anatomically more protected by catheter dressing; also the subcutaneous course of the central line itself is longer for the subclavian site than other sites and these reasons could contribute to the lower risk of infection [28]. The subclavian site is, however, associated with a higher risk of mechanical complications that can be serious for ICU patients. In general, the femoral vein site should be avoided in non-emergent line placement situations, particularly if the patient is an obese adult [13]. Using ultrasound as a guidance for catheter insertion has also been shown to reduce risk of CLABSI and other mechanical complications and is recommended [29,30].

Daily Review of Line Necessity

Removing unnecessary catheters as soon as possible decreases catheter dwell time and risk of infection. Few studies have concentrated on this step alone in CLABSI prevention, but the studies that have focused on catheter removal usually implement electronic reminders or multidisciplinary catheter rounds (where need for catheter is incorporated into daily rounds or discussed separately by a multidisciplinary group) [5,31].

Additional Considerations

Other basic practices that all hospitals should adopt include the above strategies and providing all inclusive catheter carts or kits, disinfecting hubs in maintenance care of catheters, covering the CVC site with sterile dressings, having recurrent educational interventions and using checklists to assure adherence to the evidence-based bundle (Table) [4,13]. As prevalence of non-ICU central lines has also grown, maintenance care is particularly important in reducing CLABSI. Maintenance bundles that highlight best practices such as aseptic technique, correct hand hygiene, chlorhexidine skin disinfection scrub, antimicrobial bandage application, and catheter hub disinfection have been used with success [32]. Specialized CVC insertion teams with trained personnel have also been recommended [4]. When these basic evidence-based practices are still unable to bring down CLABSI rates for select populations or during an outbreak, supplemental strategies can be tried to reduce CLABSI. These include antimicrobial-impregnated catheters, chlorhexidine-impregnated dressings, and chlorhexidine bathing, which is increasingly being used in the ICU setting [5,13,33].

 

 

Epidemiology/Risk Factors

At-risk Populations

ICU patients are at risk for CLABSI because of frequent use of multiple catheters, and the comorbidities and acuity of care that these patients have. ICU patients also tend to have lots of manipulation of their catheters and often these catheters are placed in emergent situations [13]. Patients in the non-ICU and outpatient setting are also at risk for CLABSI when they have a central venous catheter. Long courses of antibiotics for disease states such as osteomyelitis and endocarditis often entail central venous catheters. Recent work has shown that PICCs carry as high of a CLABSI risk as short-term CVCs in hospitalized patients [34]. Patients with end-stage renal disease, especially those undergoing maintenance hemodialysis via a tunneled dialysis catheter are particularly vulnerable to CLABSI [13,35].

Risk Factors for CLABSI

A number of studies have reviewed risk factors and epidemiology of CLABSI in the adult and pediatric population. Factors that have been associated with risk of CLABSI in more than one study include prolonged hospitalization before placement of the central line, prolonged duration of the central line, heavy microbial colonization at the site of insertion, heavy microbial colonization of the catheter hub, multiple lumens, internal jugular site catheterization, femoral vein site catheterization, neutropenia of the patient, a reduced nurse to patient ratio in the ICU setting, presence of total parenteral nutrition, and poor maintenance care of the catheter [4,13,36–40]. One study [41] that calculated a score to help predict risk of PICC-CLABSI found that previous CLABSI (within 3 months of PICC insertion) significantly increases risk of repeat CLABSI.

Conclusion

CLABSI is an important cause of morbidity, mortality and cost. There has been remarkable success in prevention of these infections in recent years due to focused efforts on patient safety. As efforts have multiplied to put into place interventions to decrease CLABSI nationally, the CDC published a Vital Signs report discussing the impact of these efforts [42]. It was estimated that over one decade, infection prevention efforts had avoided 25,000 CLABSIs in U.S. ICUs, a 58% reduction in this infection [42]. CLABSI has served as the best example of using evidence-based interventions through an infection prevention bundle or framework to reduce HAIs. Similar approaches are being used to try to reduce catheter-associated urinary tract infection, Clostridium difficile infection, surgical site infection, and ventilator-associated pneumonia, but there have been less distinct successes nationally and internationally for these other HAIs.

The literature emphasizes that there are several evidence-based measures that can prevent CLABSI. These include hand hygiene, using alcoholic chlorhexidine for skin preparation prior to insertion, maximal sterile barrier precautions, avoiding the femoral site for CVC insertion, and removing unnecessary catheters as soon as possible. Support from administration in emphasizing patient safety and HAI prevention along with following evidence-based practice could lead to long-term improvement in CLABSI prevention across hospital systems.

Corresponding author: Payal K. Patel, MD, MPH, Div of Infectious Diseases, Dept of Internal Medicine, VA Ann Arbor Healthcare System, 2215 Fuller Rd, Ann Arbor, MI 48105, [email protected].

Financial disclosures: None.

References

1. Magill SS, Edwards JR, Bamberg W, et al; Emerging Infections Program Healthcare-Associated Infections and Antimicrobial Use Prevalence Survey Team. Multistate point-prevalence survey of health care-associated infections. N Engl J Med 2014;370:1198–208.

2. Marchetti A, Rossiter R. Economic burden of healthcare-associated infection in US acute care hospitals: societal perspective. J Med Econ 2013;16:1399–404.

3. O’Neil C, Ball K, Wood H, et al. A central line care maintenance bundle for the prevention of central line-associated bloodstream infection in non-intensive care unit settings. Infect Control Hosp Epidemiol 2016;37:1–7.

4. Shekelle PG, Wachter RM, Pronovost PJ, et al. Making health care safer II: an updated critical analysis of the evidence for patient safety practices. Evid Rep Technol Assess (Full Rep) 2013:1–945.

5. Patel PK, Gupta A, Vaughn VM, Mann JD, Ameling JM, Meddings J. Review of strategies to reduce central line-associated bloodstream infection (CLABSI) and catheter-associated urinary tract infection (CAUTI) in adult ICUs. J Hosp Med 2018;13:105–16.

6. Chopra V, Ratz D, Kuhn L, et al. PICC-associated bloodstream infections: prevalence, patterns, and predictors. Am J Med 2014;127:319–28.

7. Sagana R, Hyzy RC. Achieving zero central line-associated bloodstream infection rates in your intensive care unit. Crit Care Clin 2013;29:1–9.

8. Nelson RE, Angelovic AW, Nelson SD, Gleed JR, Drews FA. An economic analysis of adherence engineering to improve use of best practices during central line maintenance procedures. Infect Control Hosp Epidemiol 2015;36:550–6.

9. Pronovost P, Needham D, Berenholtz S, et al. An intervention to decrease catheter-related bloodstream infections in the ICU. N Engl J Med 2006;355:2725–32.

10. Dumyati G, Concannon C, van Wijngaarden E, et al. Sustained reduction of central line-associated bloodstream infections outside the intensive care unit with a multimodal intervention focusing on central line maintenance. Am J Infect Control 2014;42:723–30.

11. Sacks GD, Diggs BS, Hadjizacharia P, et al. Reducing the rate of catheter-associated bloodstream infections in a surgical intensive care unit using the Institute for Healthcare Improvement Central Line Bundle. Am J Surg 2014;207:817–23.

12. Boyce JM, Pittet D; Healthcare Infection Control Practices Advisory Committee; HICPAC/SHEA/APIC/IDSA Hand Hygiene Task Force. Guideline for hand hygiene in health-care settings: recommendations of the Healthcare Infection Control Practices Advisory Committee and the HICPAC/SHEA/APIC/IDSA Hand Hygiene Task Force. Society for Healthcare Epidemiology of America/Association for Professionals in Infection Control/Infectious Diseases Society of America. MMWR Recomm Rep 2002; 51:1-45, quiz CE1–4.

13. Marschall J, Mermel LA, et al; Society for Healthcare Epidemiology of America. Strategies to prevent central line-associated bloodstream infections in acute care hospitals: 2014 update. Infect Control Hosp Epidemiol 2014;35:753–71.

14. Safdar N, Maki DG. The pathogenesis of catheter-related bloodstream infection with noncuffed short-term central venous catheters. Intensive Care Med 2004;30:62–7.

15. Shabot MM, Chassin MR, France AC, et al. Using the targeted solutions tool(R) to improve hand hygiene compliance is associated with decreased health care-associated infections. Jt Comm J Qual Patient Saf 2016;42:6–17.

16. Johnson L, Grueber S, Schlotzhauer C, et al. A multifactorial action plan improves hand hygiene adherence and significantly reduces central line-associated bloodstream infections. Am J Infect Control 2014;42:1146–51.

17. Barrera L, Zingg W, Mendez F, Pittet D. Effectiveness of a hand hygiene promotion strategy using alcohol-based handrub in 6 intensive care units in Colombia. Am J Infect Control 2011;39:633–9.

18. Hu KK, Lipsky BA, Veenstra DL, Saint S. Using maximal sterile barriers to prevent central venous catheter-related infection: a systematic evidence-based review. Am J Infect Control 2004;32:142–6.

19. Hu KK, Veenstra DL, Lipsky BA, Saint S. Use of maximal sterile barriers during central venous catheter insertion: clinical and economic outcomes. Clin Infect Dis 2004;39:1441–5.

20. Raad II, Hohn DC, Gilbreath BJ, et al. Prevention of central venous catheter-related infections by using maximal sterile barrier precautions during insertion. Infect Control Hosp Epidemiol 1994;15:231–8.

21. Furuya EY, Dick AW, Herzig CT, Pogorzelska-Maziarz M, Larson EL, Stone PW. Central line-associated bloodstream infection reduction and bundle compliance in intensive care units: a national study. Infect Control Hosp Epidemiol 2016;37:805–10.

22. Sherertz RJ, Ely EW, Westbrook DM, et al. Education of physicians-in-training can decrease the risk for vascular catheter infection. Ann Intern Med 2000;132:641–8.

23. Mimoz O, Lucet JC, Kerforne T, Pascal J, et al. Skin antisepsis with chlorhexidine-alcohol versus povidone iodine-alcohol, with and without skin scrubbing, for prevention of intravascular-catheter-related infection (CLEAN): an open-label, multicentre, randomised, controlled, two-by-two factorial trial. Lancet 2015;386:2069–77.

24. Lai NM, Lai NA, O’Riordan E, et al. Skin antisepsis for reducing central venous catheter-related infections. Cochrane Database Syst Rev 2016;7:CD010140.

25. Chopra V, Shojania KG. Recipes for checklists and bundles: one part active ingredient, two parts measurement. BMJ Qual Saf 2013;22:93–6.

26. Marik PE, Flemmer M, Harrison W. The risk of catheter-related bloodstream infection with femoral venous catheters as compared to subclavian and internal jugular venous catheters: a systematic review of the literature and meta-analysis. Crit Care Med 2012;40:2479–85.

27. Timsit JF. What is the best site for central venous catheter insertion in critically ill patients? Crit Care 2003;7:397–99.

28. Parienti JJ, Mongardon N, Megarbane B, et al; 3SITES Study Group. Intravascular complications of central venous catheterization by insertion site. N Engl J Med 2015;373:1220–9.

29. Hind D, Calvert N, McWilliams R, et al. Ultrasonic locating devices for central venous cannulation: meta-analysis. BMJ 2003;327:361.

30. Fragou M, Gravvanis A, Dimitriou V, et al. Real-time ultrasound-guided subclavian vein cannulation versus the landmark method in critical care patients: a prospective randomized study. Crit Care Med 2011;39:1607–12.

31. Pageler NM, Longhurst CA, Wood M, et al. Use of electronic medical record-enhanced checklist and electronic dashboard to decrease CLABSIs. Pediatrics 2014;133:e738–46.

32. Drews FA, Bakdash JZ, Gleed JR. Improving central line maintenance to reduce central line-associated bloodstream infections. Am J Infect Control 2017;45:1224–30.

33. Frost SA, Alogso MC, Metcalfe L, et al. Chlorhexidine bathing and health care-associated infections among adult intensive care patients: a systematic review and meta-analysis. Crit Care 2016;20:379.

34. Chopra V, O’Horo JC, Rogers MA, et al. The risk of bloodstream infection associated with peripherally inserted central catheters compared with central venous catheters in adults: a systematic review and meta-analysis. Infect Control Hosp Epidemiol 2013;34:908–18.

35. Xue H, Ix JH, Wang W, et al. Hemodialysis access usage patterns in the incident dialysis year and associated catheter-related complications. Am J Kidney Dis 2013;61:123–30.

36. Almuneef MA, Memish ZA, Balkhy HH, et al. Rate, risk factors and outcomes of catheter-related bloodstream infection in a paediatric intensive care unit in Saudi Arabia. J Hosp Infect 2006;62:207–13.

37. Alonso-Echanove J, Edwards JR, Richards MJ, et al. Effect of nurse staffing and antimicrobial-impregnated central venous catheters on the risk for bloodstream infections in intensive care units. Infect Control Hosp Epidemiol 2003;24:916–25.

38. Lorente L, Henry C, Martin MM, et al. Central venous catheter-related infection in a prospective and observational study of 2,595 catheters. Crit Care 2005;9:R631–5.

39. Rey C, Alvarez F, De-La-Rua V, et al. Intervention to reduce catheter-related bloodstream infections in a pediatric intensive care unit. Intensive Care Med 2011;37:678–85.

40. O’Brien J, Paquet F, Lindsay R, Valenti D. Insertion of PICCs with minimum number of lumens reduces complications and costs. J Am Coll Radiol. 2013;10:864–8.

41. Herc E, Patel P, Washer LL, et al. A model to predict central-line-associated bloodstream infection among patients with peripherally inserted central catheters: the MPC score. Infect Control Hosp Epidemiol 2017;38:1155–66.

42. Centers for Disease Control and Prevention. Vital signs: central line-associated blood stream infections--United States, 2001, 2008, and 2009. MMWR Morb Mortal Wkly Rep 2011;60:243–8.

References

1. Magill SS, Edwards JR, Bamberg W, et al; Emerging Infections Program Healthcare-Associated Infections and Antimicrobial Use Prevalence Survey Team. Multistate point-prevalence survey of health care-associated infections. N Engl J Med 2014;370:1198–208.

2. Marchetti A, Rossiter R. Economic burden of healthcare-associated infection in US acute care hospitals: societal perspective. J Med Econ 2013;16:1399–404.

3. O’Neil C, Ball K, Wood H, et al. A central line care maintenance bundle for the prevention of central line-associated bloodstream infection in non-intensive care unit settings. Infect Control Hosp Epidemiol 2016;37:1–7.

4. Shekelle PG, Wachter RM, Pronovost PJ, et al. Making health care safer II: an updated critical analysis of the evidence for patient safety practices. Evid Rep Technol Assess (Full Rep) 2013:1–945.

5. Patel PK, Gupta A, Vaughn VM, Mann JD, Ameling JM, Meddings J. Review of strategies to reduce central line-associated bloodstream infection (CLABSI) and catheter-associated urinary tract infection (CAUTI) in adult ICUs. J Hosp Med 2018;13:105–16.

6. Chopra V, Ratz D, Kuhn L, et al. PICC-associated bloodstream infections: prevalence, patterns, and predictors. Am J Med 2014;127:319–28.

7. Sagana R, Hyzy RC. Achieving zero central line-associated bloodstream infection rates in your intensive care unit. Crit Care Clin 2013;29:1–9.

8. Nelson RE, Angelovic AW, Nelson SD, Gleed JR, Drews FA. An economic analysis of adherence engineering to improve use of best practices during central line maintenance procedures. Infect Control Hosp Epidemiol 2015;36:550–6.

9. Pronovost P, Needham D, Berenholtz S, et al. An intervention to decrease catheter-related bloodstream infections in the ICU. N Engl J Med 2006;355:2725–32.

10. Dumyati G, Concannon C, van Wijngaarden E, et al. Sustained reduction of central line-associated bloodstream infections outside the intensive care unit with a multimodal intervention focusing on central line maintenance. Am J Infect Control 2014;42:723–30.

11. Sacks GD, Diggs BS, Hadjizacharia P, et al. Reducing the rate of catheter-associated bloodstream infections in a surgical intensive care unit using the Institute for Healthcare Improvement Central Line Bundle. Am J Surg 2014;207:817–23.

12. Boyce JM, Pittet D; Healthcare Infection Control Practices Advisory Committee; HICPAC/SHEA/APIC/IDSA Hand Hygiene Task Force. Guideline for hand hygiene in health-care settings: recommendations of the Healthcare Infection Control Practices Advisory Committee and the HICPAC/SHEA/APIC/IDSA Hand Hygiene Task Force. Society for Healthcare Epidemiology of America/Association for Professionals in Infection Control/Infectious Diseases Society of America. MMWR Recomm Rep 2002; 51:1-45, quiz CE1–4.

13. Marschall J, Mermel LA, et al; Society for Healthcare Epidemiology of America. Strategies to prevent central line-associated bloodstream infections in acute care hospitals: 2014 update. Infect Control Hosp Epidemiol 2014;35:753–71.

14. Safdar N, Maki DG. The pathogenesis of catheter-related bloodstream infection with noncuffed short-term central venous catheters. Intensive Care Med 2004;30:62–7.

15. Shabot MM, Chassin MR, France AC, et al. Using the targeted solutions tool(R) to improve hand hygiene compliance is associated with decreased health care-associated infections. Jt Comm J Qual Patient Saf 2016;42:6–17.

16. Johnson L, Grueber S, Schlotzhauer C, et al. A multifactorial action plan improves hand hygiene adherence and significantly reduces central line-associated bloodstream infections. Am J Infect Control 2014;42:1146–51.

17. Barrera L, Zingg W, Mendez F, Pittet D. Effectiveness of a hand hygiene promotion strategy using alcohol-based handrub in 6 intensive care units in Colombia. Am J Infect Control 2011;39:633–9.

18. Hu KK, Lipsky BA, Veenstra DL, Saint S. Using maximal sterile barriers to prevent central venous catheter-related infection: a systematic evidence-based review. Am J Infect Control 2004;32:142–6.

19. Hu KK, Veenstra DL, Lipsky BA, Saint S. Use of maximal sterile barriers during central venous catheter insertion: clinical and economic outcomes. Clin Infect Dis 2004;39:1441–5.

20. Raad II, Hohn DC, Gilbreath BJ, et al. Prevention of central venous catheter-related infections by using maximal sterile barrier precautions during insertion. Infect Control Hosp Epidemiol 1994;15:231–8.

21. Furuya EY, Dick AW, Herzig CT, Pogorzelska-Maziarz M, Larson EL, Stone PW. Central line-associated bloodstream infection reduction and bundle compliance in intensive care units: a national study. Infect Control Hosp Epidemiol 2016;37:805–10.

22. Sherertz RJ, Ely EW, Westbrook DM, et al. Education of physicians-in-training can decrease the risk for vascular catheter infection. Ann Intern Med 2000;132:641–8.

23. Mimoz O, Lucet JC, Kerforne T, Pascal J, et al. Skin antisepsis with chlorhexidine-alcohol versus povidone iodine-alcohol, with and without skin scrubbing, for prevention of intravascular-catheter-related infection (CLEAN): an open-label, multicentre, randomised, controlled, two-by-two factorial trial. Lancet 2015;386:2069–77.

24. Lai NM, Lai NA, O’Riordan E, et al. Skin antisepsis for reducing central venous catheter-related infections. Cochrane Database Syst Rev 2016;7:CD010140.

25. Chopra V, Shojania KG. Recipes for checklists and bundles: one part active ingredient, two parts measurement. BMJ Qual Saf 2013;22:93–6.

26. Marik PE, Flemmer M, Harrison W. The risk of catheter-related bloodstream infection with femoral venous catheters as compared to subclavian and internal jugular venous catheters: a systematic review of the literature and meta-analysis. Crit Care Med 2012;40:2479–85.

27. Timsit JF. What is the best site for central venous catheter insertion in critically ill patients? Crit Care 2003;7:397–99.

28. Parienti JJ, Mongardon N, Megarbane B, et al; 3SITES Study Group. Intravascular complications of central venous catheterization by insertion site. N Engl J Med 2015;373:1220–9.

29. Hind D, Calvert N, McWilliams R, et al. Ultrasonic locating devices for central venous cannulation: meta-analysis. BMJ 2003;327:361.

30. Fragou M, Gravvanis A, Dimitriou V, et al. Real-time ultrasound-guided subclavian vein cannulation versus the landmark method in critical care patients: a prospective randomized study. Crit Care Med 2011;39:1607–12.

31. Pageler NM, Longhurst CA, Wood M, et al. Use of electronic medical record-enhanced checklist and electronic dashboard to decrease CLABSIs. Pediatrics 2014;133:e738–46.

32. Drews FA, Bakdash JZ, Gleed JR. Improving central line maintenance to reduce central line-associated bloodstream infections. Am J Infect Control 2017;45:1224–30.

33. Frost SA, Alogso MC, Metcalfe L, et al. Chlorhexidine bathing and health care-associated infections among adult intensive care patients: a systematic review and meta-analysis. Crit Care 2016;20:379.

34. Chopra V, O’Horo JC, Rogers MA, et al. The risk of bloodstream infection associated with peripherally inserted central catheters compared with central venous catheters in adults: a systematic review and meta-analysis. Infect Control Hosp Epidemiol 2013;34:908–18.

35. Xue H, Ix JH, Wang W, et al. Hemodialysis access usage patterns in the incident dialysis year and associated catheter-related complications. Am J Kidney Dis 2013;61:123–30.

36. Almuneef MA, Memish ZA, Balkhy HH, et al. Rate, risk factors and outcomes of catheter-related bloodstream infection in a paediatric intensive care unit in Saudi Arabia. J Hosp Infect 2006;62:207–13.

37. Alonso-Echanove J, Edwards JR, Richards MJ, et al. Effect of nurse staffing and antimicrobial-impregnated central venous catheters on the risk for bloodstream infections in intensive care units. Infect Control Hosp Epidemiol 2003;24:916–25.

38. Lorente L, Henry C, Martin MM, et al. Central venous catheter-related infection in a prospective and observational study of 2,595 catheters. Crit Care 2005;9:R631–5.

39. Rey C, Alvarez F, De-La-Rua V, et al. Intervention to reduce catheter-related bloodstream infections in a pediatric intensive care unit. Intensive Care Med 2011;37:678–85.

40. O’Brien J, Paquet F, Lindsay R, Valenti D. Insertion of PICCs with minimum number of lumens reduces complications and costs. J Am Coll Radiol. 2013;10:864–8.

41. Herc E, Patel P, Washer LL, et al. A model to predict central-line-associated bloodstream infection among patients with peripherally inserted central catheters: the MPC score. Infect Control Hosp Epidemiol 2017;38:1155–66.

42. Centers for Disease Control and Prevention. Vital signs: central line-associated blood stream infections--United States, 2001, 2008, and 2009. MMWR Morb Mortal Wkly Rep 2011;60:243–8.

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Review of Strategies to Reduce Central Line-Associated Bloodstream Infection (CLABSI) and Catheter-Associated Urinary Tract Infection (CAUTI) in Adult ICUs

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Tue, 10/30/2018 - 08:46

Central line–associated bloodstream infection (CLABSI) and catheter-associated urinary tract infection (CAUTI) are morbid and expensive healthcare-associated infections (HAIs).1-8 While these HAIs are prevalent in intensive care units (ICUs) and general wards, most of the research, prevention efforts, and financial penalties have been focused in the ICU.9,10 For hospitalists, who are taking a larger role in caring for the critically ill,11,12 it is optimal to understand best preventive practices.

There has been a national puTash to standardize procedures and products to prevent CLABSI and CAUTI.2,13-16 CLABSI has transitioned from a common ICU complication to a “never event.” Success has been reflected in the prevention of 25,000 CLABSIs over the last decade, translating to a 58% reduction in infections, with 6000 deaths prevented and $414 million saved.2 CLABSI prevention principles have been applied to CAUTI prevention (ie, aseptic insertion, maintenance care, prompting removal) but with slower adoption17 and fewer dramatic CAUTI reductions,18 due in part to weaker recognition19 of CAUTI as a serious clinical event, despite its morbidity20 and cost.21

Despite recent improvements in preventing HAIs, there is a marked variability in how hospitals perform in preventing these infections.22 To inform infection prevention strategies for a large-scale implementation project funded by the Agency for Healthcare Research and Quality and focused on ICUs with persistently elevated CLABSI and/or CAUTI rates,23 we performed a systematic search of interventions to prevent CLABSI and CAUTI in the ICU setting. This evidence was synthesized to help units select and prioritize interventions to prevent these HAIs.

METHODS

Literature Search Strategy

We performed a systematic search to identify CLABSI and CAUTI prevention studies and synthesized findings using a narrative review process. Using criteria developed and refined from seminal articles on the topic,10,14,24-34 we searched the PubMed and Cochrane databases from their inception to October of 2015 using Medical Subject Headings (MeSHs) for “central venous catheters,” “CLABSI,” “central line associated bloodstream infection,” “catheter related bloodstream infection,” “intravascular devices,” “urinary catheterization,” “urinary catheters,” “urinary tract infections,” “CAUTI,” and “catheter associated urinary tract infections” and filtered for articles containing the MeSHs “intensive care unit” and “ICU.” Supplemental Figure 1 details the search, yielding 102 studies for CLABSI and 28 studies for CAUTI, including 7 studies with CLABSI and CAUTI interventions.

Eligibility Criteria Review

Study Design

We included randomized and nonrandomized studies that implemented at least 1 intervention to prevent CLABSI or CAUTI in an adult ICU setting and reported the preintervention or control group data to compare with the postintervention data. We excluded general ward, outpatient/ambulatory, and neonatal/pediatric settings. Interventions to prevent CLABSI or CAUTI were included. We excluded interventions focused on diagnosis or treatment or those that lacked adequate description of the intervention for replication. Studies with interventions that are no longer standard of care in the United States (US) were excluded, as were studies not available in English.

Outcomes

Primary Outcomes for Central Vascular Catheter Infection

  • CLABSI: A lab-confirmed bloodstream infection in a patient who has had a central line for at least 48 hours on the date of the development of the bloodstream infection and without another known source of infection. We included studies that reported CLABSIs per 1000 central line days or those that provided data to permit calculation of this ratio. This measure is similar to current National Healthcare Safety Network (NHSN) surveillance definitions.22
  • Catheter-related bloodstream infection (CRBSI): A lab-confirmed bloodstream infection attributed to an intravascular catheter by a quantitative culture of the catheter tip or by differences in growth between catheter and peripheral venipuncture blood culture specimens.35 This microbiologic definition of a central line bloodstream infection was often used prior to NHSN reporting, with rates provided as the number of CRBSIs per 1000 central line days.
 

 

Primary Outcome for Urinary Catheter Infection

  • CAUTI: Urinary tract infection occurring in patients during or after the recent use of an indwelling urinary catheter. We included studies that reported CAUTIs per 1000 urinary catheter days or those that provided data to permit calculation of this ratio (similar to the current NHSN surveillance definitions).22 We excluded studies where CAUTI was defined as bacteriuria alone, without symptoms.

Secondary Outcomes

  • Central line utilization ratio: The device utilization ratio (DUR) measure of central line use is calculated as central line days divided by patient days.
  • Urinary catheter utilization ratio: The DUR measure of urinary catheter use is calculated as indwelling urinary catheter days divided by patient days, as used in NHSN surveillance, excluding other catheter types.22 We excluded other measures of urinary catheter use because of a large variation in definitions, which limits the ability to compare measures across studies.

Data Synthesis and Analysis

Information on the ICU and intervention type, intervention components, outcomes, and whether interventions were in use prior to the study was abstracted by CAUTI and CLABSI experts (JM and PKP) and confirmed by a second author.

We compared interventions found in the literature to components of the previously published urinary catheter “life cycle,” a conceptual model used to organize and prioritize interventions for a reduction in CAUTI (Figure 1).36

In this framework, there are 4 stages: (1) catheter placement, (2) catheter care, (3) catheter removal, and (4) catheter reinsertion. We sought to tailor the model for interventions in the ICU and for CLABSI prevention studies in addition to CAUTI prevention studies. In Table 1,
we also provided the recommendation level for each intervention type provided in the CLABSI and CAUTI prevention guidelines from the Centers for Disease Control and Prevention Healthcare Infection Control Practices Advisory Committee, as close as was feasible, as the guidelines describe general strategies, not specific interventions.13,37 

RESULTS

Conceptual Model for Disrupting the Life Cycle of a Catheter

Our data analysis demonstrated that components of the urinary catheter life cycle (Figure 1) were useful and could be applied to vascular catheters, but changes were needed to make the model more valuable to hospitalists implementing CLABSI and CAUTI prevention interventions. We found that the previously named stage 1 (catheter placement) is better described in 2 stages: stage 0, avoid catheter if possible, and stage 1, ensure aseptic placement. Additionally, we tailored the model to include actionable language, describing ways to disrupt the life cycle. Finally, we added a component to represent interventions to improve implementation and sustainability, such as auditing compliance and timely feedback to clinicians. Thus, we introduce a new conceptual model, “Disrupting the Life Cycle of a Catheter” (Figure 2)

—including stages appropriate for targeting both CAUTI and CLABSI prevention: (stage 0) avoid catheter if possible (ie, prevent catheter “life cycle” from beginning), (stage 1) ensure aseptic placement, (stage 2) optimize catheter maintenance care, and (stage 3) promptly remove unnecessary catheters—as well as apply interventions to improve implementation and sustainability. We used this modified conceptual model to synthesize the CLABSI and CAUTI prevention interventions found in the systematic search.

Central Vascular Catheter Interventional Study Results

Characteristics of Included Central Vascular Catheter Infection Studies

Of the 102 central vascular catheter (CVC) studies that met the inclusion criteria (reporting outcomes for 105 intervention cohorts), 59 studies10,14,16,24-27,38-89 reporting outcomes for 61 intervention cohorts were performed in the US. Study designs included 14 randomized controlled trials (RCTs)48,64,68,74,79,90-98 and 88 before–after studies (Appendix Table 1). 10,14,16,24-27,33,38-47,49-63,69-73,75-78,80-89,99-131 Many RCTs evaluated antimicrobial products (CVCs, hubs, bathing) as interventions,48,68,74,90-95,97,98 but a few RCTs studied interventions64,79,93 impacting catheter care or use (Appendix Table 1). Fifty-one studies took place in tertiary care hospitals and 55 in academic hospitals. Thirty-one studies were multicenter; the largest included 792 hospitals and 1071 ICUs.24 ICU bed size ranged from 5 to 59.

CVC Study Outcomes

Sixty-three studies reported CLABSI outcomes, and 39 reported CRBSI outcomes (Table 2). Many studies had preintervention or control rates above the 2013 NHSN 75th percentiles,22 which varied by ICU type. Preintervention or control infection rates per 1000 catheter days varied widely (means: CLABSI 7.5, CRBSI 6.3); US studies reported ranges of 1.1 to 12.1 CLABSI and 1.2 to 11.0 CRBSI per 1000 catheter days; non-US studies reported ranges of 1.4 to 45.9 CLABSI and 1.6 to 22.7 CRBSI per 1000 catheter days. Postintervention rates varied widely, with overall means of 2.8 CLABSI and 2.5 CRBSI per 1000 catheter days, including US study ranges of 0 to 8.9 CLABSI and 0 to 5.4 CRBSI, and non-US study ranges of 0 to 17.1 CLABSI and 0 to 15.9 CRBSI.

 

 

Overall (Table 2), 99 of the 105 intervention
cohorts described in the 102 studies
reported either a reduced CLABSI or a reduced CRBSI outcome, including all ICU types. Of the 63 CLABSI studies, 60 reported lower postintervention CLABSI rates, with a mean reduction of 62.6%, though only 36 demonstrated statistical significance. Of the 39 studies that reported CRBSI outcomes, 37 reported lower postintervention CRBSI rates, with a mean reduction of 66%, of which 23 were statistically significant.

Central line DURs were reported in only 5 studies; 3 reported decreased postintervention DURs (2 with statistical significance), with a mean 11.7% reduction (Table 2).

CVC Interventions

CVC study interventions are summarized in Table 1, categorized by catheter life cycle component (Figure 2). Thirty-two included studies used a single intervention to prevent CVC infection. Interventions to avoid placement when possible were infrequent. Insertion-stage interventions were common and included avoiding the femoral site during placement, ensuring maximal sterile barriers, and chlorhexidine skin preparation. Standardizing basic products for central line insertion was often done by providing ICUs with a CLABSI insertion kit or stocked cart. In some studies, this was implemented prior to the intervention, and in others, the kit or cart itself was the intervention. Maintenance-stage interventions included scrubbing the hub prior to use, replacing wet or soiled dressings, accessing the catheter with sterile devices, and performing aseptic dressing changes. A recent systematic review and meta-analysis of CVC infection prevention studies indicated that implementing care bundles and/or checklists appears to yield stronger risk reductions than interventions without these components.132 The most common catheter removal interventions were daily audits of line removal and CLABSI rounds focused on ongoing catheter necessity.

Common implementation and sustainability interventions included outcome surveillance, such as feedback on CLABSI, and socio-adaptive interventions to prompt improvements in patient safety culture. Process and outcome surveillance as interventions were implemented in about one-quarter of the studies reviewed (AppendixTable 1).

CAUTI Interventional Study Results

Characteristics of Included CAUTI Studies

Of the 28 CAUTI studies that met the inclusion criteria (reporting outcomes for 30 intervention cohorts), 14 studies (reporting outcomes for 16 intervention cohorts) were performed in the US.28,34,53,66,68,133-141 Study designs included 2 RCTs (focused on urinary catheter avoidance or removal142 and chlorhexidine bathing68) and 26 nonrandomized, before–after studies28,30,33,34,53,66,109,114-116,133-141,143-149 (Appendix Table 1). The number of hospitals per study varied from 1 to 53, with the majority being single-hospital interventions.

CAUTI Study Outcomes

All 28 studies reported CAUTIs per 1000 catheter days for both intervention and comparison groups (Table 2). Preintervention or control CAUTI rates varied widely, with an overall mean of 12.5 CAUTIs per 1000 catheter days; US studies reported a range from 1.4 to 15.8 CAUTIs per 1000 catheter days; non-US studies reported a range from 0.8 to 90.1 CAUTIs per 1000 catheter days. Many studies had preintervention or control rates above the 2013 NHSN 75th percentiles.22 Postintervention CAUTI rates varied widely, with an overall mean of 7.0 CAUTIs per 1000 catheter days, including a US study range from 0 to 11.2 and a non-US study range from 1.9 to 65.7.

Overall (Table 2), 27 of the 30 intervention cohorts described in the 28 studies reported fewer CAUTIs, including all ICU types. Lower postintervention CAUTI rates were reported in 25 studies, with a mean 49.4% reduction, including 11 statistically significant reductions; many studies did not report the level of statistical significance or described inadequate power to detect a significant change (Table 2).

Urinary catheter utilization rates were reported for 11 studies (Table 2). A decreased urinary catheter utilization rate was reported in 7 studies (4 with statistically signficiant reductions), with a mean 16% reduction (Table 2). Other outcomes included cost savings, the potential for unintended negative outcomes, and clinician compliance with intervention components. Positive cost savings were reported in 5 studies.30,34,133,141,149

CAUTI Interventions

Of the 28 included CAUTI prevention studies, only 5 studied single interventions. Interventions were categorized in Table 1 by “life cycle” stages or as interventions to improve implementation and sustainability (Figure 2). Interventions to restrict indwelling urinary catheter use were common, including creating lists of approved indications selected by unit or hospital policy and requiring catheter orders with approved indications. Eight studies published approved indication lists.28,34,133-135,138,142,146 Although several studies describe the encouragement and use of bladder scanners and urinary catheter alternatives, none described purchasing these catheter alternatives.

Interventions to avoid indwelling urinary catheters included education about external catheters,28,34,109,133,140,144-146 urinary retention protocols,34,144,135,141 and bladder scanner simulation training.133 Interventions to improve aseptic insertion28,34,66,109,116,139-141-143-146,150 and maintenance care28,34,66,109,116,133,135,136,139-141,143-146,150 of urinary catheters were common. Four studies used a standardized urinary catheter kit or cart,28,34,139,142 and 2 studies used a commercial urinary catheter securement device.34,140 A CAUTI bundle checklist in daily patient care rounds was tested in 3 studies (Table 1).66,136,150 Reminder and stop order strategies, with the potential to reduce CAUTI rates by >50%,151 were included in 15 studies, with inteventions such as nurse-empowered stop orders. Several implementation and sustainability interventions were described, including socio-adaptive strategies such as holding multidisciplinary meetings to obtain unit or clinician feedback to inform design and improve buy-in and providing frequent feedback to ICU clinicians, including audits of catheter use appropriateness and catheter-associated infections.

 

 

DISCUSSION

This extensive literature review yielded a large body of literature demonstrating success in preventing CLABSI and CAUTI in all types of adult ICUs, including in general medical and surgical ICUs and in specialized units with historically higher rates, such as trauma, burn, and neurosurgical. Reported reductions in catheter infections were impressive (>65% for CLABSI or CRBSI and nearly 50% for CAUTI), though several studies had limited power to detect statistical significance. DURs were reported more rarely (particularly for vascular catheters) and often without power to detect statistical significance. Nevertheless, 7 studies reported reduced urinary catheter use (16% mean reduction), which would be anticipated to be clinically significant.

The conceptual model introduced for “Disrupting the Life Cycle of a Catheter” (Figure 2) can be a helpful tool for hospitalists and intensivists to assess and prioritize potential strategies for reducing catheter-associated infections. This study’s results indicate that CLABSI prevention studies often used interventions that optimize best practices during aseptic insertion and maintenance, but few studies emphasized reducing inappropriate central line use. Conversely, CAUTI prevention often targeted avoiding placement and prompting the removal of urinary catheters, with fewer studies evaluating innovative products or technical skill advancement for aseptic insertion or maintenance, though educational interventions to standardize aseptic catheter use were common. Recently, recommendations for reducing the inappropriate use of urinary catheters and intravenous catheters, including scenarios common in ICUs, were developed by using the rigorous RAND/UCLA Appropriateness Method152,153; these resources may be helpful to hospitalists designing and implementing interventions to reduce catheter use.

In reviewing the US studies of 5 units demonstrating the greatest success in preventing CLABSI56,62,65,78,83 and CAUTI,28,34,66,134 several shared features emerged. Interventions that addressed multiple steps within the life cycle of a catheter (avoidance, insertion, maintenance, and removal) were common. Previous work has shown that assuring compliance in infection prevention efforts is a key to success,154 and in both CLABSI and CAUTI studies, auditing was included in these successful interventions. Specifically for CLABSI, the checklist, a central quality improvement tool, was frequently associated with success. Unique to CAUTI, engaging a multidisciplinary team including nurse leadership seemed critical to optimize implementation and sustainability efforts. In addition, a focus on stage 3 (removal), including protocols to remove by default, was associated with success in CAUTI studies.

Our review was limited by a frequent lack of reporting of statistical significance or by inadequate power to detect a significant change and great variety. The ability to compare the impact of specific interventions is limited because studies varied greatly with respect to the type of intervention, duration of data collection, and outcomes assessed. We also anticipate that successful interventions are more likely to be published than are trials without success. Strengths include the use of a rigorous search process and the inclusion and review of several types of interventions implemented in ICUs.

In conclusion, despite high catheter use in ICUs, the literature includes many successful interventions for the prevention of vascular and urinary catheter infections in multiple ICU types. This review indicates that targeting multiple steps within the life cycle of a catheter, particularly when combined with interventions to optimize implementation and sustainability, can improve success in reducing CLABSI and CAUTI in the ICU.

Acknowledgments

The authors thank all members of the National Project Team for the AHRQ Safety Program for Intensive Care Units: Preventing CLABSI and CAUTI.

Disclosure

Agency for Healthcare Research and Quality (AHRQ) contract #HHSP233201500016I/HHSP23337002T provided funding for this study. J.M.’s other research is funded by AHRQ (2R01HS018334-04), the NIH-LRP program, the VA National Center for Patient Safety, VA Ann Arbor Patient Safety Center of Inquiry, the Health Research and Educational Trust, American Hospital Association and the Centers for Disease Control and Prevention. The findings and conclusions in this report are those of the authors and do not necessarily represent those of the sponsor, the Agency for Healthcare Research and Quality, or the US Department of Veterans Affairs. All authors report no conflicts of interest relevant to this article.

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70. Popovich KJ, Hota B, Hayes R, Weinstein RA, Hayden MK. Daily skin cleansing with chlorhexidine did not reduce the rate of central-line associated bloodstream infection in a surgical intensive care unit. Intensive Care Med. 2010;36(5):854-858. PubMed
71. Pronovost PJ, Watson SR, Goeschel CA, Hyzy RC, Berenholtz SM. Sustaining reductions in central line-associated bloodstream infections in Michigan intensive care units: A 10-year analysis. Am J Med Qual. 2016;31(3):197-202. PubMed
72. Rangachari P, Madaio M, Rethemeyer RK, et al. Cumulative impact of periodic top-down communications on infection prevention practices and outcomes in two units. Health Care Manage Rev. 2015;40(4):324-336. PubMed
73. Render ML, Hasselbeck R, Freyberg RW, et al. Reduction of central line infections in Veterans Administration intensive care units: an observational cohort using a central infrastructure to support learning and improvement. BMJ Qual Saf. 2011;20(8):725-732. PubMed
74. Rupp ME, Lisco SJ, Lipsett PA, et al. Effect of a second-generation venous catheter impregnated with chlorhexidine and silver sulfadiazine on central catheter-related infections: a randomized, controlled trial. Ann Intern Med. 2005;143(8):570-580. PubMed
75. Sacks GD, Diggs BS, Hadjizacharia P, Green D, Salim A, Malinoski DJ. Reducing the rate of catheter-associated bloodstream infections in a surgical intensive care unit using the Institute for Healthcare Improvement Central Line Bundle. Am J Surg. 2014;207(6):817-823. PubMed
76. Salemi C, Canola MT, Eck EK. Hand washing and physicians: how to get them together. Infect Control Hosp Epidemiol. 2002;23(1):32-35. PubMed
77. Shannon RP, Frndak D, Grunden N, et al. Using real-time problem solving to eliminate central line infections. Jt Comm J Qual Patient Saf. 2006;32(9):479-487. PubMed
78. Sopirala MM, Smyer J, Fawley L, et al. Sustained reduction of central line-associated bloodstream infections in an intensive care unit using a top-down and bottom-up approach. Am J Infect Control. 2013;41(2):183-184. PubMed
79. Speroff T, Ely EW, Greevy R, et al. Quality improvement projects targeting health care-associated infections: comparing Virtual Collaborative and Toolkit approaches. J Hosp Med. 2011;6(5):271-278. PubMed
80. Thom KA, Li S, Custer M, et al. Successful implementation of a unit-based quality nurse to reduce central line-associated bloodstream infections. Am J Infect Control. 2014;42(2):139-143. PubMed
81. Venkatram S, Rachmale S, Kanna B. Study of device use adjusted rates in health care-associated infections after implementation of “bundles” in a closed-model medical intensive care unit. J Crit Care. 2010;25(1):174.e11-174.e18. PubMed
82. Wall RJ, Ely EW, Elasy TA, et al. Using real time process measurements to reduce catheter related bloodstream infections in the intensive care unit. Qual Saf Health Care. 2005;14(4):295-302. PubMed
83. Walz JM, Ellison RT 3rd, Mack DA, et al. The bundle “plus”: the effect of a multidisciplinary team approach to eradicate central line-associated bloodstream infections. Anesth Analg. 2015;120(4):868-876. PubMed
84. Warren DK, Cosgrove SE, Diekema DJ, et al. A multicenter intervention to prevent catheter-associated bloodstream infections. Infect Control Hosp Epidemiol. 2006;27(7):662-669. PubMed
85. Warren DK, Zack JE, Mayfield JL, et al. The effect of an education program on the incidence of central venous catheter-associated bloodstream infection in a medical ICU. Chest. 2004;126(5):1612-1618. PubMed
86. Watson SR, George C, Martin M, Bogan B, Goeschel C, Pronovost PJ. Preventing central line-associated bloodstream infections and improving safety culture: a statewide experience. Jt Comm J Qual Patient Saf. 2009;35(12):593-597. PubMed
87. Mueller JT, Wright AJ, Fedraw LA, et al. Standardizing central line safety: lessons learned for physician leaders. Am J Med Qual. 2014;29(3):191-199. PubMed
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89. Zack J. Zeroing in on zero tolerance for central line-associated bacteremia. Am J Infect Control. 2008;36(10):S176.e1-S176.e2. PubMed
90. Brun-Buisson C, Doyon F, Sollet JP, Cochard JF, Cohen Y, Nitenberg G. Prevention of intravascular catheter-related infection with newer chlorhexidine-silver sulfadiazine-coated catheters: a randomized controlled trial. Intensive Care Med. 2004;30(5):837-843. PubMed
91. Carrasco MN, Bueno A, de las Cuevas C, et al. Evaluation of a triple-lumen central venous heparin-coated catheter versus a catheter coated with chlorhexidine and silver sulfadiazine in critically ill patients. Intensive Care Med. 2004;30(4):633-638 PubMed
92. Corral L, Nolla-Salas M, Ibañez-Nolla J, et al. A prospective, randomized study in critically ill patients using the Oligon Vantex catheter. J Hosp Infect. 2003;55(3):212-219. PubMed
93. Hagau N, Studnicska D, Gavrus RL, Csipak G, Hagau R, Slavcovici AV. Central venous catheter colonization and catheter-related bloodstream infections in critically ill patients: a comparison between standard and silver-integrated catheters. Eur J Anaesthesiol. 2009;26(9):752-758. PubMed
94. Kalfon P, de Vaumas C, Samba D, et al. Comparison of silver-impregnated with standard multi-lumen central venous catheters in critically ill patients. Crit Care Med. 2007;35(4):1032-1039. PubMed
95. Kurtz P, Rosa P, Penna G, et al. Antibiotic coated catheter to decrease infection: pilot study. Rev Bras Ter Intensiva. 2008;20(2):160-164. PubMed
96. Osma S, Kahveci SF, Kaya FN, et al. Efficacy of antiseptic-impregnated catheters on catheter colonization and catheter-related bloodstream infections in patients in an intensive care unit. J Hosp Infect. 2006;62(2):156-162. PubMed

97. León C, Alvarez-Lerma F, Ruiz-Santana S, et al. Antiseptic chamber-containing hub reduces central venous catheter-related infection: a prospective, randomized study. Crit Care Med. 2003;31(5):1318-1324. PubMed
98. León C, Ruiz-Santana S, Rello J, et al. Benefits of minocycline and rifampin-impregnated central venous catheters. A prospective, randomized, double-blind, controlled, multicenter trial. Intensive Care Med. 2004;30(10):1891-1899. PubMed
99. Bion J, Richardson A, Hibbert P, et al. ‘Matching Michigan’: a 2-year stepped interventional programme to minimise central venous catheter-blood stream infections in intensive care units in England. BMJ Qual Saf. 2013;22(2):110-123. PubMed
100. Cherifi S, Gerard M, Arias S, Byl B. A multicenter quasi-experimental study: impact of a central line infection control program using auditing and performance feedback in five Belgian intensive care units. Antimicrob Resist Infect Control. 2013;2(1):33. PubMed
101. Entesari-Tatafi D, Orford N, Bailey MJ, Chonghaile MN, Lamb-Jenkins J, Athan E. Effectiveness of a care bundle to reduce central line-associated bloodstream infections. Med J Aust. 2015;202(5):247-250. PubMed
102. Hakko E, Guvenc S, Karaman I, Cakmak A, Erdem T, Cakmakci M. Long-term sustainability of zero central-line associated bloodstream infections is possible with high compliance with care bundle elements. East Mediterr Health J. 2015;21(4):293-298. PubMed
103. Hansen S, Schwab F, Schneider S, Sohr D, Gastmeier P, Geffers C. Time-series analysis to observe the impact of a centrally organized educational intervention on the prevention of central-line-associated bloodstream infections in 32 German intensive care units. J Hosp Infect. 2014;87(4):220-226. PubMed
104. Hermon A, Pain T, Beckett P, et al. Improving compliance with central venous catheter care bundles using electronic records. Nurs Crit Care. 2015;20(4):196-203. PubMed
105. Jaggi N, Rodrigues C, Rosenthal VD, et al. Impact of an international nosocomial infection control consortium multidimensional approach on central line-associated bloodstream infection rates in adult intensive care units in eight cities in India. Int J Infect Dis. 2013;17(12):e1218-e1224. PubMed
106. Khalid I, Al Salmi H, Qushmaq I, Al Hroub M, Kadri M, Qabajah MR. Itemizing the bundle: achieving and maintaining “zero” central line-associated bloodstream infection for over a year in a tertiary care hospital in Saudi Arabia. Am J Infect Control. 2013;41(12):1209-1213. PubMed
107. Jeong IS, Park SM, Lee JM, Song JY, Lee SJ. Effect of central line bundle on central line-associated bloodstream infections in intensive care units. Am J Infect Control. 2013;41(8):710-716. PubMed
108. Klintworth G, Stafford J, O’Connor M, et al. Beyond the intensive care unit bundle: Implementation of a successful hospital-wide initiative to reduce central line-associated bloodstream infections. Am J Infect Control. 2014;42(6):685-687. PubMed
109. Leblebicioglu H, Ersoz G, Rosenthal VD, et al. Impact of a multidimensional infection control approach on catheter-associated urinary tract infection rates in adult intensive care units in 10 cities of Turkey: International Nosocomial Infection Control Consortium findings (INICC). Am J Infect Control. 2013;41(10):885-891. PubMed
110. Latif A, Kelly B, Edrees H, et al. Implementing a multifaceted intervention to decrease central line-associated bloodstream infections in SEHA (Abu Dhabi Health Services Company) intensive care units: the Abu Dhabi experience. Infect Control Hosp Epidemiol. 2015;36(7):816-822. PubMed
111. Longmate AG, Ellis KS, Boyle L, et al. Elimination of central-venous-catheter-related bloodstream infections from the intensive care unit. BMJ Qual Saf. 2011;20(2):174-180. PubMed
112. Lobo RD, Levin AS, Oliveira MS, et al. Evaluation of interventions to reduce catheter-associated bloodstream infection: continuous tailored education versus one basic lecture. Am J Infect Control. 2010;38(6):440-448. PubMed
113. Lorente L, Lecuona M, Jiménez A, et al. Chlorhexidine-silver sulfadiazine-impregnated venous catheters save costs. Am J Infect Control. 2014;42(3):321-324. PubMed
114. Marra AR, Cal RG, Durão MS, et al. Impact of a program to prevent central line-associated bloodstream infection in the zero tolerance era. Am J Infect Control. 2010;38(6):434-439. PubMed
115. Martínez-Reséndez MF, Garza-González E, Mendoza-Olazaran S, et al. Impact of daily chlorhexidine baths and hand hygiene compliance on nosocomial infection rates in critically ill patients. Am J Infect Control. 2014;42(7):713-717. PubMed
116. Mathur P, Tak V, Gunjiyal J, et al. Device-associated infections at a level-1 trauma centre of a developing nation: impact of automated surveillance, training and feedbacks. Indian J Med Microbiol. 2015;33(1):51-62. PubMed
117. Mazi W, Begum Z, Abdulla D, et al. Central line-associated bloodstream infection in a trauma intensive care unit: impact of implementation of Society for Healthcare Epidemiology of America/Infectious Diseases Society of America practice guidelines. Am J Infect Control. 2014;42(8):865-867. PubMed
118. Menegueti MG, Ardison KM, Bellissimo-Rodrigues F, et al. The impact of implementation of bundle to reduce catheter-related bloodstream infection rates. J Clin Med Res. 2015;7(11):857-861. PubMed
119. Paula AP, Oliveira PR, Miranda EP, et al. The long-term impact of a program to prevent central line-associated bloodstream infections in a surgical intensive care unit. Clinics (Sao Paulo). 2012;67(8):969-970. PubMed
120. Reddy KK, Samuel A, Smiley KA, Weber S, Hon H. Reducing central line-associated bloodstream infections in three ICUs at a tertiary care hospital in the United Arab Emirates. Jt Comm J Qual Patient Saf. 2014;40(12):559-561. PubMed
121. Palomar M, Álvarez-Lerma F, Riera A, et al. Impact of a national multimodal intervention to prevent catheter-related bloodstream infection in the ICU: the Spanish experience. Crit Care Med. 2013;41(10):2364-2372. PubMed
122. Peredo R, Sabatier C, Villagrá A, et al. Reduction in catheter-related bloodstream infections in critically ill patients through a multiple system intervention. Eur J Clin Microbiol Infect Dis. 2010;29(9):1173-1177. PubMed
123. Pérez Parra A, Cruz Menárguez M, Pérez Granda MJ, Tomey MJ, Padilla B, Bouza E. A simple educational intervention to decrease incidence of central line-associated bloodstream infection (CLABSI) in intensive care units with low baseline incidence of CLABSI. Infect Control Hosp Epidemiol. 2010;31(9):964-967. PubMed
124. Rosenthal VD, Guzman S, Pezzotto SM, Crnich CJ. Effect of an infection control program using education and performance feedback on rates of intravascular device-associated bloodstream infections in intensive care units in Argentina. Am J Infect Control. 2003;31(7):405-409. PubMed
125. Rosenthal VD, Maki DG, Rodrigues C, et al. Impact of International Nosocomial Infection Control Consortium (INICC) strategy on central line-associated bloodstream infection rates in the intensive care units of 15 developing countries. Infect Control Hosp Epidemiol. 2010;31(12):1264-1272. PubMed
126. Salama MF, Jamal W, Mousa HA, Rotimi V. Implementation of central venous catheter bundle in an intensive care unit in Kuwait: Effect on central line-associated bloodstream infections. J Infect Public Health. 2016;9(1):34-41. PubMed
127. Santana SL, Furtado GH, Wey SB, Medeiros EA. Impact of an education program on the incidence of central line-associated bloodstream infection in 2 medical-surgical intensive care units in Brazil. Infect Control Hosp Epidemiol. 2008;29(12):1171-1173. PubMed
128. Scheithauer S, Lewalter K, Schröder J, et al. Reduction of central venous line-associated bloodstream infection rates by using a chlorhexidine-containing dressing. Infection. 2014;42(1):155-159. PubMed

129. Singh S, Kumar RK, Sundaram KR, et al. Improving outcomes and reducing costs by modular training in infection control in a resource-limited setting. Int J Qual Health Care. 2012;24(6):641-648. PubMed
130. Zingg W, Cartier V, Inan C, et al. Hospital-wide multidisciplinary, multimodal intervention programme to reduce central venous catheter-associated bloodstream infection. PLoS One. 2014;9(4):e93898. PubMed
131. Zingg W, Imhof A, Maggiorini M, Stocker R, Keller E, Ruef C. Impact of a prevention strategy targeting hand hygiene and catheter care on the incidence of catheter-related bloodstream infections. Crit Care Med. 2009;37(7):2167-2173. PubMed
132. Blot K, Bergs J, Vogelaers D, Blot S, Vandijck D. Prevention of central line-associated bloodstream infections through quality improvement interventions: a systematic review and meta-analysis. Clin Infect Dis. 2014;59(1):96-105. PubMed
133. Alexaitis I, Broome B. Implementation of a nurse-driven protocol to prevent catheter-associated urinary tract infections. J Nurs Care Qual. 2014;29(3):245-252. PubMed
134. Elpern EH, Killeen K, Ketchem A, Wiley A, Patel G, Lateef O. Reducing use of indwelling urinary catheters and associated urinary tract infections. Am J Crit Care. 2009;18(6):535-541. PubMed

135. Fuchs MA, Sexton DJ, Thornlow DK, Champagne MT. Evaluation of an evidence-based, nurse-driven checklist to prevent hospital-acquired catheter-associated urinary tract infections in intensive care units. J Nurs Care Qual. 2011;26(2):101-109. PubMed
136. Jain M, Miller L, Belt D, King D, Berwick DM. Decline in ICU adverse events, nosocomial infections and cost through a quality improvement initiative focusing on teamwork and culture change. Qual Saf Health Care. 2006;15(4):235-239. PubMed
137. Popp JA, Layon AJ, Nappo R, Richards WT, Mozingo DW. Hospital-acquired infections and thermally injured patients: chlorhexidine gluconate baths work. Am J Infect Control. 2014;42(2):129-132. PubMed
138. Reilly L, Sullivan P, Ninni S, Fochesto D, Williams K, Fetherman B. Reducing foley catheter device days in an intensive care unit: using the evidence to change practice. AACN Adv Crit Care. 2006;17(3):272-283. PubMed
139. Saint S, Fowler KE, Sermak K, et al. Introducing the No Preventable Harms campaign: creating the safest health care system in the world, starting with catheter-associated urinary tract infection prevention. Am J Infect Control. 2015;43(3):254-259. PubMed
140. Schelling K, Palamone J, Thomas K, et al. Reducing catheter-associated urinary tract infections in a neuro-spine intensive care unit. Am J Infect Control. 2015;43(8):892-894. PubMed
141. Sutherland T, Beloff J, McGrath C, et al. A single-center multidisciplinary initiative to reduce catheter-associated urinary tract infection rates: Quality and financial implications. Health Care Manag (Frederick). 2015;34(3):218-224. PubMed
142. Chen YY, Chi MM, Chen YC, Chan YJ, Chou SS, Wang FD. Using a criteria-based reminder to reduce use of indwelling urinary catheters and decrease urinary tract infections. Am J Crit Care. 2013;22(2):105-114. PubMed
143. Amine AE, Helal MO, Bakr WM. Evaluation of an intervention program to prevent hospital-acquired catheter-associated urinary tract infections in an ICU in a rural Egypt hospital. GMS Hyg Infect Control. 2014;9(2):Doc15. PubMed
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145. Navoa-Ng JA, Berba R, Rosenthal VD, et al. Impact of an International Nosocomial Infection Control Consortium multidimensional approach on catheter-associated urinary tract infections in adult intensive care units in the Philippines: International Nosocomial Infection Control Consortium (INICC) findings. J Infect Public Health. 2013;6(5):389-399. PubMed
146. Rosenthal VD, Todi SK, Álvarez-Moreno C, et al. Impact of a multidimensional infection control strategy on catheter-associated urinary tract infection rates in the adult intensive care units of 15 developing countries: findings of the International Nosocomial Infection Control Consortium (INICC). Infection. 2012;40(5):517-526. PubMed
147. Salama MF, Jamal WY, Mousa HA, Al-Abdulghani KA, Rotimi VO. The effect of hand hygiene compliance on hospital-acquired infections in an ICU setting in a Kuwaiti teaching hospital. J Infect Public Health. 2013;6(1):27-34. PubMed
148. Seyman D, Oztoprak N, Berk H, Kizilates F, Emek M. Weekly chlorhexidine douche: does it reduce healthcare-associated bloodstream infections? Scand J Infect Dis. 2014;46(10):697-703. PubMed
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Central line–associated bloodstream infection (CLABSI) and catheter-associated urinary tract infection (CAUTI) are morbid and expensive healthcare-associated infections (HAIs).1-8 While these HAIs are prevalent in intensive care units (ICUs) and general wards, most of the research, prevention efforts, and financial penalties have been focused in the ICU.9,10 For hospitalists, who are taking a larger role in caring for the critically ill,11,12 it is optimal to understand best preventive practices.

There has been a national puTash to standardize procedures and products to prevent CLABSI and CAUTI.2,13-16 CLABSI has transitioned from a common ICU complication to a “never event.” Success has been reflected in the prevention of 25,000 CLABSIs over the last decade, translating to a 58% reduction in infections, with 6000 deaths prevented and $414 million saved.2 CLABSI prevention principles have been applied to CAUTI prevention (ie, aseptic insertion, maintenance care, prompting removal) but with slower adoption17 and fewer dramatic CAUTI reductions,18 due in part to weaker recognition19 of CAUTI as a serious clinical event, despite its morbidity20 and cost.21

Despite recent improvements in preventing HAIs, there is a marked variability in how hospitals perform in preventing these infections.22 To inform infection prevention strategies for a large-scale implementation project funded by the Agency for Healthcare Research and Quality and focused on ICUs with persistently elevated CLABSI and/or CAUTI rates,23 we performed a systematic search of interventions to prevent CLABSI and CAUTI in the ICU setting. This evidence was synthesized to help units select and prioritize interventions to prevent these HAIs.

METHODS

Literature Search Strategy

We performed a systematic search to identify CLABSI and CAUTI prevention studies and synthesized findings using a narrative review process. Using criteria developed and refined from seminal articles on the topic,10,14,24-34 we searched the PubMed and Cochrane databases from their inception to October of 2015 using Medical Subject Headings (MeSHs) for “central venous catheters,” “CLABSI,” “central line associated bloodstream infection,” “catheter related bloodstream infection,” “intravascular devices,” “urinary catheterization,” “urinary catheters,” “urinary tract infections,” “CAUTI,” and “catheter associated urinary tract infections” and filtered for articles containing the MeSHs “intensive care unit” and “ICU.” Supplemental Figure 1 details the search, yielding 102 studies for CLABSI and 28 studies for CAUTI, including 7 studies with CLABSI and CAUTI interventions.

Eligibility Criteria Review

Study Design

We included randomized and nonrandomized studies that implemented at least 1 intervention to prevent CLABSI or CAUTI in an adult ICU setting and reported the preintervention or control group data to compare with the postintervention data. We excluded general ward, outpatient/ambulatory, and neonatal/pediatric settings. Interventions to prevent CLABSI or CAUTI were included. We excluded interventions focused on diagnosis or treatment or those that lacked adequate description of the intervention for replication. Studies with interventions that are no longer standard of care in the United States (US) were excluded, as were studies not available in English.

Outcomes

Primary Outcomes for Central Vascular Catheter Infection

  • CLABSI: A lab-confirmed bloodstream infection in a patient who has had a central line for at least 48 hours on the date of the development of the bloodstream infection and without another known source of infection. We included studies that reported CLABSIs per 1000 central line days or those that provided data to permit calculation of this ratio. This measure is similar to current National Healthcare Safety Network (NHSN) surveillance definitions.22
  • Catheter-related bloodstream infection (CRBSI): A lab-confirmed bloodstream infection attributed to an intravascular catheter by a quantitative culture of the catheter tip or by differences in growth between catheter and peripheral venipuncture blood culture specimens.35 This microbiologic definition of a central line bloodstream infection was often used prior to NHSN reporting, with rates provided as the number of CRBSIs per 1000 central line days.
 

 

Primary Outcome for Urinary Catheter Infection

  • CAUTI: Urinary tract infection occurring in patients during or after the recent use of an indwelling urinary catheter. We included studies that reported CAUTIs per 1000 urinary catheter days or those that provided data to permit calculation of this ratio (similar to the current NHSN surveillance definitions).22 We excluded studies where CAUTI was defined as bacteriuria alone, without symptoms.

Secondary Outcomes

  • Central line utilization ratio: The device utilization ratio (DUR) measure of central line use is calculated as central line days divided by patient days.
  • Urinary catheter utilization ratio: The DUR measure of urinary catheter use is calculated as indwelling urinary catheter days divided by patient days, as used in NHSN surveillance, excluding other catheter types.22 We excluded other measures of urinary catheter use because of a large variation in definitions, which limits the ability to compare measures across studies.

Data Synthesis and Analysis

Information on the ICU and intervention type, intervention components, outcomes, and whether interventions were in use prior to the study was abstracted by CAUTI and CLABSI experts (JM and PKP) and confirmed by a second author.

We compared interventions found in the literature to components of the previously published urinary catheter “life cycle,” a conceptual model used to organize and prioritize interventions for a reduction in CAUTI (Figure 1).36

In this framework, there are 4 stages: (1) catheter placement, (2) catheter care, (3) catheter removal, and (4) catheter reinsertion. We sought to tailor the model for interventions in the ICU and for CLABSI prevention studies in addition to CAUTI prevention studies. In Table 1,
we also provided the recommendation level for each intervention type provided in the CLABSI and CAUTI prevention guidelines from the Centers for Disease Control and Prevention Healthcare Infection Control Practices Advisory Committee, as close as was feasible, as the guidelines describe general strategies, not specific interventions.13,37 

RESULTS

Conceptual Model for Disrupting the Life Cycle of a Catheter

Our data analysis demonstrated that components of the urinary catheter life cycle (Figure 1) were useful and could be applied to vascular catheters, but changes were needed to make the model more valuable to hospitalists implementing CLABSI and CAUTI prevention interventions. We found that the previously named stage 1 (catheter placement) is better described in 2 stages: stage 0, avoid catheter if possible, and stage 1, ensure aseptic placement. Additionally, we tailored the model to include actionable language, describing ways to disrupt the life cycle. Finally, we added a component to represent interventions to improve implementation and sustainability, such as auditing compliance and timely feedback to clinicians. Thus, we introduce a new conceptual model, “Disrupting the Life Cycle of a Catheter” (Figure 2)

—including stages appropriate for targeting both CAUTI and CLABSI prevention: (stage 0) avoid catheter if possible (ie, prevent catheter “life cycle” from beginning), (stage 1) ensure aseptic placement, (stage 2) optimize catheter maintenance care, and (stage 3) promptly remove unnecessary catheters—as well as apply interventions to improve implementation and sustainability. We used this modified conceptual model to synthesize the CLABSI and CAUTI prevention interventions found in the systematic search.

Central Vascular Catheter Interventional Study Results

Characteristics of Included Central Vascular Catheter Infection Studies

Of the 102 central vascular catheter (CVC) studies that met the inclusion criteria (reporting outcomes for 105 intervention cohorts), 59 studies10,14,16,24-27,38-89 reporting outcomes for 61 intervention cohorts were performed in the US. Study designs included 14 randomized controlled trials (RCTs)48,64,68,74,79,90-98 and 88 before–after studies (Appendix Table 1). 10,14,16,24-27,33,38-47,49-63,69-73,75-78,80-89,99-131 Many RCTs evaluated antimicrobial products (CVCs, hubs, bathing) as interventions,48,68,74,90-95,97,98 but a few RCTs studied interventions64,79,93 impacting catheter care or use (Appendix Table 1). Fifty-one studies took place in tertiary care hospitals and 55 in academic hospitals. Thirty-one studies were multicenter; the largest included 792 hospitals and 1071 ICUs.24 ICU bed size ranged from 5 to 59.

CVC Study Outcomes

Sixty-three studies reported CLABSI outcomes, and 39 reported CRBSI outcomes (Table 2). Many studies had preintervention or control rates above the 2013 NHSN 75th percentiles,22 which varied by ICU type. Preintervention or control infection rates per 1000 catheter days varied widely (means: CLABSI 7.5, CRBSI 6.3); US studies reported ranges of 1.1 to 12.1 CLABSI and 1.2 to 11.0 CRBSI per 1000 catheter days; non-US studies reported ranges of 1.4 to 45.9 CLABSI and 1.6 to 22.7 CRBSI per 1000 catheter days. Postintervention rates varied widely, with overall means of 2.8 CLABSI and 2.5 CRBSI per 1000 catheter days, including US study ranges of 0 to 8.9 CLABSI and 0 to 5.4 CRBSI, and non-US study ranges of 0 to 17.1 CLABSI and 0 to 15.9 CRBSI.

 

 

Overall (Table 2), 99 of the 105 intervention
cohorts described in the 102 studies
reported either a reduced CLABSI or a reduced CRBSI outcome, including all ICU types. Of the 63 CLABSI studies, 60 reported lower postintervention CLABSI rates, with a mean reduction of 62.6%, though only 36 demonstrated statistical significance. Of the 39 studies that reported CRBSI outcomes, 37 reported lower postintervention CRBSI rates, with a mean reduction of 66%, of which 23 were statistically significant.

Central line DURs were reported in only 5 studies; 3 reported decreased postintervention DURs (2 with statistical significance), with a mean 11.7% reduction (Table 2).

CVC Interventions

CVC study interventions are summarized in Table 1, categorized by catheter life cycle component (Figure 2). Thirty-two included studies used a single intervention to prevent CVC infection. Interventions to avoid placement when possible were infrequent. Insertion-stage interventions were common and included avoiding the femoral site during placement, ensuring maximal sterile barriers, and chlorhexidine skin preparation. Standardizing basic products for central line insertion was often done by providing ICUs with a CLABSI insertion kit or stocked cart. In some studies, this was implemented prior to the intervention, and in others, the kit or cart itself was the intervention. Maintenance-stage interventions included scrubbing the hub prior to use, replacing wet or soiled dressings, accessing the catheter with sterile devices, and performing aseptic dressing changes. A recent systematic review and meta-analysis of CVC infection prevention studies indicated that implementing care bundles and/or checklists appears to yield stronger risk reductions than interventions without these components.132 The most common catheter removal interventions were daily audits of line removal and CLABSI rounds focused on ongoing catheter necessity.

Common implementation and sustainability interventions included outcome surveillance, such as feedback on CLABSI, and socio-adaptive interventions to prompt improvements in patient safety culture. Process and outcome surveillance as interventions were implemented in about one-quarter of the studies reviewed (AppendixTable 1).

CAUTI Interventional Study Results

Characteristics of Included CAUTI Studies

Of the 28 CAUTI studies that met the inclusion criteria (reporting outcomes for 30 intervention cohorts), 14 studies (reporting outcomes for 16 intervention cohorts) were performed in the US.28,34,53,66,68,133-141 Study designs included 2 RCTs (focused on urinary catheter avoidance or removal142 and chlorhexidine bathing68) and 26 nonrandomized, before–after studies28,30,33,34,53,66,109,114-116,133-141,143-149 (Appendix Table 1). The number of hospitals per study varied from 1 to 53, with the majority being single-hospital interventions.

CAUTI Study Outcomes

All 28 studies reported CAUTIs per 1000 catheter days for both intervention and comparison groups (Table 2). Preintervention or control CAUTI rates varied widely, with an overall mean of 12.5 CAUTIs per 1000 catheter days; US studies reported a range from 1.4 to 15.8 CAUTIs per 1000 catheter days; non-US studies reported a range from 0.8 to 90.1 CAUTIs per 1000 catheter days. Many studies had preintervention or control rates above the 2013 NHSN 75th percentiles.22 Postintervention CAUTI rates varied widely, with an overall mean of 7.0 CAUTIs per 1000 catheter days, including a US study range from 0 to 11.2 and a non-US study range from 1.9 to 65.7.

Overall (Table 2), 27 of the 30 intervention cohorts described in the 28 studies reported fewer CAUTIs, including all ICU types. Lower postintervention CAUTI rates were reported in 25 studies, with a mean 49.4% reduction, including 11 statistically significant reductions; many studies did not report the level of statistical significance or described inadequate power to detect a significant change (Table 2).

Urinary catheter utilization rates were reported for 11 studies (Table 2). A decreased urinary catheter utilization rate was reported in 7 studies (4 with statistically signficiant reductions), with a mean 16% reduction (Table 2). Other outcomes included cost savings, the potential for unintended negative outcomes, and clinician compliance with intervention components. Positive cost savings were reported in 5 studies.30,34,133,141,149

CAUTI Interventions

Of the 28 included CAUTI prevention studies, only 5 studied single interventions. Interventions were categorized in Table 1 by “life cycle” stages or as interventions to improve implementation and sustainability (Figure 2). Interventions to restrict indwelling urinary catheter use were common, including creating lists of approved indications selected by unit or hospital policy and requiring catheter orders with approved indications. Eight studies published approved indication lists.28,34,133-135,138,142,146 Although several studies describe the encouragement and use of bladder scanners and urinary catheter alternatives, none described purchasing these catheter alternatives.

Interventions to avoid indwelling urinary catheters included education about external catheters,28,34,109,133,140,144-146 urinary retention protocols,34,144,135,141 and bladder scanner simulation training.133 Interventions to improve aseptic insertion28,34,66,109,116,139-141-143-146,150 and maintenance care28,34,66,109,116,133,135,136,139-141,143-146,150 of urinary catheters were common. Four studies used a standardized urinary catheter kit or cart,28,34,139,142 and 2 studies used a commercial urinary catheter securement device.34,140 A CAUTI bundle checklist in daily patient care rounds was tested in 3 studies (Table 1).66,136,150 Reminder and stop order strategies, with the potential to reduce CAUTI rates by >50%,151 were included in 15 studies, with inteventions such as nurse-empowered stop orders. Several implementation and sustainability interventions were described, including socio-adaptive strategies such as holding multidisciplinary meetings to obtain unit or clinician feedback to inform design and improve buy-in and providing frequent feedback to ICU clinicians, including audits of catheter use appropriateness and catheter-associated infections.

 

 

DISCUSSION

This extensive literature review yielded a large body of literature demonstrating success in preventing CLABSI and CAUTI in all types of adult ICUs, including in general medical and surgical ICUs and in specialized units with historically higher rates, such as trauma, burn, and neurosurgical. Reported reductions in catheter infections were impressive (>65% for CLABSI or CRBSI and nearly 50% for CAUTI), though several studies had limited power to detect statistical significance. DURs were reported more rarely (particularly for vascular catheters) and often without power to detect statistical significance. Nevertheless, 7 studies reported reduced urinary catheter use (16% mean reduction), which would be anticipated to be clinically significant.

The conceptual model introduced for “Disrupting the Life Cycle of a Catheter” (Figure 2) can be a helpful tool for hospitalists and intensivists to assess and prioritize potential strategies for reducing catheter-associated infections. This study’s results indicate that CLABSI prevention studies often used interventions that optimize best practices during aseptic insertion and maintenance, but few studies emphasized reducing inappropriate central line use. Conversely, CAUTI prevention often targeted avoiding placement and prompting the removal of urinary catheters, with fewer studies evaluating innovative products or technical skill advancement for aseptic insertion or maintenance, though educational interventions to standardize aseptic catheter use were common. Recently, recommendations for reducing the inappropriate use of urinary catheters and intravenous catheters, including scenarios common in ICUs, were developed by using the rigorous RAND/UCLA Appropriateness Method152,153; these resources may be helpful to hospitalists designing and implementing interventions to reduce catheter use.

In reviewing the US studies of 5 units demonstrating the greatest success in preventing CLABSI56,62,65,78,83 and CAUTI,28,34,66,134 several shared features emerged. Interventions that addressed multiple steps within the life cycle of a catheter (avoidance, insertion, maintenance, and removal) were common. Previous work has shown that assuring compliance in infection prevention efforts is a key to success,154 and in both CLABSI and CAUTI studies, auditing was included in these successful interventions. Specifically for CLABSI, the checklist, a central quality improvement tool, was frequently associated with success. Unique to CAUTI, engaging a multidisciplinary team including nurse leadership seemed critical to optimize implementation and sustainability efforts. In addition, a focus on stage 3 (removal), including protocols to remove by default, was associated with success in CAUTI studies.

Our review was limited by a frequent lack of reporting of statistical significance or by inadequate power to detect a significant change and great variety. The ability to compare the impact of specific interventions is limited because studies varied greatly with respect to the type of intervention, duration of data collection, and outcomes assessed. We also anticipate that successful interventions are more likely to be published than are trials without success. Strengths include the use of a rigorous search process and the inclusion and review of several types of interventions implemented in ICUs.

In conclusion, despite high catheter use in ICUs, the literature includes many successful interventions for the prevention of vascular and urinary catheter infections in multiple ICU types. This review indicates that targeting multiple steps within the life cycle of a catheter, particularly when combined with interventions to optimize implementation and sustainability, can improve success in reducing CLABSI and CAUTI in the ICU.

Acknowledgments

The authors thank all members of the National Project Team for the AHRQ Safety Program for Intensive Care Units: Preventing CLABSI and CAUTI.

Disclosure

Agency for Healthcare Research and Quality (AHRQ) contract #HHSP233201500016I/HHSP23337002T provided funding for this study. J.M.’s other research is funded by AHRQ (2R01HS018334-04), the NIH-LRP program, the VA National Center for Patient Safety, VA Ann Arbor Patient Safety Center of Inquiry, the Health Research and Educational Trust, American Hospital Association and the Centers for Disease Control and Prevention. The findings and conclusions in this report are those of the authors and do not necessarily represent those of the sponsor, the Agency for Healthcare Research and Quality, or the US Department of Veterans Affairs. All authors report no conflicts of interest relevant to this article.

Central line–associated bloodstream infection (CLABSI) and catheter-associated urinary tract infection (CAUTI) are morbid and expensive healthcare-associated infections (HAIs).1-8 While these HAIs are prevalent in intensive care units (ICUs) and general wards, most of the research, prevention efforts, and financial penalties have been focused in the ICU.9,10 For hospitalists, who are taking a larger role in caring for the critically ill,11,12 it is optimal to understand best preventive practices.

There has been a national puTash to standardize procedures and products to prevent CLABSI and CAUTI.2,13-16 CLABSI has transitioned from a common ICU complication to a “never event.” Success has been reflected in the prevention of 25,000 CLABSIs over the last decade, translating to a 58% reduction in infections, with 6000 deaths prevented and $414 million saved.2 CLABSI prevention principles have been applied to CAUTI prevention (ie, aseptic insertion, maintenance care, prompting removal) but with slower adoption17 and fewer dramatic CAUTI reductions,18 due in part to weaker recognition19 of CAUTI as a serious clinical event, despite its morbidity20 and cost.21

Despite recent improvements in preventing HAIs, there is a marked variability in how hospitals perform in preventing these infections.22 To inform infection prevention strategies for a large-scale implementation project funded by the Agency for Healthcare Research and Quality and focused on ICUs with persistently elevated CLABSI and/or CAUTI rates,23 we performed a systematic search of interventions to prevent CLABSI and CAUTI in the ICU setting. This evidence was synthesized to help units select and prioritize interventions to prevent these HAIs.

METHODS

Literature Search Strategy

We performed a systematic search to identify CLABSI and CAUTI prevention studies and synthesized findings using a narrative review process. Using criteria developed and refined from seminal articles on the topic,10,14,24-34 we searched the PubMed and Cochrane databases from their inception to October of 2015 using Medical Subject Headings (MeSHs) for “central venous catheters,” “CLABSI,” “central line associated bloodstream infection,” “catheter related bloodstream infection,” “intravascular devices,” “urinary catheterization,” “urinary catheters,” “urinary tract infections,” “CAUTI,” and “catheter associated urinary tract infections” and filtered for articles containing the MeSHs “intensive care unit” and “ICU.” Supplemental Figure 1 details the search, yielding 102 studies for CLABSI and 28 studies for CAUTI, including 7 studies with CLABSI and CAUTI interventions.

Eligibility Criteria Review

Study Design

We included randomized and nonrandomized studies that implemented at least 1 intervention to prevent CLABSI or CAUTI in an adult ICU setting and reported the preintervention or control group data to compare with the postintervention data. We excluded general ward, outpatient/ambulatory, and neonatal/pediatric settings. Interventions to prevent CLABSI or CAUTI were included. We excluded interventions focused on diagnosis or treatment or those that lacked adequate description of the intervention for replication. Studies with interventions that are no longer standard of care in the United States (US) were excluded, as were studies not available in English.

Outcomes

Primary Outcomes for Central Vascular Catheter Infection

  • CLABSI: A lab-confirmed bloodstream infection in a patient who has had a central line for at least 48 hours on the date of the development of the bloodstream infection and without another known source of infection. We included studies that reported CLABSIs per 1000 central line days or those that provided data to permit calculation of this ratio. This measure is similar to current National Healthcare Safety Network (NHSN) surveillance definitions.22
  • Catheter-related bloodstream infection (CRBSI): A lab-confirmed bloodstream infection attributed to an intravascular catheter by a quantitative culture of the catheter tip or by differences in growth between catheter and peripheral venipuncture blood culture specimens.35 This microbiologic definition of a central line bloodstream infection was often used prior to NHSN reporting, with rates provided as the number of CRBSIs per 1000 central line days.
 

 

Primary Outcome for Urinary Catheter Infection

  • CAUTI: Urinary tract infection occurring in patients during or after the recent use of an indwelling urinary catheter. We included studies that reported CAUTIs per 1000 urinary catheter days or those that provided data to permit calculation of this ratio (similar to the current NHSN surveillance definitions).22 We excluded studies where CAUTI was defined as bacteriuria alone, without symptoms.

Secondary Outcomes

  • Central line utilization ratio: The device utilization ratio (DUR) measure of central line use is calculated as central line days divided by patient days.
  • Urinary catheter utilization ratio: The DUR measure of urinary catheter use is calculated as indwelling urinary catheter days divided by patient days, as used in NHSN surveillance, excluding other catheter types.22 We excluded other measures of urinary catheter use because of a large variation in definitions, which limits the ability to compare measures across studies.

Data Synthesis and Analysis

Information on the ICU and intervention type, intervention components, outcomes, and whether interventions were in use prior to the study was abstracted by CAUTI and CLABSI experts (JM and PKP) and confirmed by a second author.

We compared interventions found in the literature to components of the previously published urinary catheter “life cycle,” a conceptual model used to organize and prioritize interventions for a reduction in CAUTI (Figure 1).36

In this framework, there are 4 stages: (1) catheter placement, (2) catheter care, (3) catheter removal, and (4) catheter reinsertion. We sought to tailor the model for interventions in the ICU and for CLABSI prevention studies in addition to CAUTI prevention studies. In Table 1,
we also provided the recommendation level for each intervention type provided in the CLABSI and CAUTI prevention guidelines from the Centers for Disease Control and Prevention Healthcare Infection Control Practices Advisory Committee, as close as was feasible, as the guidelines describe general strategies, not specific interventions.13,37 

RESULTS

Conceptual Model for Disrupting the Life Cycle of a Catheter

Our data analysis demonstrated that components of the urinary catheter life cycle (Figure 1) were useful and could be applied to vascular catheters, but changes were needed to make the model more valuable to hospitalists implementing CLABSI and CAUTI prevention interventions. We found that the previously named stage 1 (catheter placement) is better described in 2 stages: stage 0, avoid catheter if possible, and stage 1, ensure aseptic placement. Additionally, we tailored the model to include actionable language, describing ways to disrupt the life cycle. Finally, we added a component to represent interventions to improve implementation and sustainability, such as auditing compliance and timely feedback to clinicians. Thus, we introduce a new conceptual model, “Disrupting the Life Cycle of a Catheter” (Figure 2)

—including stages appropriate for targeting both CAUTI and CLABSI prevention: (stage 0) avoid catheter if possible (ie, prevent catheter “life cycle” from beginning), (stage 1) ensure aseptic placement, (stage 2) optimize catheter maintenance care, and (stage 3) promptly remove unnecessary catheters—as well as apply interventions to improve implementation and sustainability. We used this modified conceptual model to synthesize the CLABSI and CAUTI prevention interventions found in the systematic search.

Central Vascular Catheter Interventional Study Results

Characteristics of Included Central Vascular Catheter Infection Studies

Of the 102 central vascular catheter (CVC) studies that met the inclusion criteria (reporting outcomes for 105 intervention cohorts), 59 studies10,14,16,24-27,38-89 reporting outcomes for 61 intervention cohorts were performed in the US. Study designs included 14 randomized controlled trials (RCTs)48,64,68,74,79,90-98 and 88 before–after studies (Appendix Table 1). 10,14,16,24-27,33,38-47,49-63,69-73,75-78,80-89,99-131 Many RCTs evaluated antimicrobial products (CVCs, hubs, bathing) as interventions,48,68,74,90-95,97,98 but a few RCTs studied interventions64,79,93 impacting catheter care or use (Appendix Table 1). Fifty-one studies took place in tertiary care hospitals and 55 in academic hospitals. Thirty-one studies were multicenter; the largest included 792 hospitals and 1071 ICUs.24 ICU bed size ranged from 5 to 59.

CVC Study Outcomes

Sixty-three studies reported CLABSI outcomes, and 39 reported CRBSI outcomes (Table 2). Many studies had preintervention or control rates above the 2013 NHSN 75th percentiles,22 which varied by ICU type. Preintervention or control infection rates per 1000 catheter days varied widely (means: CLABSI 7.5, CRBSI 6.3); US studies reported ranges of 1.1 to 12.1 CLABSI and 1.2 to 11.0 CRBSI per 1000 catheter days; non-US studies reported ranges of 1.4 to 45.9 CLABSI and 1.6 to 22.7 CRBSI per 1000 catheter days. Postintervention rates varied widely, with overall means of 2.8 CLABSI and 2.5 CRBSI per 1000 catheter days, including US study ranges of 0 to 8.9 CLABSI and 0 to 5.4 CRBSI, and non-US study ranges of 0 to 17.1 CLABSI and 0 to 15.9 CRBSI.

 

 

Overall (Table 2), 99 of the 105 intervention
cohorts described in the 102 studies
reported either a reduced CLABSI or a reduced CRBSI outcome, including all ICU types. Of the 63 CLABSI studies, 60 reported lower postintervention CLABSI rates, with a mean reduction of 62.6%, though only 36 demonstrated statistical significance. Of the 39 studies that reported CRBSI outcomes, 37 reported lower postintervention CRBSI rates, with a mean reduction of 66%, of which 23 were statistically significant.

Central line DURs were reported in only 5 studies; 3 reported decreased postintervention DURs (2 with statistical significance), with a mean 11.7% reduction (Table 2).

CVC Interventions

CVC study interventions are summarized in Table 1, categorized by catheter life cycle component (Figure 2). Thirty-two included studies used a single intervention to prevent CVC infection. Interventions to avoid placement when possible were infrequent. Insertion-stage interventions were common and included avoiding the femoral site during placement, ensuring maximal sterile barriers, and chlorhexidine skin preparation. Standardizing basic products for central line insertion was often done by providing ICUs with a CLABSI insertion kit or stocked cart. In some studies, this was implemented prior to the intervention, and in others, the kit or cart itself was the intervention. Maintenance-stage interventions included scrubbing the hub prior to use, replacing wet or soiled dressings, accessing the catheter with sterile devices, and performing aseptic dressing changes. A recent systematic review and meta-analysis of CVC infection prevention studies indicated that implementing care bundles and/or checklists appears to yield stronger risk reductions than interventions without these components.132 The most common catheter removal interventions were daily audits of line removal and CLABSI rounds focused on ongoing catheter necessity.

Common implementation and sustainability interventions included outcome surveillance, such as feedback on CLABSI, and socio-adaptive interventions to prompt improvements in patient safety culture. Process and outcome surveillance as interventions were implemented in about one-quarter of the studies reviewed (AppendixTable 1).

CAUTI Interventional Study Results

Characteristics of Included CAUTI Studies

Of the 28 CAUTI studies that met the inclusion criteria (reporting outcomes for 30 intervention cohorts), 14 studies (reporting outcomes for 16 intervention cohorts) were performed in the US.28,34,53,66,68,133-141 Study designs included 2 RCTs (focused on urinary catheter avoidance or removal142 and chlorhexidine bathing68) and 26 nonrandomized, before–after studies28,30,33,34,53,66,109,114-116,133-141,143-149 (Appendix Table 1). The number of hospitals per study varied from 1 to 53, with the majority being single-hospital interventions.

CAUTI Study Outcomes

All 28 studies reported CAUTIs per 1000 catheter days for both intervention and comparison groups (Table 2). Preintervention or control CAUTI rates varied widely, with an overall mean of 12.5 CAUTIs per 1000 catheter days; US studies reported a range from 1.4 to 15.8 CAUTIs per 1000 catheter days; non-US studies reported a range from 0.8 to 90.1 CAUTIs per 1000 catheter days. Many studies had preintervention or control rates above the 2013 NHSN 75th percentiles.22 Postintervention CAUTI rates varied widely, with an overall mean of 7.0 CAUTIs per 1000 catheter days, including a US study range from 0 to 11.2 and a non-US study range from 1.9 to 65.7.

Overall (Table 2), 27 of the 30 intervention cohorts described in the 28 studies reported fewer CAUTIs, including all ICU types. Lower postintervention CAUTI rates were reported in 25 studies, with a mean 49.4% reduction, including 11 statistically significant reductions; many studies did not report the level of statistical significance or described inadequate power to detect a significant change (Table 2).

Urinary catheter utilization rates were reported for 11 studies (Table 2). A decreased urinary catheter utilization rate was reported in 7 studies (4 with statistically signficiant reductions), with a mean 16% reduction (Table 2). Other outcomes included cost savings, the potential for unintended negative outcomes, and clinician compliance with intervention components. Positive cost savings were reported in 5 studies.30,34,133,141,149

CAUTI Interventions

Of the 28 included CAUTI prevention studies, only 5 studied single interventions. Interventions were categorized in Table 1 by “life cycle” stages or as interventions to improve implementation and sustainability (Figure 2). Interventions to restrict indwelling urinary catheter use were common, including creating lists of approved indications selected by unit or hospital policy and requiring catheter orders with approved indications. Eight studies published approved indication lists.28,34,133-135,138,142,146 Although several studies describe the encouragement and use of bladder scanners and urinary catheter alternatives, none described purchasing these catheter alternatives.

Interventions to avoid indwelling urinary catheters included education about external catheters,28,34,109,133,140,144-146 urinary retention protocols,34,144,135,141 and bladder scanner simulation training.133 Interventions to improve aseptic insertion28,34,66,109,116,139-141-143-146,150 and maintenance care28,34,66,109,116,133,135,136,139-141,143-146,150 of urinary catheters were common. Four studies used a standardized urinary catheter kit or cart,28,34,139,142 and 2 studies used a commercial urinary catheter securement device.34,140 A CAUTI bundle checklist in daily patient care rounds was tested in 3 studies (Table 1).66,136,150 Reminder and stop order strategies, with the potential to reduce CAUTI rates by >50%,151 were included in 15 studies, with inteventions such as nurse-empowered stop orders. Several implementation and sustainability interventions were described, including socio-adaptive strategies such as holding multidisciplinary meetings to obtain unit or clinician feedback to inform design and improve buy-in and providing frequent feedback to ICU clinicians, including audits of catheter use appropriateness and catheter-associated infections.

 

 

DISCUSSION

This extensive literature review yielded a large body of literature demonstrating success in preventing CLABSI and CAUTI in all types of adult ICUs, including in general medical and surgical ICUs and in specialized units with historically higher rates, such as trauma, burn, and neurosurgical. Reported reductions in catheter infections were impressive (>65% for CLABSI or CRBSI and nearly 50% for CAUTI), though several studies had limited power to detect statistical significance. DURs were reported more rarely (particularly for vascular catheters) and often without power to detect statistical significance. Nevertheless, 7 studies reported reduced urinary catheter use (16% mean reduction), which would be anticipated to be clinically significant.

The conceptual model introduced for “Disrupting the Life Cycle of a Catheter” (Figure 2) can be a helpful tool for hospitalists and intensivists to assess and prioritize potential strategies for reducing catheter-associated infections. This study’s results indicate that CLABSI prevention studies often used interventions that optimize best practices during aseptic insertion and maintenance, but few studies emphasized reducing inappropriate central line use. Conversely, CAUTI prevention often targeted avoiding placement and prompting the removal of urinary catheters, with fewer studies evaluating innovative products or technical skill advancement for aseptic insertion or maintenance, though educational interventions to standardize aseptic catheter use were common. Recently, recommendations for reducing the inappropriate use of urinary catheters and intravenous catheters, including scenarios common in ICUs, were developed by using the rigorous RAND/UCLA Appropriateness Method152,153; these resources may be helpful to hospitalists designing and implementing interventions to reduce catheter use.

In reviewing the US studies of 5 units demonstrating the greatest success in preventing CLABSI56,62,65,78,83 and CAUTI,28,34,66,134 several shared features emerged. Interventions that addressed multiple steps within the life cycle of a catheter (avoidance, insertion, maintenance, and removal) were common. Previous work has shown that assuring compliance in infection prevention efforts is a key to success,154 and in both CLABSI and CAUTI studies, auditing was included in these successful interventions. Specifically for CLABSI, the checklist, a central quality improvement tool, was frequently associated with success. Unique to CAUTI, engaging a multidisciplinary team including nurse leadership seemed critical to optimize implementation and sustainability efforts. In addition, a focus on stage 3 (removal), including protocols to remove by default, was associated with success in CAUTI studies.

Our review was limited by a frequent lack of reporting of statistical significance or by inadequate power to detect a significant change and great variety. The ability to compare the impact of specific interventions is limited because studies varied greatly with respect to the type of intervention, duration of data collection, and outcomes assessed. We also anticipate that successful interventions are more likely to be published than are trials without success. Strengths include the use of a rigorous search process and the inclusion and review of several types of interventions implemented in ICUs.

In conclusion, despite high catheter use in ICUs, the literature includes many successful interventions for the prevention of vascular and urinary catheter infections in multiple ICU types. This review indicates that targeting multiple steps within the life cycle of a catheter, particularly when combined with interventions to optimize implementation and sustainability, can improve success in reducing CLABSI and CAUTI in the ICU.

Acknowledgments

The authors thank all members of the National Project Team for the AHRQ Safety Program for Intensive Care Units: Preventing CLABSI and CAUTI.

Disclosure

Agency for Healthcare Research and Quality (AHRQ) contract #HHSP233201500016I/HHSP23337002T provided funding for this study. J.M.’s other research is funded by AHRQ (2R01HS018334-04), the NIH-LRP program, the VA National Center for Patient Safety, VA Ann Arbor Patient Safety Center of Inquiry, the Health Research and Educational Trust, American Hospital Association and the Centers for Disease Control and Prevention. The findings and conclusions in this report are those of the authors and do not necessarily represent those of the sponsor, the Agency for Healthcare Research and Quality, or the US Department of Veterans Affairs. All authors report no conflicts of interest relevant to this article.

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125. Rosenthal VD, Maki DG, Rodrigues C, et al. Impact of International Nosocomial Infection Control Consortium (INICC) strategy on central line-associated bloodstream infection rates in the intensive care units of 15 developing countries. Infect Control Hosp Epidemiol. 2010;31(12):1264-1272. PubMed
126. Salama MF, Jamal W, Mousa HA, Rotimi V. Implementation of central venous catheter bundle in an intensive care unit in Kuwait: Effect on central line-associated bloodstream infections. J Infect Public Health. 2016;9(1):34-41. PubMed
127. Santana SL, Furtado GH, Wey SB, Medeiros EA. Impact of an education program on the incidence of central line-associated bloodstream infection in 2 medical-surgical intensive care units in Brazil. Infect Control Hosp Epidemiol. 2008;29(12):1171-1173. PubMed
128. Scheithauer S, Lewalter K, Schröder J, et al. Reduction of central venous line-associated bloodstream infection rates by using a chlorhexidine-containing dressing. Infection. 2014;42(1):155-159. PubMed

129. Singh S, Kumar RK, Sundaram KR, et al. Improving outcomes and reducing costs by modular training in infection control in a resource-limited setting. Int J Qual Health Care. 2012;24(6):641-648. PubMed
130. Zingg W, Cartier V, Inan C, et al. Hospital-wide multidisciplinary, multimodal intervention programme to reduce central venous catheter-associated bloodstream infection. PLoS One. 2014;9(4):e93898. PubMed
131. Zingg W, Imhof A, Maggiorini M, Stocker R, Keller E, Ruef C. Impact of a prevention strategy targeting hand hygiene and catheter care on the incidence of catheter-related bloodstream infections. Crit Care Med. 2009;37(7):2167-2173. PubMed
132. Blot K, Bergs J, Vogelaers D, Blot S, Vandijck D. Prevention of central line-associated bloodstream infections through quality improvement interventions: a systematic review and meta-analysis. Clin Infect Dis. 2014;59(1):96-105. PubMed
133. Alexaitis I, Broome B. Implementation of a nurse-driven protocol to prevent catheter-associated urinary tract infections. J Nurs Care Qual. 2014;29(3):245-252. PubMed
134. Elpern EH, Killeen K, Ketchem A, Wiley A, Patel G, Lateef O. Reducing use of indwelling urinary catheters and associated urinary tract infections. Am J Crit Care. 2009;18(6):535-541. PubMed

135. Fuchs MA, Sexton DJ, Thornlow DK, Champagne MT. Evaluation of an evidence-based, nurse-driven checklist to prevent hospital-acquired catheter-associated urinary tract infections in intensive care units. J Nurs Care Qual. 2011;26(2):101-109. PubMed
136. Jain M, Miller L, Belt D, King D, Berwick DM. Decline in ICU adverse events, nosocomial infections and cost through a quality improvement initiative focusing on teamwork and culture change. Qual Saf Health Care. 2006;15(4):235-239. PubMed
137. Popp JA, Layon AJ, Nappo R, Richards WT, Mozingo DW. Hospital-acquired infections and thermally injured patients: chlorhexidine gluconate baths work. Am J Infect Control. 2014;42(2):129-132. PubMed
138. Reilly L, Sullivan P, Ninni S, Fochesto D, Williams K, Fetherman B. Reducing foley catheter device days in an intensive care unit: using the evidence to change practice. AACN Adv Crit Care. 2006;17(3):272-283. PubMed
139. Saint S, Fowler KE, Sermak K, et al. Introducing the No Preventable Harms campaign: creating the safest health care system in the world, starting with catheter-associated urinary tract infection prevention. Am J Infect Control. 2015;43(3):254-259. PubMed
140. Schelling K, Palamone J, Thomas K, et al. Reducing catheter-associated urinary tract infections in a neuro-spine intensive care unit. Am J Infect Control. 2015;43(8):892-894. PubMed
141. Sutherland T, Beloff J, McGrath C, et al. A single-center multidisciplinary initiative to reduce catheter-associated urinary tract infection rates: Quality and financial implications. Health Care Manag (Frederick). 2015;34(3):218-224. PubMed
142. Chen YY, Chi MM, Chen YC, Chan YJ, Chou SS, Wang FD. Using a criteria-based reminder to reduce use of indwelling urinary catheters and decrease urinary tract infections. Am J Crit Care. 2013;22(2):105-114. PubMed
143. Amine AE, Helal MO, Bakr WM. Evaluation of an intervention program to prevent hospital-acquired catheter-associated urinary tract infections in an ICU in a rural Egypt hospital. GMS Hyg Infect Control. 2014;9(2):Doc15. PubMed
144. Kanj SS, Zahreddine N, Rosenthal VD, Alamuddin L, Kanafani Z, Molaeb B. Impact of a multidimensional infection control approach on catheter-associated urinary tract infection rates in an adult intensive care unit in Lebanon: International Nosocomial Infection Control Consortium (INICC) findings. Int J Infect Dis. 2013;17(9):e686-e690. PubMed
145. Navoa-Ng JA, Berba R, Rosenthal VD, et al. Impact of an International Nosocomial Infection Control Consortium multidimensional approach on catheter-associated urinary tract infections in adult intensive care units in the Philippines: International Nosocomial Infection Control Consortium (INICC) findings. J Infect Public Health. 2013;6(5):389-399. PubMed
146. Rosenthal VD, Todi SK, Álvarez-Moreno C, et al. Impact of a multidimensional infection control strategy on catheter-associated urinary tract infection rates in the adult intensive care units of 15 developing countries: findings of the International Nosocomial Infection Control Consortium (INICC). Infection. 2012;40(5):517-526. PubMed
147. Salama MF, Jamal WY, Mousa HA, Al-Abdulghani KA, Rotimi VO. The effect of hand hygiene compliance on hospital-acquired infections in an ICU setting in a Kuwaiti teaching hospital. J Infect Public Health. 2013;6(1):27-34. PubMed
148. Seyman D, Oztoprak N, Berk H, Kizilates F, Emek M. Weekly chlorhexidine douche: does it reduce healthcare-associated bloodstream infections? Scand J Infect Dis. 2014;46(10):697-703. PubMed
149. Apisarnthanarak A, Thongphubeth K, Sirinvaravong S, et al. Effectiveness of multifaceted hospitalwide quality improvement programs featuring an intervention to remove unnecessary urinary catheters at a tertiary care center in Thailand. Infect Control Hosp Epidemiol. 2007;28(7):791-798. PubMed
150. Marra AR, Sampaio Camargo TZ, Gonçalves P, et al. Preventing catheter-associated urinary tract infection in the zero-tolerance era. Am J Infect Control. 2011;39(10):817-822. PubMed
151. Meddings J, Rogers MA, Krein SL, Fakih MG, Olmsted RN, Saint S. Reducing unnecessary urinary catheter use and other strategies to prevent catheter-associated urinary tract infection: an integrative review. BMJ Qual Saf. 2014;23(4):277-289. PubMed
152. Chopra V, Flanders SA, Saint S, et al. The Michigan Appropriateness Guide for Intravenous Catheters (MAGIC): results from a multispecialty panel using the RAND/UCLA appropriateness method. Ann Intern Med. 2015;163(6 Suppl):S1-S40. PubMed
153. Meddings J, Saint S, Fowler KE, et al. The Ann Arbor Criteria for appropriate urinary catheter use in hospitalized medical patients: results obtained by using the RAND/UCLA appropriateness method. Ann Intern Med. 2015;162(9 Suppl):S1-S34. PubMed
154. Furuya EY, Dick AW, Herzig CT, Pogorzelska-Maziarz M, Larson EL, Stone PW. Central Line-Associated Bloodstream Infection Reduction and Bundle Compliance in Intensive Care Units: A National Study. Infect Control Hosp Epidemiol. 2016;37(7):805-810. PubMed

 

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Moving antibiotic stewardship from theory to practice

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Moving antibiotic stewardship from theory to practice

We both attend on the Infectious Disease consult team in Veterans Affairs (VA) Hospitals, and predictably the conversation on afternoon rounds often revolves around antibiotics. When we have those discussions, our focus is not on a need to “preserve antibiotics” so they might be available to some unknown patient in the future. Rather, we are working with the primary team to provide the very best treatment for the patient entrusted to our care in the bed right in front of us. We believe it is in this context—providing optimal patient care—that the current efforts in the United States to improve antibiotic use should be viewed.

The growing challenges posed by antibiotic-resistant infections and the related threat of Clostridium difficile infection combine to sicken more than 2 million people each year and contribute to the deaths of more than 25,000 patients.1 Improving antibiotic use through antibiotic stewardship is often proposed to hospitalists as an important part of stemming this tide. While this is true, even as infectious disease specialists with strong interests in antimicrobial stewardship we do not find that pitch compelling when we are on clinical service.

What motivates us to optimize antibiotic use for our patients is the evidence that doing so will have direct and immediate benefits to the patients under our care. Improving antibiotic use has been proven to decrease a patient’s risk of acquiring C. difficile infection or an antibiotic-resistant infection not at some ill-defined time in the future, but during their current hospital stay.2,3 Even more important, support from antibiotic stewardship programs has been proven to improve infection cure rates and reduce the risk of treatment failure for hospitalized patients.4 The bottom line of antibiotic stewardship is better patient care. Sometimes that means narrowing or stopping antibiotics to reduce the risks of adverse events. In other cases, like in the treatment of suspected sepsis, it means ensuring patients get broad spectrum antibiotics quickly.

The patient care benefits of improving antibiotic use led the Centers for Disease Control and Prevention (CDC) to issue a call in 2014 for all hospitals to have antibiotic stewardship programs, and to the development of The Core Elements of Hospital Antibiotic Stewardship Programs to support that effort. As of January 1, 2017, antibiotic stewardship programs that incorporate all the CDC core elements became an accreditation requirement of The Joint Commission, and the Centers for Medicare and Medicaid Services has proposed making the same requirement of all hospitals that participate in their payment programs.

This means the question is no longer whether we should have antibiotic stewardship efforts in hospitals, but how we can do this most effectively. As the physicians who provide the most care in hospitals, hospitalists are best positioned to turn stewardship theories into practice. The article from Graber et al.5 in this issue of the Journal of Hospital Medicine provides some important information that can help busy hospitalists incorporate stewardship into daily practice. The authors reviewed their experience with implementing stewardship efforts in VA hospitals to see which specific interventions were most likely to translate into improved antibiotic use. Based on their findings, we offer some suggestions for three conditions: pneumonia, urinary tract infection (UTI), and skin and soft tissue infection (SSTI). Together, these conditions drive roughly two-thirds of all antibiotic use in US hospitals.6

STEWARDSHIP IN PRACTICE: PNEUMONIA

The literature on treatment of pneumonia is increasingly demonstrating that shorter use of antibiotics is often better.7 Even though current guidelines recommend 5 to 7 days of antibiotics for uncomplicated community-acquired pneumonia, average durations of therapy are often longer.8 Previous work published in the Journal of Hospital Medicine focused on improving antimicrobial documentation as well as access to local clinical guidelines and implementing a 72-hour antimicrobial “time out” by hospitalists.9 When these multimodal interventions tailored for hospitalists were in place, utilization of antibiotics improved. Graber et al.5 also found that facility educational programs for prudent antimicrobial use and frequency of de-escalation review were associated with decreased overall antimicrobial use. Providing vague recommendations on antibiotic course, or none at all, at discharge or sign-out can lead to unnecessary antibiotics or an extended course of them. Pneumonia-specific interventions could target duration by outlining antibiotic course in hospitalist progress notes and at hand-off.

 

 

STEWARDSHIP IN PRACTICE: UTI

Misuse of antibiotics in UTI often stems from overtreatment of asymptomatic bacteriuria or unneeded diagnostic testing. Often, the pivotal step in avoiding unnecessary treatment lies in the ordering of the urine culture.10 Graber et al.5 showed that order sets were associated with decreased antimicrobial use. In the case of UTI, hospitalists could work with the stewardship team to design order sets that guide providers to appropriate reasons for ordering a urine culture. Order sets could also help providers recognize important patient-specific risks for certain antibiotics, such as the risk of C. difficile with fluoroquinolones in an elderly patient. Targeting different steps in overutilization of antibiotics would encompass more prescribers and could lead to reducing other unnecessary testing, which is a current focus for many hospitalists.

STEWARDSHIP IN PRACTICE: SSTI

Skin and soft tissue infections (SSTI) also offer a specific disease state to use order sets and education to improve duration of antibiotics, decrease overuse of broad spectrum antibiotics, and reduce unnecessary diagnostic studies. For example, gram negative and/or anaerobic coverage are rarely indicated in treating SSTIs but are often used. SSTI-specific order sets and guidelines have already been shown to improve both diagnostic work-up and antibiotic treatment.11 As the providers who manage most of these infections in hospitals, hospitalists are ideally positioned to inform the development of SSTI order sets and pathways. The work by Graber et al.5 provides some important insights into how we can effectively implement interventions to improve antibiotic use. These insights have never been more important as more hospitals move toward starting or expanding antibiotic stewardship programs. As leaders in patient safety and quality, and as the most important antibiotic prescribers in hospitals, hospitalists must play a central role in stewardship if we are to make meaningful progress.

Disclosure

Nothing to report.

 

References

1. Centers for Disease Control and Prevention. Antibiotic Resistance Threats in the United States, 2013. https://www.cdc.gov/drugresistance/pdf/ar-threats-2013-508.pdf. Accessed April 12, 2017.
2. Feazel LM, Malhotra A, Perencevich EN, Kaboli P, Diekema DJ, Schweizer ML. Effect of antibiotic stewardship programmes on Clostridium difficile incidence: a systematic review and meta-analysis. J Antimicrob Chemother. 2014;69(7):1748-1754. PubMed
3. Singh N, Rogers P, Atwood CW, Wagener MM, Yu VL. Short-course empiric antibiotic therapy for patients with pulmonary infiltrates in the intensive care unit. A proposed solution for indiscriminate antibiotic prescription. Am J Respir Crit Care Med. 2000;162(2 Pt 1):505-511. PubMed
4. Fishman N. Antimicrobial stewardship. Am J Med. 2006;119(6 Suppl 1):S53-S61; discussion S62-S70. PubMed
5. Graber CJ, Jones MM, Chou AF, et al. Association of inpatient antimicrobial utilization measures with antimicrobial stewardship activities and facility characteristics of Veterans Affairs medical centers. J Hosp Med. 2017;12:301-309. PubMed
6. Magill SS, Edwards JR, Beldavs ZG, et al. Prevalence of antimicrobial use in US acute care hospitals, May-September 2011. JAMA. 2014;312(14):1438-1446. PubMed
7. Viasus D, Vecino-Moreno M, De La Hoz JM, Carratala J. Antibiotic stewardship in community-acquired pneumonia. Expert Rev Anti Infect Ther. 2016:1-2019. PubMed
8. Avdic E, Cushinotto LA, Hughes AH, et al. Impact of an antimicrobial stewardship intervention on shortening the duration of therapy for community-acquired pneumonia. Clin Infect Dis. 2012;54(11):1581-1587. PubMed
9. Mack MR, Rohde JM, Jacobsen D, et al. Engaging hospitalists in antimicrobial stewardship: Lessons from a multihospital collaborative. J Hosp Med. 2016;11(8):576-580. PubMed
10. Trautner BW, Grigoryan L, Petersen NJ, et al. Effectiveness of an Antimicrobial Stewardship Approach for Urinary Catheter-Associated Asymptomatic Bacteriuria. JAMA Intern Med. 2015;175(7):1120-1127. PubMed
11. Jenkins TC, Knepper BC, Sabel AL, et al. Decreased antibiotic utilization after implementation of a guideline for inpatient cellulitis and cutaneous abscess. Arch Intern Med. 2011;171(12):1072-1079. PubMed

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We both attend on the Infectious Disease consult team in Veterans Affairs (VA) Hospitals, and predictably the conversation on afternoon rounds often revolves around antibiotics. When we have those discussions, our focus is not on a need to “preserve antibiotics” so they might be available to some unknown patient in the future. Rather, we are working with the primary team to provide the very best treatment for the patient entrusted to our care in the bed right in front of us. We believe it is in this context—providing optimal patient care—that the current efforts in the United States to improve antibiotic use should be viewed.

The growing challenges posed by antibiotic-resistant infections and the related threat of Clostridium difficile infection combine to sicken more than 2 million people each year and contribute to the deaths of more than 25,000 patients.1 Improving antibiotic use through antibiotic stewardship is often proposed to hospitalists as an important part of stemming this tide. While this is true, even as infectious disease specialists with strong interests in antimicrobial stewardship we do not find that pitch compelling when we are on clinical service.

What motivates us to optimize antibiotic use for our patients is the evidence that doing so will have direct and immediate benefits to the patients under our care. Improving antibiotic use has been proven to decrease a patient’s risk of acquiring C. difficile infection or an antibiotic-resistant infection not at some ill-defined time in the future, but during their current hospital stay.2,3 Even more important, support from antibiotic stewardship programs has been proven to improve infection cure rates and reduce the risk of treatment failure for hospitalized patients.4 The bottom line of antibiotic stewardship is better patient care. Sometimes that means narrowing or stopping antibiotics to reduce the risks of adverse events. In other cases, like in the treatment of suspected sepsis, it means ensuring patients get broad spectrum antibiotics quickly.

The patient care benefits of improving antibiotic use led the Centers for Disease Control and Prevention (CDC) to issue a call in 2014 for all hospitals to have antibiotic stewardship programs, and to the development of The Core Elements of Hospital Antibiotic Stewardship Programs to support that effort. As of January 1, 2017, antibiotic stewardship programs that incorporate all the CDC core elements became an accreditation requirement of The Joint Commission, and the Centers for Medicare and Medicaid Services has proposed making the same requirement of all hospitals that participate in their payment programs.

This means the question is no longer whether we should have antibiotic stewardship efforts in hospitals, but how we can do this most effectively. As the physicians who provide the most care in hospitals, hospitalists are best positioned to turn stewardship theories into practice. The article from Graber et al.5 in this issue of the Journal of Hospital Medicine provides some important information that can help busy hospitalists incorporate stewardship into daily practice. The authors reviewed their experience with implementing stewardship efforts in VA hospitals to see which specific interventions were most likely to translate into improved antibiotic use. Based on their findings, we offer some suggestions for three conditions: pneumonia, urinary tract infection (UTI), and skin and soft tissue infection (SSTI). Together, these conditions drive roughly two-thirds of all antibiotic use in US hospitals.6

STEWARDSHIP IN PRACTICE: PNEUMONIA

The literature on treatment of pneumonia is increasingly demonstrating that shorter use of antibiotics is often better.7 Even though current guidelines recommend 5 to 7 days of antibiotics for uncomplicated community-acquired pneumonia, average durations of therapy are often longer.8 Previous work published in the Journal of Hospital Medicine focused on improving antimicrobial documentation as well as access to local clinical guidelines and implementing a 72-hour antimicrobial “time out” by hospitalists.9 When these multimodal interventions tailored for hospitalists were in place, utilization of antibiotics improved. Graber et al.5 also found that facility educational programs for prudent antimicrobial use and frequency of de-escalation review were associated with decreased overall antimicrobial use. Providing vague recommendations on antibiotic course, or none at all, at discharge or sign-out can lead to unnecessary antibiotics or an extended course of them. Pneumonia-specific interventions could target duration by outlining antibiotic course in hospitalist progress notes and at hand-off.

 

 

STEWARDSHIP IN PRACTICE: UTI

Misuse of antibiotics in UTI often stems from overtreatment of asymptomatic bacteriuria or unneeded diagnostic testing. Often, the pivotal step in avoiding unnecessary treatment lies in the ordering of the urine culture.10 Graber et al.5 showed that order sets were associated with decreased antimicrobial use. In the case of UTI, hospitalists could work with the stewardship team to design order sets that guide providers to appropriate reasons for ordering a urine culture. Order sets could also help providers recognize important patient-specific risks for certain antibiotics, such as the risk of C. difficile with fluoroquinolones in an elderly patient. Targeting different steps in overutilization of antibiotics would encompass more prescribers and could lead to reducing other unnecessary testing, which is a current focus for many hospitalists.

STEWARDSHIP IN PRACTICE: SSTI

Skin and soft tissue infections (SSTI) also offer a specific disease state to use order sets and education to improve duration of antibiotics, decrease overuse of broad spectrum antibiotics, and reduce unnecessary diagnostic studies. For example, gram negative and/or anaerobic coverage are rarely indicated in treating SSTIs but are often used. SSTI-specific order sets and guidelines have already been shown to improve both diagnostic work-up and antibiotic treatment.11 As the providers who manage most of these infections in hospitals, hospitalists are ideally positioned to inform the development of SSTI order sets and pathways. The work by Graber et al.5 provides some important insights into how we can effectively implement interventions to improve antibiotic use. These insights have never been more important as more hospitals move toward starting or expanding antibiotic stewardship programs. As leaders in patient safety and quality, and as the most important antibiotic prescribers in hospitals, hospitalists must play a central role in stewardship if we are to make meaningful progress.

Disclosure

Nothing to report.

 

We both attend on the Infectious Disease consult team in Veterans Affairs (VA) Hospitals, and predictably the conversation on afternoon rounds often revolves around antibiotics. When we have those discussions, our focus is not on a need to “preserve antibiotics” so they might be available to some unknown patient in the future. Rather, we are working with the primary team to provide the very best treatment for the patient entrusted to our care in the bed right in front of us. We believe it is in this context—providing optimal patient care—that the current efforts in the United States to improve antibiotic use should be viewed.

The growing challenges posed by antibiotic-resistant infections and the related threat of Clostridium difficile infection combine to sicken more than 2 million people each year and contribute to the deaths of more than 25,000 patients.1 Improving antibiotic use through antibiotic stewardship is often proposed to hospitalists as an important part of stemming this tide. While this is true, even as infectious disease specialists with strong interests in antimicrobial stewardship we do not find that pitch compelling when we are on clinical service.

What motivates us to optimize antibiotic use for our patients is the evidence that doing so will have direct and immediate benefits to the patients under our care. Improving antibiotic use has been proven to decrease a patient’s risk of acquiring C. difficile infection or an antibiotic-resistant infection not at some ill-defined time in the future, but during their current hospital stay.2,3 Even more important, support from antibiotic stewardship programs has been proven to improve infection cure rates and reduce the risk of treatment failure for hospitalized patients.4 The bottom line of antibiotic stewardship is better patient care. Sometimes that means narrowing or stopping antibiotics to reduce the risks of adverse events. In other cases, like in the treatment of suspected sepsis, it means ensuring patients get broad spectrum antibiotics quickly.

The patient care benefits of improving antibiotic use led the Centers for Disease Control and Prevention (CDC) to issue a call in 2014 for all hospitals to have antibiotic stewardship programs, and to the development of The Core Elements of Hospital Antibiotic Stewardship Programs to support that effort. As of January 1, 2017, antibiotic stewardship programs that incorporate all the CDC core elements became an accreditation requirement of The Joint Commission, and the Centers for Medicare and Medicaid Services has proposed making the same requirement of all hospitals that participate in their payment programs.

This means the question is no longer whether we should have antibiotic stewardship efforts in hospitals, but how we can do this most effectively. As the physicians who provide the most care in hospitals, hospitalists are best positioned to turn stewardship theories into practice. The article from Graber et al.5 in this issue of the Journal of Hospital Medicine provides some important information that can help busy hospitalists incorporate stewardship into daily practice. The authors reviewed their experience with implementing stewardship efforts in VA hospitals to see which specific interventions were most likely to translate into improved antibiotic use. Based on their findings, we offer some suggestions for three conditions: pneumonia, urinary tract infection (UTI), and skin and soft tissue infection (SSTI). Together, these conditions drive roughly two-thirds of all antibiotic use in US hospitals.6

STEWARDSHIP IN PRACTICE: PNEUMONIA

The literature on treatment of pneumonia is increasingly demonstrating that shorter use of antibiotics is often better.7 Even though current guidelines recommend 5 to 7 days of antibiotics for uncomplicated community-acquired pneumonia, average durations of therapy are often longer.8 Previous work published in the Journal of Hospital Medicine focused on improving antimicrobial documentation as well as access to local clinical guidelines and implementing a 72-hour antimicrobial “time out” by hospitalists.9 When these multimodal interventions tailored for hospitalists were in place, utilization of antibiotics improved. Graber et al.5 also found that facility educational programs for prudent antimicrobial use and frequency of de-escalation review were associated with decreased overall antimicrobial use. Providing vague recommendations on antibiotic course, or none at all, at discharge or sign-out can lead to unnecessary antibiotics or an extended course of them. Pneumonia-specific interventions could target duration by outlining antibiotic course in hospitalist progress notes and at hand-off.

 

 

STEWARDSHIP IN PRACTICE: UTI

Misuse of antibiotics in UTI often stems from overtreatment of asymptomatic bacteriuria or unneeded diagnostic testing. Often, the pivotal step in avoiding unnecessary treatment lies in the ordering of the urine culture.10 Graber et al.5 showed that order sets were associated with decreased antimicrobial use. In the case of UTI, hospitalists could work with the stewardship team to design order sets that guide providers to appropriate reasons for ordering a urine culture. Order sets could also help providers recognize important patient-specific risks for certain antibiotics, such as the risk of C. difficile with fluoroquinolones in an elderly patient. Targeting different steps in overutilization of antibiotics would encompass more prescribers and could lead to reducing other unnecessary testing, which is a current focus for many hospitalists.

STEWARDSHIP IN PRACTICE: SSTI

Skin and soft tissue infections (SSTI) also offer a specific disease state to use order sets and education to improve duration of antibiotics, decrease overuse of broad spectrum antibiotics, and reduce unnecessary diagnostic studies. For example, gram negative and/or anaerobic coverage are rarely indicated in treating SSTIs but are often used. SSTI-specific order sets and guidelines have already been shown to improve both diagnostic work-up and antibiotic treatment.11 As the providers who manage most of these infections in hospitals, hospitalists are ideally positioned to inform the development of SSTI order sets and pathways. The work by Graber et al.5 provides some important insights into how we can effectively implement interventions to improve antibiotic use. These insights have never been more important as more hospitals move toward starting or expanding antibiotic stewardship programs. As leaders in patient safety and quality, and as the most important antibiotic prescribers in hospitals, hospitalists must play a central role in stewardship if we are to make meaningful progress.

Disclosure

Nothing to report.

 

References

1. Centers for Disease Control and Prevention. Antibiotic Resistance Threats in the United States, 2013. https://www.cdc.gov/drugresistance/pdf/ar-threats-2013-508.pdf. Accessed April 12, 2017.
2. Feazel LM, Malhotra A, Perencevich EN, Kaboli P, Diekema DJ, Schweizer ML. Effect of antibiotic stewardship programmes on Clostridium difficile incidence: a systematic review and meta-analysis. J Antimicrob Chemother. 2014;69(7):1748-1754. PubMed
3. Singh N, Rogers P, Atwood CW, Wagener MM, Yu VL. Short-course empiric antibiotic therapy for patients with pulmonary infiltrates in the intensive care unit. A proposed solution for indiscriminate antibiotic prescription. Am J Respir Crit Care Med. 2000;162(2 Pt 1):505-511. PubMed
4. Fishman N. Antimicrobial stewardship. Am J Med. 2006;119(6 Suppl 1):S53-S61; discussion S62-S70. PubMed
5. Graber CJ, Jones MM, Chou AF, et al. Association of inpatient antimicrobial utilization measures with antimicrobial stewardship activities and facility characteristics of Veterans Affairs medical centers. J Hosp Med. 2017;12:301-309. PubMed
6. Magill SS, Edwards JR, Beldavs ZG, et al. Prevalence of antimicrobial use in US acute care hospitals, May-September 2011. JAMA. 2014;312(14):1438-1446. PubMed
7. Viasus D, Vecino-Moreno M, De La Hoz JM, Carratala J. Antibiotic stewardship in community-acquired pneumonia. Expert Rev Anti Infect Ther. 2016:1-2019. PubMed
8. Avdic E, Cushinotto LA, Hughes AH, et al. Impact of an antimicrobial stewardship intervention on shortening the duration of therapy for community-acquired pneumonia. Clin Infect Dis. 2012;54(11):1581-1587. PubMed
9. Mack MR, Rohde JM, Jacobsen D, et al. Engaging hospitalists in antimicrobial stewardship: Lessons from a multihospital collaborative. J Hosp Med. 2016;11(8):576-580. PubMed
10. Trautner BW, Grigoryan L, Petersen NJ, et al. Effectiveness of an Antimicrobial Stewardship Approach for Urinary Catheter-Associated Asymptomatic Bacteriuria. JAMA Intern Med. 2015;175(7):1120-1127. PubMed
11. Jenkins TC, Knepper BC, Sabel AL, et al. Decreased antibiotic utilization after implementation of a guideline for inpatient cellulitis and cutaneous abscess. Arch Intern Med. 2011;171(12):1072-1079. PubMed

References

1. Centers for Disease Control and Prevention. Antibiotic Resistance Threats in the United States, 2013. https://www.cdc.gov/drugresistance/pdf/ar-threats-2013-508.pdf. Accessed April 12, 2017.
2. Feazel LM, Malhotra A, Perencevich EN, Kaboli P, Diekema DJ, Schweizer ML. Effect of antibiotic stewardship programmes on Clostridium difficile incidence: a systematic review and meta-analysis. J Antimicrob Chemother. 2014;69(7):1748-1754. PubMed
3. Singh N, Rogers P, Atwood CW, Wagener MM, Yu VL. Short-course empiric antibiotic therapy for patients with pulmonary infiltrates in the intensive care unit. A proposed solution for indiscriminate antibiotic prescription. Am J Respir Crit Care Med. 2000;162(2 Pt 1):505-511. PubMed
4. Fishman N. Antimicrobial stewardship. Am J Med. 2006;119(6 Suppl 1):S53-S61; discussion S62-S70. PubMed
5. Graber CJ, Jones MM, Chou AF, et al. Association of inpatient antimicrobial utilization measures with antimicrobial stewardship activities and facility characteristics of Veterans Affairs medical centers. J Hosp Med. 2017;12:301-309. PubMed
6. Magill SS, Edwards JR, Beldavs ZG, et al. Prevalence of antimicrobial use in US acute care hospitals, May-September 2011. JAMA. 2014;312(14):1438-1446. PubMed
7. Viasus D, Vecino-Moreno M, De La Hoz JM, Carratala J. Antibiotic stewardship in community-acquired pneumonia. Expert Rev Anti Infect Ther. 2016:1-2019. PubMed
8. Avdic E, Cushinotto LA, Hughes AH, et al. Impact of an antimicrobial stewardship intervention on shortening the duration of therapy for community-acquired pneumonia. Clin Infect Dis. 2012;54(11):1581-1587. PubMed
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Issue
Journal of Hospital Medicine 12(5)
Issue
Journal of Hospital Medicine 12(5)
Page Number
382-383
Page Number
382-383
Publications
Publications
Topics
Article Type
Display Headline
Moving antibiotic stewardship from theory to practice
Display Headline
Moving antibiotic stewardship from theory to practice
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© 2017 Society of Hospital Medicine

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Address for correspondence and reprint requests: Payal K. Patel, MD, MPH, University of Michigan, Infectious Disease Clinic, Taubman Center, Floor 3 Reception D, 1500 East Medical Center Drive, SPC 5352, Ann Arbor, MI 48109; Telephone: 734-845-5695; Fax: 734-845-3290; E-mail: [email protected].

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