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Comparison of cefazolin administered as a continuous or intermittent infusion for prophylaxis of surgical site infections in adult patients undergoing cardiac or neurologic surgery

Published online by Cambridge University Press:  03 December 2025

Richard H. Drew Open the ORCID record for Richard H. Drew [Opens in a new window] ,
Nicholas A. Turner Open the ORCID record for Nicholas A. Turner [Opens in a new window] ,
Elizabeth Keil Open the ORCID record for Elizabeth Keil [Opens in a new window]  and
Jessica Seidelman
Richard H. Drew*
Affiliation:
Duke University School of Medicine (Infectious Diseases), Durham, NC, USA Campbell University College of Pharmacy & Health Sciences, Buies Creek, NC, USA
Nicholas A. Turner
Affiliation:
Duke University School of Medicine (Infectious Diseases), Durham, NC, USA
Elizabeth Keil
Affiliation:
HCA HealthONE Swedish, Englewood, CO, USA
Jessica Seidelman
Affiliation:
Duke University School of Medicine (Infectious Diseases), Durham, NC, USA
*
Corresponding author: Richard H. Drew; Email: richard.drew@duke.edu
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Abstract

In a propensity-matched cohort of adult cardiac or neurosurgical procedures (n = 1,342), infection was less frequent with continuous infusion (1.8%) versus intermittent cefazolin (2.4%), though the difference was statistically non-significant (−0.6%, 95% CI−2.3 to 1.1; p = 0.57). The 0% infection rate among cardiac cases receiving continuous cefazolin infusion warrants further investigation.

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Concise Communication
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Infection Control & Hospital Epidemiology , First View , pp. 1 - 4
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (https://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided that no alterations are made and the original article is properly cited. The written permission of Cambridge University Press or the rights holder(s) must be obtained prior to any commercial use and/or adaptation of the article.
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© The Author(s), 2025. Published by Cambridge University Press on behalf of The Society for Healthcare Epidemiology of America

Introduction

Surgical site infections (SSIs) occur in up to 3% of patients undergoing surgery, representing a significant cause of morbidity, prolonged hospitalization, and mortality. Reference Seidelman, Mantyh and Anderson1 Cefazolin is the primary choice for SSI prevention across a variety of surgical procedures, including cardiovascular and neurologic surgery. Reference Berríos-Torres, Umscheid and Bratzler2Reference Ling, Apisarnthanarak and Abbas4 Recommended dosing, timing of administration prior to incision, and intervals for redosing are designed to optimize efficacy for infection prevention. Reference Berríos-Torres, Umscheid and Bratzler2Reference Ling, Apisarnthanarak and Abbas4 While beta-lactams are commonly administered by continuous infusion for treatment (rather than prevention) of infection, data regarding continuous cefazolin infusion for SSI prophylaxis are sparse. Reference Shoulders, Crow and Davis5Reference Yu, Dooley and Woods9 Current surgical prophylaxis guidelines do not differentiate between intermittent and continuous infusion in their recommendations for cefazolin use in SSI prophylaxis. Reference Berríos-Torres, Umscheid and Bratzler2Reference Ling, Apisarnthanarak and Abbas4

Objectives

Beginning in August 2016, Duke University Health (DUH) permitted use of continuous infusion cefazolin in patients undergoing cardiac surgery, later followed by neurosurgery. The objective of this retrospective cohort project was to compare the incidence of culture-confirmed SSI through postoperative day 90 (POD90) in patients undergoing cardiovascular or neurologic surgery receiving cefazolin prophylaxis by either intermittent or continuous infusion.

Study design

The protocol was reviewed by the DUH Institutional Review Board and designated as Exempted Human Research. We identified patients ≥18yrs of age who underwent select cardiac or neurologic surgery (using National Healthcare Safety Network [NHSN Codes] CABG, coronary artery bypass graft; CARD, cardiac surgery; CRAN, craniotomy; FUSN-ACDF, Spinal Fusion —Anterior Cervical; FUSN-nonACDF, Spinal Fusion—Non-Anterior Cervical) at Duke University Health facilities from 1/2/2018 to 1/29/25. All included patients received at least one weight-based loading dose of cefazolin followed by either continuous infusion (defined as least 1 intraoperative continuous infusion of 0.5–1gm/hr) or weight-based intermittent dosing (based on surgery time, renal function, and blood loss) until incision closure. Patients were followed through POD90 for SSIs per standard National Healthcare Safety Network (NHSN) SSI surveillance by infection preventionists [Surgical Site Infection Event. V. January 2025. Available at: https://www.cdc.gov/nhsn/pdfs/pscmanual/9pscssicurrent.pdf, accessed 5/6/24]. All culture-confirmed infections (superficial + deep organ space) through day 90 are included; superficial infection observation period was thru POD30.

Statistical analysis

We used propensity score matching (PSM) to address selection bias among prophylactic antibiotic strategies. Propensity scores for continuous infusion cefazolin were estimated using a logistic regression model with 8 covariates thought to influence surgical site infection risk: age, sex, body mass index, wound class, ASA rating, diabetes mellitus, NHSN surgical category, and additional receipt of vancomycin as part of perioperative prophylaxis. Subjects receiving continuous infusion cefazolin were matched 1:1 with subjects receiving intermittent cefazolin using the MatchIt package in R. Infection-free survival was modeled using Cox proportional hazards with a robust variance estimate to account for matching. The proportional hazards assumption was verified with Schoenfield residual plots. Survival analysis was conducted with the survival and survminer packages in R. 10 P values < 0.05 were considered statistically significant.

Results

A total of 11,431 unique eligible subjects were identified. Summary characteristics for the overall and propensity-matched cohorts are shown in Table 1. Imbalance by wound class, ASA rating, diabetes, and NHSN surgery category indicates likely selection bias for continuous vs intermittent infusion regimens. Characteristics were well-balanced after propensity matching. Within the matched cohort of 1,342 subjects, the median age was 62.4 yrs. Most subjects were male (56.2%), had a clean surgical wound (98.7%), ASA Class III (severe systemic disease) 47.4%, and received coadministration of vancomycin for prophylaxis (45.5%).

Table 1. Demographics and clinical characteristics of overall and matched cohorts

BMI, body mass index; IQ25, IQ75, interquartile range 25%, 75%.

NHSN procedure codes: CABG, coronary artery bypass graft; CARD, cardiac surgery; CRAN, craniotomy; FUSN-ACDF, Spinal Fusion – Anterior Cervical; FUSN-nonACDF, Spinal Fusion – Non-Anterior Cervical; SMD, standardized mean difference.

Within the matched cohort, the continuous infusion group had a numerically lower SSI rate than the intermittent group (1.8% vs 2.4%, respectively), though this failed to reach statistical significance (difference −0.6%, 95% CI−2.3 to 1.1, p = 0.57 by McNemar’s test).

Time-to-event analysis yielded consistent results: the hazard ratio for infection-free survival with continuous relative to intermittent infusion was 0.74 (95% CI 0.35–1.57, p = 0.44) (see Figure 1). An exploratory subgroup analysis among cardiac and neurosurgical cases found no apparent difference in infection-free survival with continuous infusion among neurosurgical cases. Although limited by small numbers, 0 infections were observed among the 167 matched cardiac surgery cases receiving continuous infusion versus 4 infections among the 167 receiving intermittent.

Figure 1. Surgical site infection-free survival—matched cohort, all surgery categories.

Discussion

We evaluated the impact of cefazolin administration method—continuous versus intermittent infusion—on 90-day incidence of SSIs within a cohort of adult cardiac and neurosurgical patients. Although SSIs were numerically less frequent with cefazolin prophylaxis by continuous infusion—particularly within the cardiac surgery subgroup—the differences failed to reach statistical significance.

Continuous infusions of cefazolin have been employed to optimize the pharmacokinetic-pharmacodynamic relationship while facilitating optimal tissue concentrations. However, data to support such practices are sparse. A pharmacokinetic study in patients undergoing cardiopulmonary bypass (CPB) reported serum target trough concentrations were maintained more effectively in patients receiving cefazolin by continuous infusion. Reference Adembri, Ristori and Chelazzi7 In patients undergoing neurosurgical procedures, total drug exposure in plasma was similar in both intermittent and continuous cefazolin infusion groups. Reference Yu, Dooley and Woods9

Clinical data examining the impact of cefazolin infusion method on SSI incidence are also sparse. Several prior studies have observed lower SSI rates with continuous rather than intermittently dosed cefazolin—mostly among cardiac procedures—though nearly all are hindered by either risk of confounding or small sample sizes after careful propensity matching.

In the present study, the small number of matched subjects and nearly bimodal distribution in propensity scores indicates significant confounding within the overall (unmatched) cohort. While stringent propensity matching successfully minimized this confounding, we were left with much smaller case numbers for outcome assessment—limiting power.

To further explore potential differences within the treatment groups, infection-free survival was compared between exposure groups and was also not statistically significant. Exploratory subgroup analyses did suggest a potential difference in benefit between cardiac and neurosurgical procedures. Low observed infection rates and diverging infection-free survival curves suggest continuous infusion regimens may have greater benefit for cardiac surgeries—a finding that warrants further investigation, as larger numbers may be necessary to confirm benefit.

There are several limitations to our study. The retrospective cohort within a single health system may not be extrapolated to other institutions. Our assignment of infusion method was dependent on the presence of a cefazolin infusion rate; therefore, a missing value in that field may have been assigned to intermittent group in error. However, infusion method assignments followed closely with expected use (shift toward intermittent) due to the IV fluid shortage in late 2024. The primary endpoint (culture-confirmed infections) may have excluded those clinically diagnosed and meeting additional NHSN supportive criteria for infection. Given its retrospective nature, we were unable to determine compliance with cefazolin prophylaxis guidelines. However, the compliance in each group would likely closely mimic “real-world” performance. Finally, differences in infusion method may not be reflected solely in prophylactic efficacy. Expense, medication waste, drug compatibility with medications using the same IV line, equipment needs, missed or delayed redosing, and training needs for OR staff (if the process differs from other surgeries) should also be considered.

In summary, among a matched cohort of 1,342 cardiac and neurosurgical patients, we were unable to detect a difference in SSI through postoperative day 90. Subgroup analysis revealed potential differences between these patient groups that, while small, may combine with logistic advantages to the use of continuous infusions of cefazolin particularly for cardiac surgery.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/ice.2025.10365.

Acknowledgements

Dr. Sarah Lewis, Dr. Michael Tichey, Dr. Christine Sarubbi, Dr. Michael Yarrington

Disclosures

JLS is a consultant for Osteal Therapeutics, 3M, Nichols & Associates, and Bendin Sumrall & Ladner, LLC.

NAT has received research funding from Purio and PDI, and served as a clinical trial adjudicator for Basilea.

Though not directly related to this study, NAT is supported by a career development grant from the National Institute of Allergy and Infectious Diseases (NIAID) of the National institutes of Health (NIH; grant K23-Al177941). The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

RHD receives publication royalties from UpToDate.

References

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Figure 0

Table 1. Demographics and clinical characteristics of overall and matched cohorts

Figure 1

Figure 1. Surgical site infection-free survival—matched cohort, all surgery categories.

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