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pdfSupplementary Appendix
This appendix has been provided by the authors to give readers additional information about their work.
Supplement to: Magill SS, O’Leary E, Janelle SJ, et al. Changes in prevalence of health care–associated infections
in U.S. hospitals. N Engl J Med 2018;379:1732-44. DOI: 10.1056/NEJMoa1801550
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table of Contents
Emerging Infections Program Hospital Prevalence Survey Team members................................................. 1
Funding source and author roles .................................................................................................................. 2
Methods: hospital and patient selection ...................................................................................................... 3
Methods: training and data collection.......................................................................................................... 4
Methods: National Healthcare Safety Network surveillance definitions ..................................................... 5
Methods: modeling and national burden estimates .................................................................................... 6
Results: comparison of prevalence of health care-associated infections .................................................... 8
Discussion: limitations .................................................................................................................................. 9
Figure S1...................................................................................................................................................... 11
Table S1 ....................................................................................................................................................... 12
Table S2 ....................................................................................................................................................... 13
Table S3 ....................................................................................................................................................... 15
Table S4 ....................................................................................................................................................... 18
Table S5 ....................................................................................................................................................... 21
Table S6 ....................................................................................................................................................... 22
Table S7 ....................................................................................................................................................... 24
Table S8 ....................................................................................................................................................... 26
Table S9 ....................................................................................................................................................... 28
Table S10 ..................................................................................................................................................... 31
References .................................................................................................................................................. 33
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Emerging Infections Program Hospital Survey Team members
The following individuals were members of the Emerging Infections Program Hospital Survey
Team and non-author contributors:
California Emerging Infections Program, Oakland, CA: Deborah Godine, RN, CIC; Linda Frank, RN, BSN;
Lauren Pasutti, MPH; Erin Parker, MPH; Brittany Martin, MPH; Karen Click
Colorado Department of Public Health and Environment, Denver, CO: Helen Johnston, MPH; Sarabeth
Friedman, CNM, MSN; Annika Jones, MPH; Tabetha Kosmicki, MPH
Connecticut Emerging Infections Program, New Haven and Hartford, CT: James Meek, MPH; Richard
Melchreit, MD; James Fisher, MPH; Amber Maslar
Division of Healthcare Quality Promotion, Centers for Disease Control and Prevention, Atlanta, GA:
Katherine Allen-Bridson, RN, BSN, MScPH, CIC; Angela Anttila, PhD, MSN, NPC, CIC (CACI, Inc.); Henrietta
Smith, RN, MSN, CIC (Northrop Grumman); Anthony Fiore, MD, MPH
Georgia Emerging Infections Program, Decatur, GA: Susan L. Morabit, MSN, RN, PHCNS-BC, CIC; Lewis
Perry, DrPH, MPH, RN; Scott K. Fridkin, MD
Maryland Department of Health, Baltimore, MD: Elisabeth Vaeth, MPH; Rebecca Perlmutter, MPH, CIC
Minnesota Department of Health, St. Paul, MN: Jane Harper, BSN, MS, CIC; Annastasia Gross, MPH,
MT(ASCP); Nabeelah Rahmathullah, MBBS, MPH; Brittany Von Bank, MPH
New Mexico Department of Health, Santa Fe, NM: Lourdes M. Irizarry, MD; Joan Baumbach, MD, MS,
MPH
New York Emerging Infections Program and University of Rochester Medical Center, Rochester, NY: Gail
Quinlan, RN, CIC; Anita Gellert, RN
Oregon Health Authority, Portland, OR: Alexia Zhang, MPH
Tennessee Department of Health, Nashville, TN: Patricia Lawson, RN, MS, MPH; Raphaelle H. Beard,
MPH; Vicky P. Reed, RN; Daniel Muleta, MD, MPH
1
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Funding source and author roles
This work was supported through the Centers for Disease Control and Prevention’s Emerging
Infections Program Cooperative Agreement with funds from the CDC’s Division of Healthcare Quality
Promotion in the National Center for Emerging and Zoonotic Infectious Diseases. Author roles are as
follows:
Project concept or design: Shelley S. Magill, Joelle Nadle, Sarah Janelle, Wendy Bamberg, Susan M. Ray,
Lucy E. Wilson, Katherine Richards, Ruth Lynfield, Linn Warnke, Ghinwa Dumyati, Zintars Beldavs,
Marion A. Kainer, Jonathan R. Edwards
Data acquisition: Joelle Nadle, Sarah Janelle, Tolulope Oyewumi, Samantha Greissman, Meghan
Maloney, Nicolai Buhr, Katherine Richards, Linn Warnke, Jean Rainbow, Deborah L. Thompson, Marla
Sievers, Shamima Sharmin, Emily B. Hancock, Cathleen Concannon, Valerie Ocampo, Monika Samper,
Ruby M. Phelps, Cindy Gross, Denise Leaptrot, Janet Brooks, Eileen Scalise, Farzana Badrun
Data analysis: Shelley S. Magill, Erin O’Leary, Jonathan R. Edwards
Data interpretation: Shelley S. Magill, Erin O’Leary, Joelle Nadle, Susan M. Ray, Lucy E. Wilson, Katherine
Richards, Nicolai Buhr, Ruth Lynfield, Shamima Sharmin, Ghinwa Dumyati, Zintars Beldavs, Marion A.
Kainer, Cindy Gross, Denise Leaptrot, Janet Brooks, Eileen Scalise, Jonathan R. Edwards
Shelley S. Magill wrote the first draft of the manuscript. All of the authors vouch for the completeness
and accuracy of the data, and all authors decided to submit the manuscript.
2
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Methods: hospital and patient selection
To engage additional hospitals beyond those that participated in the 2011 survey, Emerging
Infections Program sites used the same approach employed in the 2011 survey.1 Each site recruited
additional hospitals using randomly sorted hospital lists stratified by bed size, with the following goals in
each bed size stratum: 13 small (<150 beds), 9 medium (150–399 beds), and 3 large (≥400 beds)
hospitals. Participation was voluntary.
The numbers of randomly selected acute care inpatients to be included in the survey were
determined by hospital bed size category, as in 2011. For small and medium hospitals, the sample goal
was 75 patients; if the hospital had < 75 patients on the survey date then all patients were to be
included. For large hospitals, the sample goal was 100 patients.
3
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Methods: training and data collection
Hospital staff participating in 2015 survey activities were asked to view recorded survey
operations training or join a live training session prior to their hospitals’ survey dates. Emerging
Infections Program staff participated in live training or viewed recorded training on survey operations,
health care-associated infection (HAI) definitions, and data collection. Training provided for the 2015
survey was similar to training provided for the 2011 survey, except for the option of viewing recorded
training sessions. Emerging Infections Program data collectors also received training for expanded data
collection activities in the 2015 survey, including HAI data collection using two different sets of National
Healthcare Safety Network HAI surveillance definitions (the 2011 definitions and the 2015 definitions).
Hospitals in the 2015 survey were asked to complete a questionnaire that included information
on hospital characteristics and infection control and antimicrobial stewardship policies and practices.
Emerging Infections Program staff also gathered limited information on selected hospital characteristics.
Hospital data were entered into a Research Electronic Data Capture (REDCap)2 database hosted at CDC,
and were included with patient data in the analysis. Emerging Infections Program sites had the option of
utilizing their data collectors for all aspects of patient data collection, or engaging hospital staff to collect
a limited amount of demographic and clinical information for each surveyed patient in their facility. In
addition, in the 2015 survey Emerging Infections Program sites and hospitals were given the option of
collecting the initial, limited demographic and clinical data on the survey date or retrospectively. If these
data were collected retrospectively, data collectors were instructed only to report information present
in the medical record up until 17:00 hours on the survey date. Emerging Infections Program staff
reviewed medical records to collect detailed information on antimicrobial use and HAIs; hospital staff
did not participate in these reviews. CDC staff provided support to Emerging Infections Program data
collectors for questions regarding National Healthcare Safety Network HAI definitions, HAI
determinations, or other aspects of data collection.
4
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Methods: National Healthcare Safety Network surveillance definitions
The Emerging Infections Program hospital prevalence surveys of HAIs and antimicrobial use are
conducted using the National Healthcare Safety Network’s acute care hospital HAI surveillance
definitions. Each year CDC updates these surveillance definitions to improve the objectivity, usability or
clinical credibility of the definitions. In 2015, major revisions to the National Healthcare Safety Network
definitions were implemented. Therefore, in the 2015 survey, we opted to collect HAI data using two
different sets of National Healthcare Safety Network HAI definitions. Data were collected using the same
HAI definitions used in the 2011 survey3 for the purposes of comparing HAI prevalence and distribution
in the 2011 and 2015 surveys, which is the focus of this manuscript. Data were also collected using the
2015 definitions for the five most common HAI types (pneumonia, surgical-site infections,
gastrointestinal infections, bloodstream infections, and urinary tract infections) and for ventilatorassociated events.4 A detailed description of the National Healthcare Safety Network HAI definition
changes implemented in 2015 is beyond the scope of this appendix; in general, changes were designed
to reduce the subjectivity of the surveillance definitions by providing specific time periods within which
HAI definition criteria must be met, and update HAI definition criteria to reflect current practices in
diagnostic testing (see https://www.cdc.gov/nhsn/pdfs/newsletters/vol9-3-eNL-Sept-2014.pdf). A
“repeat infection timeframe” was also implemented in the National Healthcare Safety Network in 2015,
specifying a duration of 14 days for most HAIs, but this timeframe was not strictly implemented in the
2015 survey due to its cross-sectional design. We did not have the data to be able to apply the 2015
definitions retroactively to patients in the 2011 survey.
5
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Methods: modeling and national burden estimates
We developed approaches to handling missing or unknown data to maximize the numbers of
patients whose data could be included in the modeling process. For patients who had surgical-site
infections (SSIs) with onset before hospitalization but for whom a specific onset date was unknown, we
created a proxy onset date. First, we determined the median number of days from the operative
procedure date to SSI onset date in patients with known SSI onset dates before admission. We added
the median number of days from procedure to SSI onset to the operative procedure dates of patients
with unknown SSI onset dates before admission to create proxy SSI onset dates. For one patient with
pneumonia for whom onset date was unknown, but onset was before hospitalization (such infections
could be deemed HAIs if related to a prior, recent hospitalization), we set the onset date equal to the
admission date. There were also patients with missing hospital length of stay data. Of these 9 patients, 8
were still in the hospital 6 months after the survey date when follow up for discharge and outcome
information ended. For these patients, a proxy for hospital length of stay was considered the time from
admission to last follow up date. For the ninth patient, hospital discharge date was unknown.
We developed national burden estimates for 2015 using a process similar to the method used in
2011.1 First, we used logistic and log-binomial regression models to identify patient and hospital factors
associated with HAIs, and we assessed model fit using the likelihood ratio test and Akaike Information
Criterion score. Log-binomial regression models were compared and verified for robustness using
Poisson regression in a Generalized Estimating Equations framework. Second, we used factors
independently associated with HAIs to partition survey data and 2014 National Inpatient Sample (NIS)
data (Healthcare Cost and Utilization Project, Agency for Healthcare Research and Quality) into patient
strata.5 We predicted HAI prevalence within each stratum using the final log-binomial regression model.
We calculated HAI incidence in each stratum with the formula of Rhame and Sudderth,6 using the
predicted prevalence and stratum-specific data from the prevalence survey on hospital length of stay
6
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
and time to HAI onset. Finally, we generated national burden estimates of hospital patients with HAIs by
multiplying HAI incidence by the total number of discharges in each NIS stratum and summing across
strata. The point estimate of the total number of patients with HAIs and the upper and lower bounds of
the 95% confidence interval (CI) were rounded to the nearest hundred.
7
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Results: comparison of HAI prevalence
Among patients in the 2015 survey, we compared the percentage of patients with HAIs detected
by the 2011 definitions vs. the 2015 definitions. When the 2011 definitions were applied, 342 of 12,299
patients had pneumonia, SSIs, bloodstream infections, urinary tract infections, or gastrointestinal
infections (2.8%; 95% confidence interval [CI], 2.5 to 3.1). When the 2015 definitions were applied, 345
patients had ≥1 of these 5 HAI types (2.8%; 95% CI, 2.5 to 3.1). A comparison of the distribution of HAI
types using the 2011 definitions vs. the 2015 definitions is shown in Table S5.
8
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Discussion: limitations
Additional limitations of our prevalence survey include its restriction to only those HAIs that
were active at the time of the survey, defined as HAIs with signs or symptoms on the survey date, or
HAIs still being treated with antimicrobial agents. Although we used the same definitions in 2011 and in
2015, practice changes could have affected detection of active HAIs. For example, substantial changes in
medical record documentation of signs and symptoms or antimicrobial prescribing could have affected
our ability to detect HAIs. Similar findings were observed in the subset of hospitals that participated in
both surveys and in the subset of patients who received antimicrobial agents and met our HAI review
criterion, suggesting that changes in documentation and prescribing likely do not account for the
observed decrease in prevalence.
Point prevalence surveys have the potential to over-represent HAIs of longer duration, such as
SSIs, since on any given day patients with such infections are more likely to have signs or symptoms or
be receiving antibiotics than patients with shorter-duration infections, such as urinary tract infections.7
Although this prevalence survey bias could influence the distribution of HAI types detected in the
survey, it would not be expected to affect substantially the comparison of overall prevalence in 2011
compared with 2015.
We used the Rhame and Sudderth formula for converting HAI prevalence to incidence,4 which is
a method with well-described limitations.8-12 The formula was published almost 40 years ago, and its
components may not fully account for the complexities of present-day health care delivery. For
example, the formula incorporates a term representing the time from hospital admission to HAI onset,
which may present challenges for HAIs that begin prior to the prevalence survey hospitalization. As an
example, most SSIs have their onset outside the hospital, following discharge from the hospitalization
during which the operative procedure occurred, and some investigators have reported a poor
correlation between observed SSI incidence and SSI incidence calculated using the Rhame and Sudderth
9
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
formula.12 Similarly, patients may be readmitted for Clostridioides difficile infections that begin in the
outpatient setting but are related to a prior hospitalization. Although the HAI surveillance definitions we
used allow for detection of certain HAIs that are present on admission, whether the timing of these
infections is adequately accounted for in the conversion of prevalence to incidence is unclear.
The formula is intended to capture active and cured infections and uses the time from
admission to the first HAI in patients with multiple HAIs;6 because of our survey methods, we detected
only active HAIs, and we cannot assume that all infections active at the time of the survey were in fact
patients’ first HAIs during the hospitalization. For patients with multiple HAIs active at the time of the
survey, we used time from admission to onset of the first infection in our analysis.
Finally, Rhame and Sudderth recommended using the average daily census and average daily
admissions from the survey month to approximate the average length of stay of all hospital patients in
their formula. They cautioned that using the average length of stay of all patients on the survey date
would result in an artificially inflated length of stay, since prevalence surveys are biased toward longerstay patients.6 Although we asked hospitals to provide data on average daily census from a recent year,
we did not have data on average daily census or daily admissions at the time of the survey, and
therefore we used the average length of stay of patients included in the survey. It is unlikely that this or
the other limitations discussed above affected the results of our analysis comparing 2011 and 2015 HAI
prevalence, since we used the same approach in both surveys.
10
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Figure S1. Numbers of patients surveyed by month, 2011 vs. 2015.
6000
5196
(46%)
5000
4236
(38%)
3422
(28%)
4000
3000
2000
1000
0
2952
(24%)
2917
(24%)
1960
(16%)
1048
667 (9%)
(6%)
May
801
(7%)
June
July
2011
2015
11
August
382
(3%)
September
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S1. Catchment areas, hospitals and patients included in the survey, by Emerging Infections
Program site.
No. of
No. of
Hospitals (%)
Patients (%)
Site
Survey Catchment Areaa
California
3-county San Francisco Bay area
14 (7.0)
919 (7.5)
Colorado
11-county Front Range areab
16 (8.0)
1078 (8.8)
Connecticut
Entire state
14 (7.0)
1049 (8.5)
Georgia
20-county metropolitan Atlanta area
22 (11.1)
1525 (12.4)
Maryland
Entire state
22 (11.1)
1437 (11.7)
Minnesota
Entire state
25 (12.6)
1377 (11.2)
New Mexico
Entire state
18 (9.0)
876 (7.1)
New York
10-county western New York areac
22 (11.1)
1312 (10.7)
Oregon
10-county metropolitan Portland and Eugene area
22 (11.1)
1370 (11.1)
Tennessee
Entire state
24 (12.1)
1356 (11.0)
199 (100)
12,299 (100)
Total
Percentages may not total 100 due to rounding.
a
Catchment areas for the 2015 survey were the same as for the 2011 survey unless otherwise specified.
Catchment area for the 2011 survey consisted of 5 Front Range counties.
b
c
Catchment area for the 2011 survey consisted of 9 western New York counties.
12
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S2. Characteristics of hospitals participating in the 2015 survey.
Hospitals
(N=199)
Characteristic
Region — no. (%)
Midwest
25 (12.6)
Northeast
36 (18.1)
South
68 (34.2)
West
70 (35.2)
Locationa — no. (%)
Rural
22 (11.1)
Urban
177 (88.9)
Teaching hospitalb — no. (%)
Yes
88 (44.2)
No
111 (55.8)
Infection preventionist staffingc — no. (%)
At least 1 full-time equivalent
171 (85.9)
Less than 1 full-time equivalent
28 (14.1)
Hospital epidemiologist staffingd — no. (%)
At least 1 full-time equivalent
42 (21.1)
Less than 1 full-time equivalent
157 (78.9)
Percentages may not total 100 due to rounding.
a
Urban vs. rural location was determined based on 2010 U.S. Census data. Hospitals located in counties
that are part of metropolitan statistical areas were considered urban. Hospitals located in counties in
micropolitan statistical areas or rural areas were considered rural.
13
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Teaching hospitals were defined on the basis of membership in the Council of Teaching Hospitals, or
b
having an American Medical Association-approved residency program, or a self-reported or calculated
intern/resident to bed ratio of ≥0.25. This is similar to how teaching status was defined in the 2014
National Inpatient Sample.13 Teaching status was initially missing for one hospital; this hospital was
subsequently categorized as a teaching hospital based on information submitted by Emerging Infections
Program staff.
c
Hospitals were asked to submit staffing data from the most recent year for which data were available:
2015 (51 hospitals, 26%); 2014 (146, 73%); or 2013 (2, 1%). In one instance where data were reported in
aggregate for >1 hospital in the same system, Emerging Infections Program site staff were consulted,
and aggregated data were apportioned to each hospital.
Hospitals were asked to submit staffing data from the most recent year for which data were available:
d
2015 (52 hospitals, 26%); 2014 (145, 73%); 2013 (2, 1%). In one instance where data were reported in
aggregate for >1 hospital in the same system, Emerging Infections Program site staff were consulted,
and aggregated data were apportioned to each hospital.
14
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S3. Additional demographic and clinical characteristics of surveyed patients, 2015.
Characteristic
Patients
Patients
All Patients
without HAIs
with HAIs
P
(N=12,299)
(N=11,905)
(N=394)
Valuea,b
Sex — no. (%)
0.01
Female
6822 (55.5)
6628 (55.7)
194 (49.2)
Male
5476 (44.5)
5276 (44.3)
200 (50.8)
1 (<0.1)
1 (<0.1)
0
Missing data
Age category — no. (%)
<1 year
<0.001
1339 (10.9)
1319 (11.1)
20 (5.1)
1-17 years
527 (4.3)
514 (4.3)
13 (3.3)
18-24 years
457 (3.7)
444 (3.7)
13 (3.3)
25-44 years
1951 (15.9)
1910 (16.0)
41 (10.4)
45-64 years
3211 (26.1)
3056 (25.7)
155 (39.3)
65-84 years
3756 (30.5)
3634 (30.5)
122 (31.0)
≥85 years
1058 (8.6)
1028 (8.6)
30 (7.6)
Race — no. (%)
0.33
American Indian or Alaska Native
142 (1.2)
140 (1.2)
2 (0.5)
Asian
312 (2.5)
307 (2.6)
5 (1.3)
2007 (16.3)
1939 (16.3)
68 (17.3)
615 (5.0)
598 (5.0)
17 (4.3)
Black or African-American
Multiple races or other unspecified
race
15
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Patients
Patients
All Patients
without HAIs
with HAIs
P
(N=12,299)
(N=11,905)
(N=394)
Valuea,b
41 (0.3)
40 (0.3)
1 (0.3)
White
8161 (66.4)
7895 (66.3)
266 (67.5)
Missing data
1021 (8.3)
986 (8.3)
35 (8.9)
Characteristic
Native Hawaiian or other Pacific
Islander
Ethnicity — no. (%)
Hispanic or Latino
0.79
977 (7.9)
944 (7.9)
33 (8.4)
Not Hispanic or Latino
7991 (65.0)
7734 (65.0)
257 (65.2)
Missing data
3331 (27.1)
3227 (27.1)
104 (26.4)
Primary payer — no. (%)
0.39
Medicaid
2446 (19.9)
2377 (20.0)
69 (17.5)
Medicare
4952 (40.3)
4781 (40.2)
171 (43.4)
No charge
11 (<0.1)
10 (<0.1)
1 (0.3)
Other
309 (2.5)
300 (2.5)
9 (2.3)
Private
3850 (31.3)
3724 (31.3)
126 (32.0)
Self-pay
430 (3.5)
421 (3.5)
9 (2.3)
Missing data
301 (2.5)
292 (2.5)
9 (2.3)
Normal
3601 (29.3)
3464 (29.1)
137 (34.8)
0.12
Overweight
2887 (23.5)
2789 (23.4)
98 (24.9)
0.91
Obese
3846 (31.3)
3727 (31.3)
119 (30.2)
0.15
Body mass index categoryc — no. (%)
16
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Characteristic
Missing data
Patients
Patients
All Patients
without HAIs
with HAIs
P
(N=12,299)
(N=11,905)
(N=394)
Valuea,b
1965 (16.0)
1925 (16.2)
40 (10.2)
0.001
Outcome of hospitalization — no. (%)
Died
<0.001d
358 (2.9)
313 (2.6)
45 (11.4)
11,927 (97.0)
11,579 (97.3)
348 (88.3)
Still in hospital 6 months after survey
8 (<0.1)
7 (<0.1)
1 (0.3)
Missing data
6 (<0.1)
6 (<0.1)
0
Survived
Percentages may not total 100 due to rounding.
a
Chi-square test, unless otherwise indicated.
Comparison excludes patients with missing data, unless otherwise indicated.
b
c
Body mass index (BMI) categories were generated using reported or calculated body mass index for
patients ≥2 years of age. BMI was considered missing for children <2 years of age, even if BMI was
reported in the medical record. For adults (≥20 years), normal weight was BMI <25; overweight
25≤BMI<30; and obese BMI ≥30. For children (2–19 years), normal weight was BMI <85th percentile for
age and sex; overweight BMI between the 85th and 95th percentile for age and sex; and obese BMI ≥95th
percentile for age and sex.
Comparison includes patients who were known to have survived or died during the hospitalization;
d
patients still in the hospital and those with unknown outcome were excluded.
17
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S4. Comparison of additional, selected patient characteristics, 2011 vs. 2015 survey.
Characteristic
2011 Survey
2015 Survey
Patients
Patients
(N=11,282)
(N=12,299)
Sex — no. (%)
0.83
Female
6236 (55.3)
6822 (55.5)
Male
5034 (44.6)
5476 (44.5)
12 (0.1)
1 (<0.1)
Missing data
Age category — no. (%)
<1 year
0.08
1151 (10.2)
1339 (10.9)
1–17 years
479 (4.3)
527 (4.3)
18–24 years
462 (4.1)
457 (3.7)
25–44 years
1686 (15.0)
1951 (15.9)
45–64 years
3060 (27.1)
3211 (26.1)
65–84 years
3429 (30.4)
3756 (30.5)
≥85 years
1014 (9.0)
1058 (8.6)
1 (<0.1)
0
Missing data
Race — no. (%)
<0.001c
American Indian or Alaska Native
119 (1.1)
142 (1.2)
Asian
254 (2.3)
312 (2.5)
1905 (16.9)
2007 (16.3)
254 (2.3)
615 (5.0)
Black or African-American
Multiple races or other unspecified
P Valuea,b
race
18
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
2011 Survey
2015 Survey
Patients
Patients
(N=11,282)
(N=12,299)
20 (0.2)
41 (0.3)
White
7537 (66.8)
8161 (66.4)
Missing data
1193 (10.6)
1021 (8.3)
Characteristic
Native Hawaiian or other Pacific
P Valuea,b
Islander
Ethnicity — no. (%)
<0.001c
Hispanic or Latino
846 (7.5)
977 (7.9)
Not Hispanic or Latino
3715 (32.9)
7991 (65.0)
Missing data
6721 (59.6)
3331 (27.1)
Ventilator in place on survey date — no.
0.71
(%)
Yes
527 (4.7)
586 (4.8)
No
10,748 (95.3)
11,683 (95.0)
7 (<0.1)
30 (0.2)
6 (3–13)d
6 (3–13)d
Missing data
Median hospital length of stay among
patients who received antimicrobial
therapy at the time of the survey (or
information not available) (IQR)
Percentages may not total 100 due to rounding. IQR denotes interquartile range.
a
Chi-square test, unless otherwise indicated.
Comparison excludes patients with missing data, unless otherwise indicated.
b
c
Comparison includes patients with missing data.
19
0.15e
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Hospital length of stay data were missing for 53 patients in the 2011 survey and 2 patients in the 2015
d
survey. Excludes patients in the 2011 survey who were screen-positive for antimicrobial therapy at the
time of the survey based on a special criterion for dialysis patients. This criterion was not implemented
in the 2015 survey.
e
Median 2-sample test
20
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S5. Distribution of common HAI types in the 2015 survey, 2011 definitions vs. 2015 definitions.
No. of HAIs (%), 2011 HAI
No. of HAIs (%), 2015 HAI
Definitions (N=361)
Definitions (N=370)
Pneumonia
110 (30.5)
97 (26.2)
Gastrointestinal infection
91 (25.2)
95 (25.7)
Surgical site infection
69 (19.1)
88 (23.8)
Bloodstream infection
52 (14.4)
55 (14.9)
Urinary tract infection
39 (10.8)
35 (9.5)
Percentages may not total 100 due to rounding.
21
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S6. Multivariable log binomial regression model to identify variables associated with health careassociated infections (HAIs) in the subset of patients meeting the HAI review criterion, combined 2011
and 2015 survey populations (N=9118).
No. of
Total
Patients
Adjusted
95%
No. of
with
Risk
Confidence
Patients
HAIs
Ratio
Interval
P Value
Survey year 2015
4614
394
0.84
0.75–0.94
0.003
Ventilator on the survey datea
700
176
1.28
1.09–1.52
0.003
Survey date in May or Juneb
3662
310
0.88
0.78–1.00
0.04
Large hospital
1744
280
1.25
1.11–1.41
<0.001
Critical care unit on the survey date
1597
271
1.28
1.10–1.49
0.002
≤1 day
1881
27
Ref
--
--
2–4 days
3501
81
1.62
1.07–2.54
0.03
5–6 days
1144
76
4.59
3.02–7.19
<0.001
7–9 days
942
127
8.95
6.06–13.74
<0.001
10–12 days
480
122
16.17
10.98–24.76
<0.001
13–20 days
606
174
18.38
12.62–27.93
<0.001
≥21 days
564
239
24.15
16.66–36.57
<0.001
Variable*
Time from admission to survey
*
Other variables that were tested but found not to be statistically significant predictors of HAI risk were
age and presence of a central line or urinary catheter on the survey date.
a
Ventilator presence was unknown for 17 patients without HAIs and 1 patient with HAI (patients with
unknown ventilator status were grouped with patients without ventilators for analysis).
22
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Survey dates were categorized as being in May–June versus July–September.
b
23
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S7. Multivariable log binomial regression model to identify variables associated with health careassociated infections (HAIs) in the subset of patients in 148 hospitals that participated in both the 2011
and 2015 surveys, combined 2011 and 2015 survey populations (N=18,451).
No. of
Total No.
Patients
Adjusted
95%
of
with
Risk
Confidence
Patients
HAIs
Ratio
Interval
P Value
Survey year 2015
9169
297
0.78
0.68–0.90
<0.001
Ventilator on the survey datea
877
139
1.69
1.40–2.02
<0.001
Central line on the survey dateb
3371
382
1.87
1.59–2.20
<0.001
Urinary catheter on the survey datec
3875
241
1.18
1.01–1.39
0.04
Large hospital
4310
255
1.24
1.07–1.43
0.004
≤1 day
5408
20
Ref
Ref
—
2–4 days
7043
69
2.43
1.51–4.10
<0.001
5–6 days
1688
56
6.93
4.24–11.81
<0.001
7–9 days
1480
105
13.68
8.68–22.71
<0.001
≥10 days
2832
430
26.52
17.30–43.14
<0.001
6389
166
Ref
Ref
—
10,448
456
1.49
1.26–1.78
<0.001
1614
58
1.76
1.31–2.31
<0.001
Variable*
Time from admission to survey
Aged
<45 years
45–84 years
≥85 years
*
Other variables that were tested but found not to be statistically significant predictors of HAI risk were
survey month (May–June versus July–September) and location in a critical care unit on the survey date.
24
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
a
Ventilator presence was unknown for 26 patients without HAIs and 0 patients with HAI (patients with
unknown ventilator status were grouped with patients without ventilators for analysis).
Central line presence was unknown for 51 patients without HAIs and 0 patients with HAI (patients with
b
unknown central line status were grouped with patients without central lines for analysis).
c
Urinary catheter presence was unknown for 45 patients without HAIs and 3 patients with HAI (patients
with unknown catheter status were grouped with patients without urinary catheters for analysis).
Model excluded 1 patient without HAIs in the 2011 survey for whom age was unknown.
d
25
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S8. Multivariable log binomial regression model to identify variables associated with health careassociated infections (HAIs), excluding the presence of devices, in the subset of patients in 148 hospitals
that participated in both the 2011 and 2015 surveys, combined 2011 and 2015 survey populations
(N=18,451).
No. of
Total
Patients
Adjusted
95%
No. of
with
Risk
Confidence
Patients
HAIs
Ratio
Interval
P Value
Survey year 2015
9169
297
0.76
0.66–0.87
<0.001
Critical care unit on the survey date
2790
212
1.58
1.35–1.85
<0.001
Large hospital
4310
255
1.28
1.11–1.49
<0.001
≤1 day
5408
20
Ref
Ref
--
2–4 days
7043
69
2.51
1.56–4.24
<0.001
5–6 days
1688
56
7.74
4.74–13.17
<0.001
7–9 days
1480
105
16.39
10.43–27.14
<0.001
≥10 days
2832
430
35.90
23.59–58.08
<0.001
<40 years
5739
143
Ref
Ref
--
40–50 years
1708
63
1.76
1.32–2.33
<0.001
51–65 years
4179
208
2.13
1.73–2.62
<0.001
66–69 years
1203
43
1.66
1.19–2.28
0.002
≥70 years
5622
223
2.15
1.75–2.65
<0.001
Variable*
Time from admission to survey
Agea
26
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
*
Survey month (May–June versus July–September) was also tested but was not found to be a statistically
significant predictor of HAI risk.
a
Model excluded 1 patient without HAIs in the 2011 survey for whom age was unknown.
27
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S9. Log-binomial regression model to identify factors associated with HAIs among patients surveyed in 2015 (N=12,299).
Full, Final Model
Final Model* For Burden Estimation
Total
No. of
No. of
Patients
Adjusted
Confidence
Patients
with HAIs
Risk Ratio
Interval
P Value
≤1 year
1388
22
Ref
Ref
—
2–26 years
1119
26
2.33
1.34–4.05
0.003
27–51 years
2574
72
2.94
1.84–4.70
52–64 years
2404
122
4.10
65–77 years
2607
82
≥78 years
2207
≤4 days
5–6 days
Factor
95%
95%
Adjusted
Confidence
Risk Ratio
Interval
P Value
Ref
Ref
—
<0.001
2.26
1.58–3.22
<0.001
2.62–6.42
<0.001
3.21
2.32–4.44
<0.001
2.89
1.82–4.61
<0.001
2.19
1.54–3.11
<0.001
70
3.77
2.35–6.04
<0.001
2.71
1.88–3.90
<0.001
5861
20
Ref
Ref
—
1427
15
2.66
1.36–5.19
0.004
Ref
Ref
—
Agea
Hospital length of
stayb
28
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Full, Final Model
Total
No. of
No. of
Patients
Adjusted
Confidence
Patients
with HAIs
Risk Ratio
Interval
7–8 days
1064
26
5.84
9–14 days
1543
75
15–23 days
992
≥24 days
Final Model* For Burden Estimation
95%
95%
Adjusted
Confidence
P Value
Risk Ratio
Interval
P Value
3.26–10.44
<0.001
4.69
2.83–7.75
<0.001
11.22
6.83–18.42
<0.001
9.43
6.34–14.04
<0.001
85
17.70
10.79–29.04
<0.001
16.98
11.51–25.03
<0.001
1412
173
26.90
16.58–43.67
<0.001
28.83
20.12–41.32
<0.001
Ventilatorc
586
81
1.53
1.21–1.93
<0.001
Not included in final model
Central lined
2081
213
1.88
1.52–2.32
<0.001
Not included in final model
11,719
381
1.88
1.11–3.19
0.02
Not included in final model
3557
176
1.37
1.11–1.70
0.004
Not included in final model
1474
56
0.60
0.45–0.81
<0.001
Not included in final model
Factor
Rural hospitale
Hospital with >400
licensed bedsf
Hospital with 500–
800 licensed bedsf
*
The final model for burden estimation included factors significant in multivariable models and available in the prevalence survey dataset and in
the 2014 National Inpatient Sample.
29
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
a
Age categories ≤1 year and 2–26 years were collapsed in the final model for burden estimation due to no health care-associated infection
events in certain categories of age and length of stay.
Hospital length of stay was available for 12,290 patients; length of stay was unknown for 1 patient, and 8 patients were still in the hospital at
b
least 6 months after the survey date. Time from admission to the date of follow-up (≥6 months following the survey date) was used as a proxy
for hospital length of stay in patients who remained in the hospital for more than 6 months after the survey date. Hospital length of stay
categories ≤4 days and 5–6 days were collapsed in the final model for burden estimation due to there being no health care-associated infection
events in certain categories of age and length of stay.
c
Ventilator presence was unknown for 29 patients without HAIs and 1 patient with HAI (patients with unknown ventilator status were grouped
with patients without ventilators for analysis).
Central line presence was unknown for 42 patients without HAIs and 1 patient with HAI (patients with unknown central line status were
d
grouped with patients without central lines for analysis).
Hospitals were categorized as urban versus rural based on U.S. Census data; hospitals located in a metropolitan county were considered urban,
e
and hospitals located in a micropolitan or rural county were considered rural.
f
Hospitals were asked to submit licensed bed data from the most recent year for which data were available: 2015 (39 hospitals, 20%); 2014 (157,
79%); 2013 (3, 2%). In one instance where data were reported in aggregate for >1 hospital in the same system, Emerging Infections Program site
staff were consulted, and aggregated data were apportioned to each hospital.
30
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Table S10. Estimated numbers of health care-associated infections in the United States in 2015.
Percentage of Patients
Estimated Infectionsb in the
with Infection Typea
United States
No. of Infections
(95% Confidence Interval)
(95% Confidence Interval)
Pneumonia
110
27.9 (23.7–32.5)
176,700 (51,200–621,600)
Gastrointestinal infection
91
23.1 (19.1–27.5)
146,300 (41,300–526,000)
Surgical-site infection
69
17.5 (14.0–21.5)
110,800 (30,200–411,200)
Bloodstream infection
52c
13.2 (10.1–16.8)
83,600 (21,800–321,300)
Urinary tract infection
39
9.9 (7.2–13.2)
62,700 (15,600–252,500)
Skin and soft tissue infection
22
5.6 (3.6–8.2)
35,500 (7,800–156,800)
Eye, ear, nose throat and mouth infection
21d
5.3 (3.4–7.9)
33,600 (7,300–151,100)
Lower respiratory infection
18
4.6 (2.8–7.0)
29,100 (6,000–133,900)
Bone and joint infection
2
0.5 (0.08–1.7)
3,200 (200–32,500)
Central nervous system infection
1
0.3 (0.01–1.2)
1,900 (0–23,000)
Cardiovascular infection
1
0.3 (0.01–1.2)
1,900 (0–23,000)
Reproductive tract infection
1
0.3 (0.01–1.2)
1,900 (0–23,000)
Systemic infection
0
0 (0–0.8)
0 (0–15,300)
Infection Type
31
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
Infection Type
No. of Infections
Total
a
Percentage of Patients
Estimated Infectionsb in the
with Infection Typea
United States
(95% Confidence Interval)
(95% Confidence Interval)
687,200 (181,400–2,691,200)
Among the 394 surveyed patients with health care-associated infections, the percentage with each infection type.
Estimates are based on the total number of patients with health care-associated infections (and upper and lower bounds of the 95% CI), prior to
b
rounding to the nearest hundred, multiplied by the rounded proportions (and upper and lower bounds of the 95% CIs) of patients with each type
of infection. These products were then rounded to the nearest hundred to estimate the total numbers of each HAI. The rounded products were
added together to determine the total number of all HAIs. For the purposes of burden estimation, we assumed each infection occurred in a
unique patient.
c
One patient had 2 separate bloodstream infections. For the purposes of burden estimation, we assumed that each of these 52 infections
occurred in a unique patient.
One patient had 2 separate eye, ear, nose, throat and mouth infections. For the purposes of burden estimation, we assumed that each of these
d
21 infections occurred in a unique patient.
32
�Supplementary Appendix, “Changes in Prevalence of Health Care-Associated Infections in U.S. Hospitals”
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34
�
| File Type | application/pdf |
| Author | Magill, Shelley (CDC/OID/NCEZID) |
| File Modified | 2018-10-15 |
| File Created | 2018-10-12 |