Research Article
Changes in Renal Function in Elderly Patients
Following Intravenous Iodinated Contrast Administration:
A Retrospective Study

Ali Alsafi, Zaid Alsafi, Amish Lakhani, and Nicola H. Strickland

Radiology Department, Imperial College Healthcare NHS, Hammersmith Hospital, Du Cane Road, London W12 0HS, UK

Correspondence should be addressed to Ali Alsafi; ali.alsafi03@alumni.imperial.ac.uk

Received 12 January 2014; Revised 19 February 2014; Accepted 25 February 2014; Published 24 March 2014

Academic Editor: Keiji Tanimoto

Copyright © 2014 Ali Alsafi et al. This is an open access article distributed under the Creative Commons Attribution License, which
permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Background. Contrast-induced nephropathy (CIN) is a recognised complication of intravascular administration of iodinated
contrast media (ICM). Previous studies suggest a higher incidence in the elderly, but no large study has assessed this to date.
We set out to assess changes in creatinine in elderly inpatients following computed tomography (CT) examination and compare
those who received intravenous contrast to those who did not. Methods. Using the Radiology Information System in two teaching
hospitals, inpatients over the age of seventy who had a CT examination and a baseline creatinine were identified and their follow-up
creatinine levels were analysed. Elderly inpatients who underwent a noncontrast CT over the same period were used as controls.
Results. 677 elderly inpatients who received ICM were compared with 487 controls. 9.2% of patients who received ICM developed
acute kidney injury (AKI) compared to 3.5% of inpatient controls (𝑃 < 0.0001). Patients with higher baseline eGFR had a higher
incidence of post-CT AKI. Conclusions. The incidence of post-CT AKI is higher in patients who received IV ICM compared to
those who did not; the difference may be partly attributable to contrast-induced nephropathy. This suggests that the incidence of
CIN in the elderly may not be as high as previously thought.

1. Background

Intravascular administration of iodinated contrast media
(ICM) is used in a variety of diagnostic and therapeutic pro-
cedures. While ICM are generally safe, only resulting in
minor side effects, they can result acute renal impairment
known as contrast induced nephropathy (CIN) [1]. The
majority of cases of CIN are self-limiting, although occasion-
ally chronic renal failure ensues necessitating long-term renal
replacement. Even when transient, CIN is associated with
increased length of hospital stay and significant morbidity
[1, 2].

Diabetes mellitus, preexisting renal failure, congestive
heart failure, and hypotension, dehydration as well as the
use of ACE inhibitors, diuretics, and nonsteroidal anti-
inflammatory drugs have all been identified as important
risk factors for developing CIN [3, 4]. Hydration in high-risk

patients remains the most important preventative measure
[5, 6].

Many attempts at defining CIN exist, but the most widely
accepted definition is a 25% rise in serum creatinine concen-
tration from baseline or an absolute increase by 44𝜇mol/L
over the 48 to 72 hours following ICM administration, once
other causes of renal impairment have been excluded [2, 4].

The use of CT in clinical medicine has exponentially
increased over the past two decades, including managing
elderly patients, who are thought to be particularly suscep-
tible to developing CIN [7–10]. The true incidence of CIN
in the elderly is not known, as most studies addressing the
issue assumed that acute kidney injury (AKI) following ICM
administration is in fact CIN [11–13]. The results of these
studies are therefore likely to be an overestimate, as they failed
to compare the incidence of AKI in their patient population
to that of a control group. AKI itself is difficult to define,

Hindawi Publishing Corporation
Radiology Research and Practice
Volume 2014, Article ID 459583, 4 pages
http://dx.doi.org/10.1155/2014/459583



2 Radiology Research and Practice

but a practical definition is that of a rapid deterioration in
renal function resulting in the inability to maintain fluid,
electrolyte, or acid-base homeostasis [14].

CIN has come recently under question as a clinical entity,
with suggestions that its incidence and significance have been
grossly overestimated. One study even questions the existence
of CIN, particularly in patients with preexisting normal renal
function [15–17].

In this study, we sought to retrospectively evaluate
changes in renal function in elderly patients who underwent a
contrast enhanced CT examination and compare to controls
who had a noncontrast CT. The aim was to estimate the
incidence of post-CT AKI in the elderly.

2. Methods

Using the Radiology Information System (RIS) in two teach-
ing hospitals, inpatients over the age of seventy who had
a contrast enhanced computed tomography (CT) examina-
tion between August 2011 and August 2012 were identified.
Demographic and examination data were recorded. Using
the hospitals’ pathology results systems, the most recent
creatinine (Cr) values prior to the contrast examination were
recorded. Follow-up Cr values 48–72 hours following the
examination were also noted. The most recent Cr prior to the
CT examination (up to six weeks) was taken as the baseline
against which changes in Cr were compared. eGFR was
calculated using the modified diet in renal disease (MDRD)
formula [18].

Information relating to prehydration, posthydration, and
administration of NAC was not readily available and not
recorded, although our standard in-hospital practice is to pre-
and posthydrate high-risk patients.

We excluded patients who had no baseline creatinine,
those who had no blood tests between 48 and 72 hours
following the CT examination, and those on haemodialysis,
peritoneal dialysis, or hemofiltration. Patients who had a
nephrostomy or renal stent placement within 7 days of the
study were also excluded. Patients who had a contrast head
CT receiving 50 mL of Omnipaque 300 were excluded. This
group constitutes a small number of patients with a signif-
icantly lower contrast dose to the remainder of the study
population.

All elderly inpatients who underwent a noncontrast
examination over the same period were used as controls with
the same exclusion criteria. These patients were also identified
using the RIS system. Those who developed AKI of an order
comparable to that seen in CIN, (25% rise in serum crea-
tinine concentration from baseline or an absolute increase
by 44𝜇mol/L) were identified. The incidence of AKI was
calculated for the ICM and control group.

Institutional review board approval was obtained and
informed consent was waived prior to commencing this
retrospective study.

2.1. Statistical Analysis. Two-tailed Fisher’s exact test was
used to compare categorical data, while two-tailed Student’s
t-test was used to compare numerical data. 𝑃 values <0.05
were considered significant. Odds ratio was calculated using

Table 1: Demographic data and baseline eGFR (mL/min/1.73 m2).

Body CT
(𝑛 = 677)

Controls
(𝑛 = 487)

𝑃value

Average age (range) 80.4 (70–102) 82 (70–103) <0.0001∗

Males (%) 340 (50.2%) 240 (49.3%) 0.7666#
Females (%) 337 (49.8%) 247 (50.7%)
Baseline eGFR>90 220 (32%) 153 (31.4%) 0.7030#
∗Unpaired Student’s 𝑡-test; #Fisher’s exact test.

Table 2: Number of patients developing post-CT AKI in the
ICM and control groups with varying baseline eGFR. (eGFR in
mL/min/1.73 m2).

Baseline eGFR ICM group (%) Controls (%)
>90 13 (5.91%) (𝑛 = 220) 2 (1.31%) (𝑛 = 153)
60–90 19 (9.13%) (𝑛 = 208) 2 (1.23%) (𝑛 = 162)
45–60 7 (7.37%) (𝑛 = 95) 3 (4.48%) (𝑛 = 67)
<45 23 (14.9%) (𝑛 = 154) 10 (9.52%) (𝑛 = 105)
Total 62 (9.16%) (𝑛 = 677) 17 (3.49%) (𝑛 = 487)

GraphPad Prism 5.0 for Mac OS X (GraphPad Software Inc.,
San Diego, CA, USA).

3. Results and Discussion

920 inpatients over the age of 70 had a contrast enhanced
CT examination between August 2011 and 2012, including
825 body CT examinations and 95 head CT examinations;
the latter were excluded. A further 81 patients were excluded
because they were receiving renal replacement therapy and
one patient was excluded because of a recent nephrostomy.

677 patients had a baseline creatinine and at least one
further creatinine measurement 48–72 hours following their
CT. None of the patients had more than one contrast
enhanced examination during the study period. Over the
same period, 850 inpatients underwent a CT examination
without contrast. 363 of these patients were excluded: 17
because they were receiving renal replacement, 48 who had
no baseline creatinine, one who had acute kidney injury
predating the CT examination, and 297 who did not have
a creatinine level measured 48–72 hours following their CT
examination. The remaining 487 cases were used as controls.
There was no significant difference in sex or baseline eGFR
between the two groups, although the control group was
slightly older than the ICM group. (Demographics and
baseline eGFR are shown in Tables 1 and 2 resp.)

In the 48 to 72 hours following intravenous adminis-
tration of 80–120 mL of Omnipaque 300, 5.9% (13/220) of
patients with a baseline eGFR > 90 mL/min/1.73 m2 devel-
oped AKI compared with 9.1% (19/208), 7.4% (7/95), and
14.9% (23/154) of those with eGFR 60–90 mL/min/1.73 m2,
45–60 mL/min/1.73 m2, and <45 mL/min/1.73 m2, respec-
tively (Figure 1). The relative risk for developing post-CT
AKI in patients who had 80–120 mL of ICM with a baseline
eGFR < 45 mL/min/1.73 m2 compared to those with an



Radiology Research and Practice 3

<45 45–60 60–90 >90

##

Baseline eGFR mL/min/1.73 m2

ICM group

5

10

Po
st

-C
T

 A
K

I (
%

)

Controls

∗

∗∗

Figure 1: Percentage of patients developing post-CT AKI in the
ICM group compared to controls. Using Fisher’s exact test: ∗𝑃 <
0.05 and ∗∗𝑃 < 0.001, comparing the ICM group versus controls
and ##𝑃 < 0.005 comparing to patients with a baseline GFR >
90 mL/min/1.73 m2.

eGFR > 90 mL/min/1.73 m2 was 1.65 (95% CI 1.25 to 2.18,
𝑃= 0.0043).

The relative risk for developing post-CT AKI in inpatients
who had 80–120 mL of ICM compared with controls is 1.35
(95% CI 1.22 to 1.57,𝑃< 0.0001).

Intravenous contrast media (ICM) are widely used in
diagnostic and interventional radiology; their use, however, is
associated with up to 11% of hospital-acquired AKI [5]. CIN
is a cause of significant morbidity and mortality in hospital
patients and is thought to be an important cause of AKI in this
population alongside sepsis, hypoperfusion, major surgery,
and nephrotoxic medication [5, 11–13].

Increasing age is an independent predictor for developing
CIN with a fivefold increase in risk in patients over the age of
seventy [7].

Previous studies, including MacDonald et al’s recent large
meta-analysis, showed no difference in incidence of post-
CT AKI, between contrast and control groups. These studies
assessed significantly younger patient populations than ours
(median patient age of 62 versus 82 in our study) and their
results may not be generalizable to an older age group [15, 16,
19].

Davenport et al. on the other hand demonstrated that IV
ICM is an important risk factor, albeit not the only one, in
developing post-CT AKI in an adult patient population [17].
Our results extend these conclusions to a significantly older
population, which may be even more susceptible to CIN.

Two studies estimated the incidence of CIN in the elderly
at 6% and 14%, respectively. Neither study accounted for other
causes of AKI nor did they compare with controls [9, 10]. To
our knowledge, this is the first study to compare the incidence

of post-CT AKI in elderly patients who received IV ICM with
controls who had nonenhanced examinations.

While the excess AKI in the ICM group is, at least
partly, likely attributable to contrast administration, there
may be inherent differences between the two groups, with
patients not receiving ICM being perceived as high-risk and
therefore undergoing noncontrast examinations. The fact that
the average baseline eGFR, age, and gender distribution are
similar in the two groups does not support this.

Furthermore, a significant number of the noncontrast
studies were head CT examinations (87%), suggesting that
the disease processes for which the two groups presented to
hospital may be different, with the ICM group being more
likely to have systemic, rather than neurological, symptoms
and therefore more likely to develop AKI. This is merely
speculative but may partly account for the differences seen in
conjunction with true CIN. If this is the case, the incidence of
CIN may even be lower.

4. Limitations

Although we did not assess for risk factors other than
preexisting renal impairment, by using a control population
with similar demographics who were inpatients during the
same study period, the difference in incidence of AKI may be
partly attributable to the administration of IV ICM.

Our results apply to an elderly hospital inpatient popu-
lation and may not be generalizable to a healthier outpatient
population, whose risk of CIN is perhaps even lower.

5. Conclusions

The incidence of AKI in our elderly inpatient population
was 9.2% after administration of 80–120 mL of intravenous
ICM compared with 3.5% in inpatient controls. The difference
between the two groups may be, at least partly, attributable
to ICM. Caution, however, needs to be exercised in elderly
patients with low baseline eGFR (<45 mL/min/1.73 m2) as
post-CT AKI approaches 15% in this group.

Abbreviations

CIN: Contrast induced nephropathy
ICM: Iodinated contrast media
CT: Computed tomography
AKI: Acute kidney injury
eGFR: estimated glomerular filtration rate
Cr: Creatinine
NAC: n-Acetylcysteine
MDRD: Modified diet in renal disease
RIS: The Radiology Information System.

Conflict of Interests

The authors declare that there is no conflict of interests
regarding the publication of this paper.



4 Radiology Research and Practice

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