Dermatology: Practical and Conceptual


16 Research  |  Dermatol Pract Concept 2017;7(3):3

DERMATOLOGY PRACTICAL & CONCEPTUAL
www.derm101.com

Introduction

Surgical site infections (SSI) account for up to 20% of 

healthcare associated infections, [1] which amounts to 

approximately 35,000-40,000 infections in Australia each 

year [2].

As Australia has the highest rate of skin cancer in the 

world, and as the majority of skin cancer is managed in 

general practice [3], GP minor surgery and optimal post-

operative management is a particular issue for Australian 

GPs. It is projected that close to a million surgical procedures 

for both squamous cell carcinoma (SCC) and basal cell car-

cinoma (BCC) will be performed in 2016 [4], the majority of 

these by general practitioners (GPs).

The acceptable rate of SSI following clean minor surgery 

(Class 1) is less than 5% [5], however, the infection rate may 

Topical antibiotics to prevent surgical site infection 
after minor surgery in primary care

Clare Heal1, Phoebe Lepper1, Jennifer Banks1

1 James Cook University, Mackay Base Hospital, Mackay, Australia

Key words: surgical site infection, skin cancer, topical antibiotics

Citation: Heal C, Lepper P, Banks J. Topical antibiotics to prevent surgical site infection after minor surgery in primary care. Dermatol 
Pract Concept 2017;7(3):3. DOI: https://doi.org/10.5826/dpc.0703a03

Received: December 12, 2016; Accepted: April 28, 2017; Published: July 31, 2017

Copyright: ©2017 Heal et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, 
which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: None.

Competing interests: The authors have no conflicts of interest to disclose.

All authors have contributed significantly to this publication.

Corresponding author: Prof Clare Heal, PhD, James Cook University Rural Clinical School, Mackay Base Hospital Mackay QLD 4740, 
Australia. Tel. 0457506701. Email: clare.heal@jcu.edu.au

Background: Surgical site infection (SSI) after minor surgery in primary care can compromise cosmet-
ic outcomes, delay wound healing and increase costs. In addition to efficacy, adverse effects must be 
considered when considering antibiotic prophylaxis. There is no prior published literature regarding 
the proportion of general practitioners (GPs) who use topical antibiotics as SSI prophylaxis following 
minor surgery.

Objectives: To identify the proportion of GPs in a regional center in Queensland, Australia who apply 
topical antibiotics to wounds prevent SSIs after minor surgery.

Method: A database of 90 GPs was established, and they were invited to complete a questionnaire.

Results: The response rate was 62% (56/90). Topical antibiotics prophylaxis was reported as being 
used always or sometimes in routine practice by 18% (10/56) of participants after both skin lesion 
excision and repair of lacerations. In the context of high-risk situations, on the other hand, use was 
higher. They were more likely to be used in high-risk situations, most frequently in diabetic patients 
(41.0% [23/56]) and immunocompromised patients (46.5% [26/56]).

Conclusions: Evidence-based prescribing of antibiotics is vital. Topical antibiotic prophylaxis is often 
prescribed excessively after clean dermatological surgery, however, in our sample of GPs, only 18% 
used topical antibiotics always or sometimes in their practice.

ABSTRACT



Research  |  Dermatol Pract Concept 2017;7(3):3 17

tionnaire was pilot tested in May 2014 and based on feedback 

was further refined before distribution. The questionnaire 

aimed to investigate topical antibiotic prescribing both in 

routine practice and in the context of high-risk situations. The 

categories of “always and sometimes” were further combined 

for the purposes of interpretation to indicate that topical 

antibiotics were used “ever,” as opposed to “seldom or never.”

Data collection
The questionnaire, information sheet, and consent form were 

individually posted to all GPs in the database. Each practice 

was initially sent an email to inform them of the survey and 

to request the return of the completed questionnaires and 

consent forms. After a period of three months, a second copy 

of the survey was sent to eligible participants with a follow-up 

email. Data from completed questionnaires were de-identified 

and stored securely.

Data analysis
Data collected from the survey was analyzed using Statistical 

Package for Social Sciences (SPSS, Inc. version 22). Participant 

characteristics and outcomes were presented using frequen-

cies and descriptive statistics. Comparisons of outcomes 

were analyzed with a Chi-squared test or Fisher’s exact test 

where appropriate, with a p value less than 0.05 considered 

significant.

Ethical considerations
Ethical approval for the study was obtained from the 

James Cook University Human Research Ethics Committee 

(H5616).

Results

Completed surveys were returned by 56/90 participants 

(62% response rate). The characteristics of those GPs who 

responded are presented in Table 1. Of the participants who 

responded, 53.6% were male, 60% (34/56) were aged 46-55, 

and 34% had a length of practice between 21 and 30 years. 

This is representative of the demographics of GPs in Mackay.

Use of topical antibiotics after excisions and 
lacerations in the context of routine practice
In the context of routine practice, topical antibiotics were 

reported to be used always or sometimes (as opposed to 

seldom and never) to prevent wound infections after minor 

skin excisions by 18% (10/56) of participants. After lacera-

tions, 18% (10/56) of participants also reported using topi-

cal antibiotics always or sometimes (Table 2). There was no 

association between the GP characteristics of age, gender, and 

length of time in practice and the use of topical antibiotics in 

excisions and lacerations.

be higher because of body site, [6,7] the pathology of the 

lesion removed [6-8] or environmental conditions [8,9].

Limited guidelines exist regarding antibiotic prophylaxis 

of dermatological procedures [10-12,13], and those available 

guidelines do not recommend any type of antibiotic to pre-

vent SSI in clean (class 1) minor surgery [11]. The National 

Institute for Health and Care Excellence (NICE) guidelines 

also state “do not use topical antibiotics in wounds healing 

by primary intention to reduce the risk of surgical site infec-

tion.” [12] In practice, antibiotic prophylaxis is prescribed 

excessively or inappropriately for dermatological surgery, in 

general, and it is recommended it be reserved for high-risk 

situations [13-15]. A recent Cochrane Review found moder-

ate quality evidence that topical antibiotics probably prevent 

SSI compared to no treatment (RR 0.61, 95% CI 0.42 to 

0.87), but did not recommend use in clean (class 1) surgery, 

where the baseline infection rate is already low. There was 

insufficient evidence in the review to make judgments about 

adverse events such as allergic contact dermatitis and antibi-

otic resistance [16] that limits the ability to make an overall 

evaluation of the use of topical antibiotics.

Currently, there is no data available to assess the propor-

tion of Australian GPs who use topical antibiotics as SSI 

prophylaxis in wounds healing by primary intention. The 

aim of this study was to identify the proportion of GPs in 

Mackay, Queensland who use topical antibiotics to prevent 

SSI in excisions and lacerations healing by primary intention 

as well as identifying the class of topical antibiotics used and 

clinical and patient factors that may influence this use.

Methods

Study design and setting
All GPs, including GP registrars working within the 4740 

postcode, were initially identified by a search of the Towns-

ville-Mackay Medicare Local Service Finder. Each GP clinic 

was contacted by a study author (PL) to confirm the GPs 

working at that service. Those GPs who were on leave at the 

time of the survey were excluded as were GPs working in 

settings that did not involve minor surgery (women’s health, 

occupational health). A database of 90 GPs was established.

Sample size
Based on an estimated incidence of 50% for our primary 

outcome (incidence of prescribing topical antibiotics), the 

sample size was calculated to be 47 for 95% confidence and 

10% precision.

Questionnaire
The two-page questionnaire was designed by one author (PL) 

with assistance from other authors (CH and JB), using current 

guidelines and literature to ensure content validity. The ques-



18 Research  |  Dermatol Pract Concept 2017;7(3):3

One other study of topical antibiotic use was identified 

in the literature. This was a survey of UK plastic surgeons 

regarding topical chloramphenicol use, which was initially 

conducted in 1999 and then repeated in 2010. In the initial 

survey, 66% of UK plastic surgeons reported using topical 

chloramphenicol ointment in their practice, and in 2010 a 

slightly higher proportion of 72% was reported [17,18]. This 

is higher than the reported rate of 18% in our GP survey 

and may in part be due to a difference in types of surgery or 

patient expectations.

It was interesting that, in the context of routine practice, 

topical antibiotics were reported to be used always or some-

times by the same number of GPs (18%) after excisions as 

lacerations. Excisions are classified as class 1 wounds with 

an acceptable postoperative infection rate of less than 5% 

[5], while lacerations are classified class 3 wounds, with an 

acceptable infection rate of 10-17% [19]. Assuming that the 

relative risk reduction in both clinical situations is the same, 

topical antibiotics would be of more clinical value after lac-

erations than skin excisions, where the likely absolute risk 

reduction in infection would be higher.

In our previous studies of risk factors for infection, we 

established excision from the lower limb as being the most 

significant independent risk factor for SSI, with infection rates 

as high as 30% [6,7,20] and, therefore, in the context of high-

risk practice, the reported high frequency of use of topical 

antibiotics by GPs in excisions from the lower limb (39%) is 

probably justified. The evidence for diabetes as a risk factor 

Class of topical antibiotics used
The different subtypes of topical antibiotics used by GPs in 

any area of their practice are reported in Table 3. The two 

most commonly used antibiotics were chloramphenicol, 

which was reported to be used by 56.6% (30/53) of GPs, 

and mupirocin, which was reported to be used by 43.4% 

(23/53) of GPs.

There was no significant association between GP charac-

teristics and the class of topical antibiotic used.

Use of topical antibiotics in the context of high-
risk situations
The reported use of topical antibiotics was higher in the con-

text of clinical situations that are considered to be at higher 

risk for infection (Table 4). A total of 41.0% (23/56) of GPs 

reported ever (always or sometimes) using topical antibiot-

ics in diabetic patients, 46.5% (26/56) of GPs reported the 

same for immunocompromised patients, 46.5% (26/56) for 

patients with previous surgical site infection, 39.3% (22/56) 

for lower limb sites, 17.9% (10/56) for upper limb sites and 

33.4% (19/56) for facial wounds. GPs who had been in 

practice for less than ten years reported they were signifi-

cantly more likely to use antibiotics always or sometimes for 

immunocompromised patients (p= 0.01), and patients with 

previous surgical site infections (p= 0.02) compared with GPs 

who had been in practice for a longer period.

Discussion

The judicious use of antibiotics is critical. In addition to 

efficacy, health system costs, side effects, and the rise in anti-

biotic resistance must be taken into account when considering 

antibiotic use prophylactically. While there is much discussion 

about GP oral antibiotic use, we believe that this is the first 

study to establish the frequency of topical antibiotic use in 

the context of minor surgery by GPs.

TABLE 1. Characteristics of respondents

Characteristics
N (%) 
N=56

Gender Male
Female

30 (53.6)
26 (46.4)

Age in years ** < 30
30-44
45-59
60 and older

2 (3.6)
13 (23.2)
34 (60.7)
5 (8.9)

Length of practice 
in GP (Y)

10 years or less
11-20
21-30
More than 30 years

15 (26.8)
16 (28.6)
19 (33.9)
6 (10.7)

** 2 participants did not report age

TABLE 2. Frequency of topical antibiotic use in 
the context of routine practice

Frequency Excisions % Lacerations %

Never 29 (51.8) 36 (64.3)

Seldom 17 (30.4) 10 (17.9)

Sometimes  8 (14.3)  9 (16.1)

Always  2 (3.6)  1 (1.8)

TABLE 3. Types of topical antibiotics used**

Antibiotic Used Frequency N (%)*

Mupirocin 23 (43.4)

Chloramphenicol 30 (56.6)

Polymixin B sufate 1 (1.9)

bacitracin zinc, neomycin 
sulfate, polymyxin B sulfate 
combination ointment (TAO)

1(1.9)

Neomycin 2 (3.8)

Not used 10 (18.8)

* There was missing data from 3 GPs, denominator=53 GPs
** This question referred to topical antibiotics used in any 
 clinical situation by GPs

https://www.drugs.com/mtm/bacitracin-neomycin-and-polymyxin-b-topical.html
https://www.drugs.com/mtm/bacitracin-neomycin-and-polymyxin-b-topical.html


Research  |  Dermatol Pract Concept 2017;7(3):3 19

Implications for General Practice

Evidence-based prescribing of antibiotics is vital. In practice, 

antibiotic prophylaxis is often prescribed excessively or inap-

propriately for dermatological surgery [13-15]; however, in 

our sample of GPs only 18% used topical antibiotics always 

or sometimes in their practice. It is evident that topical anti-

biotics are used too frequently for prophylaxis against infec-

tion after clean surgery and that they should be reserved for 

high-risk situations.

Acknowledgements
Professor Jill Thistlethwaite.

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diabetic patients (41%) is not justified, based on our previous 

research. Excisions from the facial regions have a lower than 

average rate of wound infection [21], however, GPs reported 

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TABLE 4. Antibiotic use in high-risk situations

Frequency

N (%)

Diabetes 
Mellitus

Immuno-
compromised

Previous SSI
Lower limb 

sites
Upper limb 

sites
Facial Sites

Never 14 (25) 11 (19.6) 13 (23.2) 16 (28.6) 25 (44.6) 22 (39.3)

Seldom 19 (33.9) 18 (32.1) 17 (30.4) 18 (32.1) 21 (37.5) 18 (32.1)

Sometimes 19 (33.9) 16 (28.6) 21 (37.5) 19 (33.9) 10 (17.8) 18 (26.8)

Always 4 (7.1) 10 (17.9) 5 (8.9) 3 (5.3) 0 (0) 1 (1.8)

 



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