Antimicrobial Susceptibility Testing: A Comprehensive Review PDF

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This document is a review of antimicrobial susceptibility testing methods. It discusses common methods, their advantages and disadvantages, and future directions in the field. The review highlights the increasing threat of antimicrobial resistance and the need for improved testing methods.

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antibiotics
Review
Antimicrobial Susceptibility Testing: A Comprehensive Review
of Currently Used Methods
Ina Gajic 1, * , Jovana Kabic 1 , Dusan Kekic 1 , Milos Jovicevic 1 , Marina Milenkovic 2 , Dragana Mitic Culafic 3 ,
Anika Trudic 4,5 , Lazar Ranin 1 and Natasa Opavski 1

1 Institute of Microbiology and Immunology, Faculty of Medicine, University of Belgrade,
11000 Belgrade, Serbia; [email protected] (J.K.); [email protected] (D.K.);
[email protected] (M.J.); [email protected] (L.R.); [email protected] (N.O.)
2 Department of Microbiology and Immunology, Faculty of Pharmacy, University of Belgrade,
11000 Belgrade, Serbia; [email protected]
3 Faculty of Biology, University of Belgrade, 11000 Belgrade, Serbia; [email protected]
4 Faculty of Medicine, University of Novi Sad, 21000 Novi Sad, Serbia; [email protected]
5 Institute for Pulmonary Diseases of Vojvodina, Sremska Kamenica, 21204 Novi Sad, Serbia
* Correspondence: [email protected]; Tel.: +381-629-726-331

Abstract: Antimicrobial resistance (AMR) has emerged as a major threat to public health globally.
Accurate and rapid detection of resistance to antimicrobial drugs, and subsequent appropriate
antimicrobial treatment, combined with antimicrobial stewardship, are essential for controlling the
emergence and spread of AMR. This article reviews common antimicrobial susceptibility testing (AST)
methods and relevant issues concerning the advantages and disadvantages of each method. Although
accurate, classic technologies used in clinical microbiology to profile antimicrobial susceptibility



are time-consuming and relatively expensive. As a result, physicians often prescribe empirical


antimicrobial therapies and broad-spectrum antibiotics. Although recently developed AST systems
Citation: Gajic, I.; Kabic, J.; Kekic, D.;
have shown advantages over traditional methods in terms of testing speed and the potential for
Jovicevic, M.; Milenkovic, M.; Mitic
providing a deeper insight into resistance mechanisms, extensive validation is required to translate
Culafic, D.; Trudic, A.; Ranin, L.;
Opavski, N. Antimicrobial
these methodologies to clinical practice. With a continuous increase in antimicrobial resistance,
Susceptibility Testing: A additional efforts are needed to develop innovative, rapid, accurate, and portable diagnostic tools
Comprehensive Review of Currently for AST. The wide implementation of novel devices would enable the identification of the optimal
Used Methods. Antibiotics 2022, 11, treatment approaches and the surveillance of antibiotic resistance in health, agriculture, and the
427. https://doi.org/10.3390/ environment, allowing monitoring and better tackling the emergence of AMR.
antibiotics11040427

Academic Editor: Eleonora Nicolai
Keywords: antimicrobial susceptibility testing; antimicrobial resistance; methods

Received: 28 February 2022
Accepted: 18 March 2022
Published: 23 March 2022 1. The Emergence of Antimicrobial Resistance and Overlooked Pandemic
Publisher’s Note: MDPI stays neutral Antimicrobial resistance (AMR) remains the world’s most urgent public health con-
with regard to jurisdictional claims in cern. According to the World Health Organization (WHO), Geneva, Switzerland, antibiotic
published maps and institutional affil- resistance is rising to dangerously high levels in all parts of the world, leading to increased
iations. morbidity and mortality. Hence, the six leading mortality-causing pathogens—Escherichia
coli, Staphylococcus aureus, Klebsiella pneumoniae, Streptococcus pneumoniae, Acinetobacter bauman-
nii, and Pseudomonas aeruginosa—were responsible for 929,000 deaths attributable to AMR and
3.57 million deaths associated with AMR in 2019. This number could rise to 10 million by
Copyright: © 2022 by the authors.
2050 according to estimates by the WHO. Furthermore, the SARS-CoV-2 pandemic has
Licensee MDPI, Basel, Switzerland.
exacerbated the existing global crisis of AMR, mostly due to the mis- and over-use of antibi-
This article is an open access article
distributed under the terms and
otics, treatments that induce immunosuppression, and prolonged hospitalisation. Besides,
conditions of the Creative Commons
during the COVID-19 pandemic, limited ability to work with AMR partnerships, decreases in
Attribution (CC BY) license (https:// funding, and reduced availability of nursing, medical, and public health staff affected AMR
creativecommons.org/licenses/by/ surveillance, prevention, and control. In addition, increased use of disinfectants, including
4.0/). hand sanitisers and surface cleaners, is anticipated to cause increased rates of antimicrobial

Antibiotics 2022, 11, 427. https://doi.org/10.3390/antibiotics11040427 https://www.mdpi.com/journal/antibiotics
Antibiotics 2022, 11, 427 2 of 26

resistance in pathogenic microbes in the coming years. Replacement of first-line antibiotics
by more expensive medications, a longer duration of illness, and treatment-related to AMR
increases healthcare costs as well as the economic burden on patients and societies. The
World Bank estimates that drug-resistant infections could cause a global economic crisis,
leading to 28 million people who could be pushed into extreme poverty every year by 2050,
with an overall cost to the global economy of USD 1 trillion per year.
Throughout their evolution, bacteria have developed versatile resistance mechanisms
to antibiotics. The four main mechanisms of AMR are enzymatic inactivation of antimicro-
bial compounds, alteration of a drug target, reduced permeability of the outer membrane,
and active drug efflux. Hydrolases (e.g., beta-lactamases encoding by bla genes, such
as extended-spectrum beta-lactamases, ESBL; cephalosporinases; and carbapenemases),
passivation, and modified enzymes are three of the most important drug-inactivating
enzymes. An altered target site is a major cause of Gram-positive bacteria’s drug resistance
(e.g., PBP2a in methicillin-resistant S. aureus, MRSA by the acquisition of the mecA gene and
other homologues), as well as polymyxin-resistant bacteria. The membrane permeability is
a key in the level of susceptibility to antibiotics in some bacteria, such as Enterobacterales.
Modification of the bacterial envelope by decreasing the porin production or increasing the
expression of efflux pump systems (e.g., M phenotype in Streptococcus spp. encoding by
mefA gene) has been reported.
The causes of antimicrobial resistance are complex and multifaceted. In countries
where antibiotics are sold without a prescription or used as growth-promoting substances or
prophylactic additives in livestock farming, antibiotic-resistant bacteria develop especially
fast. Administration of antibiotics to patients with suspected moderate to severe bacterial
infections has been deemed inappropriate in at least half of the cases. Antimicrobial
stewardship (AMS) is one of the key strategies for combatting resistance. Implementation
of such programs is therefore recommended across the globe.
The present review provides an updated overview of the various antimicrobial sus-
ceptibility testing (AST) methods that are currently used or potentially applicable in the
foreseeable future, as well as their advantages and disadvantages.

2. The Rationale for Performing Susceptibility Testing
The choice of the best therapeutic option for the treatment of bacterial infections relies
on the results of AST, a part of the routine work of all clinical microbiological laboratories.
These reports provide insight into local patterns of antimicrobial susceptibility, helping
physicians to choose the most effective antibiotic therapy. For instance, if the AMR rate
of a pathogen is above 20%, that drug should not be administered as a single empiric ther-
apy for infection treatment. Evaluation of the effectiveness of prevention and infection
control measures relies as well on the results of AST, e.g., monitoring of resistant pathogens
such as MRSA (methicillin-resistant Staphylococcus aureus), VRE (vancomycin-resistant
enterococci), extended-spectrum beta-lactamase (ESBL)- and carbapenemase-producing En-
terobacterales, carbapenem-resistant Acinetobacter baumannii (CRAB), carbapenem-resistant
Pseudomonas aeruginosa (CRPA), colistin-resistant bacteria, etc.. Finally, surveillance of
antimicrobial resistance is based on routine clinical antimicrobial susceptibility data from
microbiological laboratories. Numerous AMR surveillance systems exist, of which the
WHOs Global Antimicrobial Resistance and Use Surveillance System (GLASS), European
Antimicrobial Resistance Surveillance Network (EARS-Net), and Antibiotic Resistance
Laboratory Network (AR Lab Network) of the Centers for Disease Control and Prevention
are the most recognizable networks of national surveillance systems providing information
on the actual burden of resistance at the international level. Policymakers and health
administrators revise the recommendations for empirical treatment for community or
hospital-acquired infections according to the local, national, and international AMR data.
In addition, prevention and infection control measures are implemented based on the same
data as a part of AMS programs [16,17]. Likewise, continuous monitoring provides early
warnings of emerging threats and identifies long-term resistance trends.
Antibiotics 2022, 11, 427 3 of 26

Although resistance surveillance at the national and international levels is of great
benefit to public health, knowledge of the local resistance rates is of even greater practical
importance to physicians. An antibiogram represents a convenient and widely available
measurement of an institution’s pathogens and susceptibilities. Therefore, it is in-
creasingly suggested that there is the necessity to create local (hospital or institutional)
antibiograms specific for each hospital and even ward, annually. This principle applies
especially to certain hospital departments where resistance rates are high, such as intensive
care units. Additionally, this is particularly relevant for secondary and tertiary hospitals
that treat chronically ill patients who have already received multiple antibiotic courses and
thus increase antimicrobial selective pressure. Klinker et al. provide the rationale for why
hospital AMS programs should implement alternative antibiograms, including combination
and syndromic antibiograms, in addition to traditional antibiograms. A combination
antibiogram is used to determine in vitro rates of susceptibility to potential antibacterial
combination regimens consisting of a first-choice antibiotic plus alternatives. A syndromic
antibiogram displays the likelihood of adequate coverage for a specific infection syndrome,
considering the weighted incidence of pathogens causing that syndrome. It was developed
by Hebert et al. as a weighted-incidence syndromic combination antibiogram. While
combination antibiograms are useful in determining combined empiric antibiotic regimens
for multidrug-resistant pathogens , syndromic antibiograms provide effective antibiotic
therapy for a specific infectious syndrome, such as hospital- and ventilator-associated
pneumonia. The Clinical and Laboratory Standards Institute (CLSI) has developed
guidelines (M39-A4) to provide a standardised template for the preparation of institu-
tional antibiograms. In a retrospective study by Puzniak et al. , the utility of combination
antibiograms in identifying optimal anti-P. aeruginosa drug regimens in US hospitals was
evaluated. They found that adding an aminoglycoside to backbone antibiotic, such as
extended-spectrum cephalosporin, carbapenem, or piperacillin-tazobactam, resulted in
higher susceptibility rates than adding a fluoroquinolone. They concluded that local insti-
tutional use of combination antibiograms ensures optimisation and timely administration
of appropriate empiric therapy of infections caused by difficult-to-treat pathogens.
Clinical laboratories currently employ several AST methods depending on the equip-
ment and laboratory test menu that they provide. Conventional AST based on phenotypic
testing examines the bacterial response in the presence of an antimicrobial agent. Classical
culture-dependent methods (e.g., a disk diffusion test, gradient diffusion method) are
firmly established in the diagnostic routine, and their main limitation is that the results are
obtained for most clinically important bacteria within at least 18–24 h or 48 h, including
prior bacterial isolation and identification. The turnaround time is prolonged for anaerobes
or some slow-growing fastidious bacteria such as the HACEK group (Haemophilus species,
Aggregatibacter species, Cardiobacterium hominis, Eikenella corrodens, and Kingella species),
Brucella spp. etc.. For many years, clinical laboratories have been equipped with
automated systems based on microdilution trays to provide faster results (6–24 h after
initial isolation). However, the time required to obtain the results is similar in comparison
with the broth microdilution (BMD) method. Molecular AST is based on the detection
of resistance determinants in bacterial isolates or directly in clinical specimens by molecular
methods with a turnaround time of approximately 1–6 h. Besides high costs, major
drawbacks of molecular methods are detection of the resistance genes targeted only by
the known probes and overestimating resistance because the resistance gene is not neces-
sarily associated with the expression of a resistance phenotype. Because of a significant
rise in multi- and pan-drug-resistant infections, there is an urgent need for a more rapid
and reliable test to improve infection diagnosis and support evidence-based antimicrobial
prescribing. The currently used methods for AST are summarised in Figure 1.
Antibiotics 2022, 11, x FOR PEER REVIEW 4 of 27

Antibiotics 2022, 11, 427 antimicrobial prescribing. The currently used methods for AST are summarised in 4 of 26
Figure 1.

Figure 1. Current methods for antimicrobial susceptibility testing and turnaround time (created with
FigureBioRender.com,
1. Current methods foron
accessed antimicrobial
27 Februarysusceptibility testingofand
2022. Reproduction thisturnaround time
figure requires (created from
permission
with BioRender.com., accessed on 27 February 2022. Reproduction of this figure requires permission
BioRender.com). PCR—polymerase chain reaction. qPCR—quantitative polymerase chain reaction.
from BioRender.com). PCR—polymerase chain reaction. qPCR—quantitative polymerase chain re-
NGS—next-generation sequencing. MALDI-TOF MS—matrix-assisted laser desorption/ionization
action. NGS—next-generation sequencing. MALDI-TOF MS—matrix-assisted laser desorption/ion-
izationtime-of-flight
time-of-flightmass
massspectrometry.
spectrometry.
3. Commonly Used Techniques
3. Commonly Used
3.1. Classical Techniques
Methods
3.1. Classical MethodsMethods: Broth Dilution and Agar Dilution
3.1.1. Dilution
3.1.1. Dilution Methods:
Although newBroth Dilution have
technologies and Agar
beenDilution
introduced to obtain data on bacterial sus-
ceptibilitynew
Although to antimicrobial
technologies have agents, conventional
been introducedtechnologies
to obtain dataare onstill in widespread
bacterial suscep- use.
tibility to antimicrobial agents, conventional technologies are still in widespread use. Be-broth
Besides disc diffusion susceptibility tests, the most widely used methods include
sides macro- and microdilution
disc diffusion susceptibility andtests,
agar dilution,
the most representing
widely usedthe reference
methods methods
include. By
broth
macro- using
and broth and agar and
microdilution dilution
agarmethods, the minimumthe
dilution, representing inhibitory
referenceconcentrations
methods.(MICs)By of
usingantimicrobial
broth and agar agents (i.e.,methods,
dilution the lowest theconcentration at whichconcentrations
minimum inhibitory the agent inhibits the of
(MICs) growth
of microorganisms)
antimicrobial canlowest
agents (i.e., the be determined [29,30].
concentration The MIC
at which valueinhibits
the agent servesthe as growth
the basis for
of microorganisms) can be determined [29,30]. The MIC value serves as the basis for as- that
assessing the susceptibility category of the pathogen to a given antibiotic, of organisms
sessinggive
theambiguous results,
susceptibility and especially
category when no
of the pathogen to aclinical breakpoints
given antibiotic, of for disk diffusion
organisms that are
give ambiguous results, and especially when no clinical breakpoints for disk diffusiondegree
available. Contrary to a qualitative method, the MIC value allows assessing the are of
susceptibility or resistance to the antibiotic. Besides the determination
available. Contrary to a qualitative method, the MIC value allows assessing the degree of of MICs, the ad-
vantage of
susceptibility or broth dilution
resistance methods
to the is the.
antibiotic possibility
Besidesofthe
obtaining the minimum
determination of MICs, bactericidal
the
advantage of broth dilution methods is the possibility of obtaining the minimum bacteri- that
concentration (MBC), which is the lowest concentration of an antimicrobial substance
cidal kills 99.9% of bacteria
concentration (MBC),.
which is the lowest concentration of an antimicrobial sub-
The macrodilution
stance that kills 99.9% of bacteria method,.also known as the in-tube dilution test, uses serial two-fold
dilution of antimicrobial substances in corresponding media. A known concentration of
suspended bacteria is added to the tubes prepared, as described in. After 24 h of
incubation at 37 ◦ C, bacterial growth is measured by turbidity of media, allowing visual
Antibiotics 2022, 11, 427 5 of 26

determination of MIC values. Another macrodilution method is the time-kill methodol-
ogy. This test allows monitoring of the effect of different concentrations of antimicrobial
substances by examining the rate at which antimicrobials lead to bacterial death—i.e., the
bactericidal activity of antimicrobial agents is determined depending on the concentration
and time. Bacterial viability is determined by counting colonies on agar plates at regular
time points for 24 h. The rate of bacterial growth is monitored via changes in log
CFU/mL during the first 24 h time-kill test. Based on the results, experimental curves
which represent the absence of growth or the killing effect can be constructed and give us
insight into the interaction between the bacteria and the antimicrobial agent. The data can
be further analysed using different mathematical models [30,34,35].
The BMD method is standardised, accurate, and inexpensive. Since it is performed
in 96-well microtiter plates, it allows the testing of several antimicrobial substances in
a row and eight series of two-fold dilutions of antimicrobial agents in one plate. After
the dilutions are made, each well is inoculated with standardised bacterial inoculum and
incubated for at least 16–24 h. Although this procedure is used as a reference method, it
has been improved by the addition of a resazurin colour redox indicator. Resazurin is
a blue colour that turns into pink, fluorescent resorufin in the presence of metabolically
active bacterial cells. The reduction of resazurin to fluorescent resorufin can be measured
fluorimetrically [27,32,36–38]. Nowadays, there are several commercially available easy to
perform BMD systems such as MBD Sensititre System (Thermo Fisher Scientific, Waltham,
MA, USA) and ComASP Colistin (Liofilhem, Roseto degli Abruzzi, Italy), formerly Sen-
siTest Colistin. The MBD Sensititre System can be performed manually or automatically.
ComASP Colistin is a compact panel containing the antibiotic colistin in seven two-fold
serial dilutions and allows for four samples to be tested simultaneously with the BMD
method.
The agar dilution method involves adding different concentrations of antimicrobial
substances to the non-selective medium before solidification. Afterwards, the stan-
dardised bacterial inoculum is spotted on the agar surface. Following overnight incubation,
plates are evaluated visually, determining whether growth has occurred at the inoculated
sites. The lowest concentration of antibiotics that prevent bacterial growth is considered to
be the MIC. This method allows simultaneous testing of different bacterial strains.

3.1.2. Antimicrobial Gradient Method
The gradient strip test is a combination of disk-diffusion and dilution method of AST,
having advantageous properties of both methods. It allows the MIC to be determined while
keeping it simple and easy to use. The method is based on the diffusion of an antibiotic
through agar with a continuous gradient. A concordance of the susceptibility categories and
MIC values obtained by gradient test and BMD method, a “gold standard” recommended
by the European Committee on Antimicrobial Susceptibility Testing (EUCAST) and CLSI,
were observed [28,42]. For example, the new ceftazidime–avibactam and ceftolozane–
tazobactam gradient tests (Etests, bioMérieux, Marcy-l’Étoile, France) have shown a high
categorical agreement between gradient test and BMD, of 96% and 94%, respectively [43,44].
On the other hand, for some antibiotics, such as colistin and tigecycline , controversial
results have been obtained. Some agar-related factors, i.e., the content of divalent cations,
can affect the diffusion of colistin, resulting in false susceptibility. Consequently, BMD
remains the only appropriate method for MIC determination for certain antibiotics.
Currently, a few commercial gradient strip tests, such as Etest (bioMérieux, France), MIC
Test Strip (Liofilchem, Roseto degli Abruzzi, Italy), M.I.C.Evaluator (Thermo Scientific,
Waltham, MA, USA), and Ezy MIC Strip (HiMedia Laboratories, Mumbai, India), are
available. They can be used for susceptibility testing of microorganisms to antibiotics
and antifungals [48–50].
A gradient strip test is performed according to the manufacturer’s instructions: a short
plastic or paper strip impregnated with antibiotic is placed on inoculated agar (Figure 2).
On the standardised 100 mm Petri dish, two strips may be placed, while on the larger
 Antibiotics 2022, 11, x FOR PEER REVIEW 6 of 27

available. They can be used for susceptibility testing of microorganisms to antibiotics
and antifungals [48–50].
Antibiotics 2022, 11, 427 6 of 26
A gradient strip test is performed according to the manufacturer’s instructions: a
short plastic or paper strip impregnated with antibiotic is placed on inoculated agar (Fig-
ure 2). On the standardised 100 mm Petri dish, two strips may be placed, while on the
150 mm150
larger Petri
mm dish, updish,
Petri to sixupantibiotics may be tested
to six antibiotics may be simultaneously. The MICThe
tested simultaneously. of a MIC
tested of
agent is determined by the intersection of a zone of inhibition with the strip and
a tested agent is determined by the intersection of a zone of inhibition with the strip and measured
using labelled
measured concentrations
using on the strip.on
labelled concentrations If the
the intersection
strip. If the is between two
intersection values on
is between twoa
scale, a higher value is reported as MIC. In addition, if beta-haemolysis is
values on a scale, a higher value is reported as MIC. In addition, if beta-haemolysis is present on the
plate, careful
present examination
on the of the
plate, careful strip is required
examination sinceisthe
of the strip reporting
required ofthe
since thereporting
intersection of
of the
haemolysis leads to false higher MICs values. Automated systems for reading the results
intersection of haemolysis leads to false higher MICs values. Automated systems for read-
of gradient tests are also available (ADAGIO Automated System, Bio-Rad Laboratories,
ing the results of gradient tests are also available (ADAGIO Automated System, Bio-Rad
Hercules, CA, USA).
Laboratories, Hercules, CA, USA).

Figure 2. Disk diffusion and gradient test of various bacterial isolates. (A)—Antimicrobial suscepti-
Figure 2. Disk diffusion and gradient test of various bacterial isolates. (A)—Antimicrobial
bility of Streptococcus pyogenes showing iMLS phenotype, using disk diffusion method. (B)—Anti-
susceptibility of Streptococcus
microbial susceptibility pyogenes showingbeta-lactamase-producing
of extended-spectrum iMLS phenotype, using disk diffusionaeruginosa,
Pseudomonas method.
(B)—Antimicrobial
using disk diffusion susceptibility of extended-spectrum
method. (C)—Gradient beta-lactamase-producing
test of Enterococcus Pseudomonas aerugi-
spp. iMLS phenotype—inducible
nosa, using disk
macrolide, diffusion method.
lincosamide, (C)—Gradient
and streptogramin test of Enterococcus spp. iMLS phenotype—inducible
phenotype.
macrolide, lincosamide, and streptogramin phenotype.
A variation of gradient tests exists for the detection of various AMR phenotypes.
A variation
Currently, Etestsofforgradient testsdetection
phenotypic exists forofthe
ESBLdetection of various
production AMR phenotypes.
in enterobacteria are avail-
Currently,
able, suchEtests forwith
as strips phenotypic detection of ESBL
cefotaxime+clavulanic production
acid, ceftazidimein with
enterobacteria
clavulanicare avail-
acid, and
able, such as strips with cefotaxime+clavulanic acid, ceftazidime with clavulanic acid, and
cefepime with clavulanic acid. The gradient tests for ESBL detection are two-sided
cefepime with clavulanic acid. The gradient tests for ESBL detection are two-sided
strips that contain antibiotic on one end, while on the other is the same antibiotic with
strips that contain antibiotic on one end, while on the other is the same antibiotic with
clavulanic acid. Reduction in MIC equal to or greater than eight times by the combination
clavulanic acid. Reduction in MIC equal to or greater than eight times by the combination
of antibiotic and clavulanate refers to ESBL production. Similar to the double-disk
of antibiotic and clavulanate refers to ESBL production. Similar to the double-disk
synergy test, the phantom zone below the clavulanic end also indicates a positive result.
synergy test, the phantom zone below the clavulanic end also indicates a positive result.
Identification of metallo-beta-lactamase (MBL)-producing bacteria can be carried out us-
Identification of metallo-beta-lactamase (MBL)-producing bacteria can be carried out using
ing a gradient test. These tests contain carbapenem antibiotic on one side of the strip and
a gradient test. These tests contain carbapenem antibiotic on one side of the strip and the
the same carbapenem with EDTA on the other side. Imipenem with EDTA for detection
same carbapenem with EDTA on the other side. Imipenem with EDTA for detection of MBL
of MBL in Acinetobacter spp. and Pseudomonas spp. is available, although sensitivity and
in Acinetobacter spp. and Pseudomonas spp. is available, although sensitivity and specificity
specificity may vary [53,54]. For detection of AmpC beta-lactamase-producing enterobac-
may vary [53,54]. For detection of AmpC beta-lactamase-producing enterobacteria, Etest
teria, Etest impregnated
impregnated with cefotetanwithoncefotetan
one end andon one end and cefotetan–cloxacillin
cefotetan–cloxacillin on the otheronendthe other
can be
end can be used. Gradient tests with a predefined gradient of vancomycin
used. Gradient tests with a predefined gradient of vancomycin and teicoplanin on each and
teicoplanin
side on can
of the strip eachbeside
usedoffor
thethe
strip can beofused
detection for the detection
glycopeptide resistanceof in
glycopeptide re-
Staphylococcus
sistance
aureus in Since. Staphylococcus
these testsaureus.toSince
are easy thesethey
perform, testscould
are easy to perform,
be used they could
as “screening” be
tests
used as “screening” tests for the detection of emerging resistance patterns
for the detection of emerging resistance patterns among clinically relevant bacteria. among clini-
callyPlenty
relevant bacteria. of gradient tests are known: simple performance, flexibility in
of advantages
the testing of any combination of antibiotics, and the fact that they do not require expertise
and special technologies. Moreover, their use is suited when only a couple of antibiotics
are needed to be tested. The price of each strip is relatively high, compared with the price
of disks; therefore, gradient tests are usually used to test only a few antibiotics per strain.
The incubation length of 16–24 h for gradient tests may represent a disadvantage, as more
rapid automated systems are available with the reliable determination of MIC.
Antibiotics 2022, 11, 427 7 of 26

3.1.3. Disk Diffusion Test
Since its development in 1940, the disk diffusion (DD) test has remained the most
widely used routine AST in clinical microbiological laboratories. It has been stan-
dardised to test the susceptibility of the most common and clinically relevant bacteria that
cause human diseases [42,58]. The standardisation is a continuous process, and DD for
many microorganisms/antimicrobials is an ongoing process. The method is based on
placing different antibiotic-impregnated disks on previously inoculated agar with bacterial
suspension. The antibiotic diffuses radially outward through the agar medium, producing
an antibiotic concentration gradient. After the inhibition zones are established within 24 h
of incubation at 35 ± 1 ◦ C, the zone diameters of each tested antibiotic are measured by the
naked eye or using an automated system. Obtained results should be interpreted and
categorised according to the recommended clinical breakpoint of the standard in use [42,61].
Disk diffusion is the most widely used AST method in microbiology laboratories because
of its low cost and ease of performance and applicability of numerous bacterial species and
antibiotics. The choice of antibiotic disks is flexible and enables the clinical laboratory
to make different combinations according to the bacterial species and the type of sample
the isolate was obtained from. Simple interpretation allows the detection of atypical
phenotypes and visibility of contamination. However, the main disadvantages are the
inability to determine the MIC and delays in getting the results. Reduction in turnaround
time and timely treatment are of great importance for critically ill patients. In addition,
the biological properties of lag and log phase of bacterial growth and their expression on
antibiotic influence should be considered. Nevertheless, methods to reduce incuba-
tion time for DD were suggested decades ago [64–66]. A revival of that idea led to the
development of automated systems (WASPLab, Copan, Murrieta, CA, USA and BD Kiestra,
Becton, Dickinson and Company, Franklin Lakes, NJ, USA) for an acceleration of AST by
DD [67,68]. The automatisation of the AST by DD leads to a shortening of the required
time to obtain results and produce the final report. EUCAST has defined a methodol-
ogy of disk diffusion rapid AST (RAST), which is performed directly from positive blood
culture bottles, with breakpoints for short incubations of 4, 6, and 8 h [69–71]. RAST can
be implemented in routine laboratories without major investments. The method has been
validated for a limited number of bacterial species and antibiotics so far. Furthermore, the
combined use of a MALDI-TOF MS for the identification of bacteria and RAST directly
from positive blood bottles enables reporting AST results within less than 24 h, which
significantly reduced the turnaround time compared with the 24–48 h needed for culturing
and classical AST methods, such as DD. The predictive value of direct DD testing from
positive blood cultures has been reported to have an important influence on AMS.
Quality control testing of media and antibiotics is of great importance for ensuring
that disk diffusion is providing accurate and reliable results [59,74]. In some cases, the DD
method is more reliable than MIC determination. For instance, in the case of detecting
penicillinase-producing S. aureus strains, the inhibition zone diameter combined with the
EUCAST-based zone edge test is the most sensitive and specific phenotypic method [42,75].
The DD method can be used for screening of susceptibility to a larger number of antibiotics
or a whole class of antibiotics; detection of certain important resistance phenotypes, such
as ESBL, carbapenemases, inducible resistance to macrolides (Figure 2); or the presence
of a heteroresistant population of bacterial species in a sample that cannot be detected by
other phenotypic AST methods. The above-mentioned suggests that the DD method will
remain a widely used AST method in the future.

3.1.4. Chromogenic Agar Media for Detection of Antimicrobial-Resistant Bacteria
Since the introduction of the first chromogenic media for the detection of antibiotic-
resistant bacteria 20 years ago, a variety of different media for the detection of clinically
important resistant pathogens—such as MRSA, VRE, and ESBL- and carbapenemases-
producing or colistin-resistant Gram-negative bacteria—have been developed [76–80].
Antibiotics 2022, 11, 427 8 of 26

The main purpose of the development of chromogenic media was to enable more
rapid detection and identification of resistant microorganisms. The target organisms are
characterised by specific enzyme systems that metabolise the substrates to release the
chromogen. The chromogen can then be visually detected by direct observation of a distinct
colour change in the medium. Thus, these selective and differential media enable target
pathogens to grow as coloured colonies. Compared with the use of conventional culture
media, the use of chromogenic agar often reduces the costs and labour time. Their
primary use is for screening of patients colonised with various pathogens, and therefore
they are valuable in infection prevention and control of hospital-acquired infections.
The sensitivity and specificity of chromogenic media depend on the manufacturer and the
type of microorganism detected; thus, additional identification confirmation of the resistant
bacteria is sometimes needed. Because of their wide applicability, new chromogenic media
are being developed [83,84].

3.1.5. Colourimetric Tests for Detection of Antimicrobial-Resistant Bacteria
Colourimetric tests represent phenotypic methods developed for the detection of AMR.
They are based upon the bacterial enzymes hydrolysing test component, which is detected
by the changes in pH values and the colour of chromogenic substances. Briefly, bacterial
suspension or bacterial lysate suspension is added to a detection solution containing
antibiotic and pH indicator dyes, such as phenol red, and incubated for a short period of
time, no longer than a couple of hours. The pH of the detection solution changes due to
the growth of antibiotic-resistant bacteria, or bacterial enzymes activity, and subsequently,
the colour of the solution changes, which can then be visually observed. These tests were
shown to be fast, easy to perform and interpret, and highly sensitive and specific. A good
example of such colourimetric tests is Carba NP (bioMérieux, Marcy-l’Étoile, France), which
detects carbapenemase-producing bacteria. The test gives reliable results in 30 min to 2 h,
making it the quick and easy way to control carbapenemase producers.

4. Current Technologies for Rapid AST
4.1. Automated and Semi-Automated Devices Based on Microdilution Susceptibility Testing
Clinical microbiology laboratories are under increasing pressure to provide fast and
reliable microbial identification (ID) and AST. Automated and semi-automated devices
for bacterial ID and AST are worthy of the task and have significantly improved laboratory
efficiency. Nowadays, automation has been successfully implemented in most clinical
microbiological laboratories to reduce turnaround times, increase efficiency, and improve
cost-effectiveness [86,87]. Various test systems—such as the VITEK 2 (bioMérieux, France),
MicroScan Walkaway (Dade-Behring MicroScan, Deerfield, IL, USA), and Phoenix system
(BD Diagnostic Systems, Baltimore, MD, USA)—have been widely used over the last
decades. These instruments, using optical systems for measuring subtle changes, determine
bacterial growth and antimicrobial susceptibility and can produce results in a shorter
time (6–12 h) than conventional manual assessment.
VITEK 2 Systems—The first generation of VITEK system with a turnaround time of 13 h
was developed for enumeration and identification of bacteria and yeasts in 1973. The
VITEK 2 System, the next-generation of an instrument, is a BMD-based AST system that
uses 64-well plastic cards containing 17–20 antimicrobial agents. If the bacterial isolate
is not previously identified, one card is used for bacterial identification (ID card) and
the other for antimicrobial susceptibility testing (AST card). Two Vitek 2 instruments
are available with test card (ID and AST) capacities of 60 cards (Vitek 2) and 120 cards
(Vitek 2 XL). Results are reported in 4–18 h, containing MIC and category of susceptibility,
whereas the detection of AMR is facilitated by the Advanced Expert System (AES). The
currently available Vitek 2 Compact instruments can use 15, 30, and 60 cards. The
main advantage of the Vitek 2 system with computer software is the determination of
susceptibility of clinically important resistant pathogens, such as Staphylococcus aureus
and Enterococcus faecalis, to an additional four to ten antibiotics [86,89,90].
Antibiotics 2022, 11, 427 9 of 26

Phoenix System—The Phoenix System is widely accepted and used in clinical mi-
crobiology laboratories for identification testing (ID) and antimicrobial susceptibility
testing (AST). The principle of determining the susceptibility is based on the use of
an oxidation-reduction indicator (resazurin dye or Alamar blue) and the detection of
bacterial growth in the presence of various concentrations of the antimicrobial agent.
In the Phoenix instrument, a maximum of 100 tests can be performed by using Phoenix
ID/AST combination panels (51 for ID and 85 for AST). The instrument performs
automatic reading at 20 min intervals during incubation for up to 18 h and provides
accurate and rapid susceptibility results with easy workflow for the laboratory worker.
In 2014, the new panel for susceptibility of Gram-negative bacteria was introduced for
the Phoenix system to be used in combination with the BD Bruker MALDI-TOF.
MicroScan WalkAway plus System—The MicroScan WalkAway plus System provides
accurate and rapid identification and susceptibility results for a wide range of Gram-
positive and Gram-negative aerobic bacteria. The instrument utilises three types of
panel configurations: combo panels, breakpoint combo panels, and MIC panels. There
are two types of system: 40- and 96-panel capacity models. The panels are manually
inoculated, rehydrated by the RENOK inoculator, and read automatically. The results
are obtained after 4.5–18 h by reading of rapid panels.
MicroScan AutoScan 4—The AutoScan 4 is a semiautomated instrument mostly used
in smaller laboratories or for the testing of supplemental antimicrobial agents. The
instrument provides simplified ID/AST testing in a highly reliable and affordable
package. The system uses the off-line incubation of the conventional MicroScan AST
panels. The panels are manually inoculated or with the MicroScan Renok instrument
and read automatically.
MicroScan WalkAway System—The first generation of the MicroScan WalkAway
System available on the market is the AutoSCAN-3. The new versions of instruments
Auto-ACAN-4 and AutoSCAN-WalkAway are improved and use dry panels that do
not need refrigeration. The AutoSCAN-WalkAway system detects bacterial enzymatic
activity and can process 96 panels at the same.
Each of the above-mentioned systems has inherent advantages and limitations, and
the results vary widely by antimicrobial drugs, software versions, and cards used. Hence,
some of the systems are not reliable for correct categorisation of susceptibility profiles for
certain drugs, leading to wrong classifications of susceptibility categories. It seems
that low inoculum size has a major influence on the outcome of these systems, with false
susceptibilities being reported. Additionally, software updates and synchronisation of
breakpoints according to the current standards are mandatory. Thus, it is incumbent upon
the instrument manufacturer to keep pace with the breakpoint updates and make relevant
improvements, such as extending the detection limit and verifying the performance of the
AST system with the revised breakpoints internally, to avoid the problem of uncategorised
results. Panels usually contain only several concentrations of each antimicrobial agent,
and the resulting MIC is not always given as an exact value. In contrast, classical BMD con-
tains a wide range of doubling dilution antimicrobial concentrations for the determination
of the MIC, thus obtaining the more precise value. In addition, according to the previously
published reports, many of the resistance phenotypes are not easily detected using the
automated susceptibility testing methods so prevalent in today’s clinical laboratories.
Nonetheless, interestingly, the ability of automated systems to detect inducible resistance
to clindamycin in 524 isolates of Staphylococcus spp. revealed sensitivity and specificity of
100% and 99.6%, respectively, for Phoenix, and 91.1% and 99.8%, respectively, for Vitek
2. The multicentre evaluation showed that categorical agreement between the Phoenix
system and a BMD reference method for 2013 streptococcal isolates including Streptococcus
pneumoniae, viridans group streptococci, and beta-haemolytic Streptococcus groups A, B, C,
and G ranged from 92% to 100%, with one exception for viridans streptococci and penicillin,
which was 87%. However, according to the results of the evaluation of ASTs obtained
 ity and specificity of 100% and 99.6%, respectively, for Phoenix, and 91.1% and 99.8%,
respectively, for Vitek 2. The multicentre evaluation showed that categorical agree-
ment between the Phoenix system and a BMD reference method for 2013 streptococcal
isolates including Streptococcus pneumoniae, viridans group streptococci, and beta-haemo-
lytic Streptococcus groups A, B, C, and G ranged from 92% to 100%, with one exception for
Antibiotics 2022, 11, 427 10 of 26
viridans streptococci and penicillin, which was 87%. However, according to the re-
sults of the evaluation of ASTs obtained using Vitek 2, Phoenix, and MicroScan, caution
should be taken for AST of Stenotrophomonas maltophilia, as a high rate of errors may be
using 2, Phoenix, and MicroScan, caution should be taken for AST of Stenotrophomonas
Vitek.
observed
maltophilia, as a high rate of errors may be observed.
4.2. Molecular-Based Techniques for Resistance Detection
4.2. Molecular-Based Techniques for Resistance Detection
Molecular AST directly detects specific resistance genes, as well as mutations in and
Molecular AST directly detects specific resistance genes, as well as mutations in and
expression of these genes. These molecular methods have been developed and tested as
expression of these genes. These molecular methods have been developed and tested as an
an alternative for or complementary to conventional AST and are generally faster than
alternative for or complementary to conventional AST and are generally faster than classic
classic culture-based
culture-based assays,
assays, with the with the test
test results results available
available within onewithin onehours
to a few to a few
hours
(Figure
3).
(Figure 3). Most of the molecular AST methods fall into one of the three categories:
Most of the molecular AST methods fall into one of the three categories: amplification-based, ampli-
fication-based, hybridization-based,
hybridization-based, or sequence-based. or sequence-based. In amplification-based
In amplification-based methods,
methods, the target gene
the target gene sequence is amplified to allow detection; in hybridization-based
sequence is amplified to allow detection; in hybridization-based techniques, hybridized tech-
niques, hybridized nucleic acid probes target gene sequences allowing
nucleic acid probes target gene sequences allowing detection; and in sequence-based detection; and in
sequence-based
approaches, approaches,
genome sequences genome sequences
are analysed are analysed
to detect to detect resistance-confer-
resistance-conferring mutations or
ring mutations
resistance genes. or resistance genes.

Figure3.
Figure 3. The
Thebasic
basicworkflow
workflowofofmolecular-based
molecular-based techniques
techniques forfor antimicrobial
antimicrobial susceptibility
susceptibility testing.
testing. The
The routes from a clinical specimen to a final result are indicated by arrows (created
routes from a clinical specimen to a final result are indicated by arrows (created with BioRender.com, with
accessed on 27 February 2022. Reproduction of this figure requires permission from BioRender.com).

4.2.1. Polymerase Chain Reaction
The most widely used nucleic acid amplification-based method for the detection of
specific resistance genes is polymerase chain reaction (PCR). Both real-time and conven-
tional PCR rely on the amplification of nucleic acid sequences that encode resistance to
an antibiotic. New PCR-based methods are being developed for the detection of genetic
determinants of resistance to a variety of antibiotics for various bacterial species, as our
knowledge about the genetic basis of antibiotic resistance increases. Multiplex assays
for simultaneous testing of multiple genetic determinants in various bacterial species have
also been developed, i.e., multiplex assays for identifying numerous cephalosporinase-
and carbapenemase-encoding genes, such as blaKPC , blaNDM , blaIMP , blaVIM , blaAmpC , blaTEM ,
blaSHV , and blaOXA , or mecA gene-encoding methicillin resistance in MRSA [100,101]. Op-
Antibiotics 2022, 11, 427 11 of 26

Gen, Inc. (Rockville, MD, USA) has recently released the multiplex-based Acuitas® AMR
Gene Panel that detects 28 genetic AMR markers, covering select drugs in nine classes of
antibiotics, from 26 different pathogens. The advantage of this test in comparison
with other commercially available molecular tests is that it also detects non-beta-lactam
resistance genes and those for what would be considered “last-resort antibiotics”, such
as colistin.
Real-time PCR (quantitative PCR, qPCR) is one of the most ubiquitous methods found
throughout clinical microbiology. Although costlier, qPCR offers several advantages over
conventional PCR, including the measurement of data in real-time, greater sensitivity,
reduced risk of carryover contamination, and greater amenity to multiplexing. Further
advantages are that many systems are partially or even completely automated, such as
GeneXpert® Instrument Systems (Cepheid Corp., Sunnyvale, CA, USA) and BD MAX
System platform (Becton Dickinson, Franklin Lakes, NJ, USA), which are easily operated
and can be used for the detection of carbapenemases, ESBLs, MRSA, VRE, etc. [103–105].
The downside is that they are limited to using test assays only from specific manufacturers,
with GeneXpert® Instrument Systems requiring GeneXpert assays (Cepheid Corp., Sun-
nyvale, CA, USA) and BD MAX System using Check-Points® qPCR assays (Wageningen,
The Netherlands). Tests based on qPCR can also be used for phenotypic differentiation of
resistant and susceptible strains due to its ability to measure genome copy numbers during
bacterial growth in the presence of antibiotics. The major disadvantage is that the
system cannot provide information about the mechanism of resistance and that it requires
the previous culture, meaning that the primary clinical samples cannot be used.

4.2.2. DNA-Microarrays
DNA-microarrays are used to identify the presence of specific nucleic acid sequences
using complementary short oligonucleotides immobilised on a solid surface. Since these
oligonucleotides can be assembled onto solid surfaces in close proximity, this method could
detect numerous sequences in a single assay, which would allow simultaneous, in parallel
detection of different pathogens and detection of vast numbers of different resistance genes,
as well as detecting numerous distinct mechanisms of resistance or variants of a single
mechanism present in bacterial isolates, as opposed to PCR-based approaches. The
Verigene system (Luminex Corporation, Austin, TX, USA) has developed Blood Culture
Multiplex Microarray-Based Molecular assays for rapid diagnostics of 12 Gram-positive
and 9 Gram-negative bacteria, along with their associated resistance genes (i.e., mecA, vanA,
vanB, blaKPC , blaNDM , blaIMP , and blaVIM ). In addition to qPCR-based assays, Check-
Points® has also developed the CHECK-MDR CT103 DNA microarray for the detection
of the clinically most prevalent ESBLs and carbapenemases, as well as mobile colistin
resistance (mcr) genes in Gram-negative bacteria. Both of these microarray tests have
shown high sensitivity (94–100%) and specificity (94–98%), and CHECK-MDR CT103 DNA
microarray also showed the ability to discriminate between carbapenemase and ESBL
variants of GES-type beta-lactamase [108,109].
The advantages of currently available molecular-based methods are that they are direct,
rapid, highly sensitive, and specific, thus potentially allowing the earlier administration
of targeted therapy. Furthermore, for some methods, direct clinical samples can be
used. However, it should be noted that the presence of a resistance marker does not
always have to correlate with phenotypic resistance. Additionally, the extent and intensity
of gene expression are important parameters, as some genes need different expression
levels to produce resistance. A potential solution to this issue would be the use of reverse
transcription qPCR, which relies on the measurement of gene transcripts (RNA levels)
instead of the presence of a gene [110,111]. Another drawback is that these methods can
only detect resistances that are searched for, and not novel or uncharacterised mechanisms
of resistance, which could lead to false-negative results and inappropriate classification of
resistant isolates as susceptible. A final consideration is that these methods are not capable
of defining MIC values. As such, these methods have to be validated against phenotypic
Antibiotics 2022, 11, 427 12 of 26

data to be useful, and extensive resistance marker databases and innovative bioinformatics
methodologies are mandatory requirements. Nevertheless, molecular-based AST methods
are a safe, efficient, and reliable screening tool in clinical settings. As experience with these
tests grows, and as data are gathered on their efficacy and clinical impact, they will likely
be more widely adopted.

4.2.3. Whole-Genome Sequencing in Antimicrobial Susceptibility Testing
As DNA sequencing technology and bioinformatics pipelines for genome assembly
and analysis advance, the possibility of using these techniques for the detection of an-
tibiotic resistance opens. Applying whole-genome sequencing (WGS) would essentially
enable the detection of all genes involved in AMR, which would help make comprehen-
sive databases of all species-specific resistance factors (i.e., CARD-Comprehensive Antibi-
otic Resistance Database—https://card.mcmaster.ca, ResFinder—https://cge.cbs.dtu.dk/
services/ResFinder (accessed on 27 February 2022)) and make in silico AMR detection
possible. Recent studies showed high concordance between the resistance profiles obtained
using WGS and those obtained using phenotypic susceptibility testing, demonstrating that
data obtained from genome sequences can correlate well with phenotypic resistance in
some cases [112,113]. In addition to genome-based resistome analyses, RNA-mediated tran-
scriptomic approaches have also been described [114,115]. Despite all of the advantages,
WGS is not routinely performed in clinical practice. Considering the turnaround times of
WGS, the existence of unknown resistance mechanisms, and the elevated cost compared
with traditional and emerging techniques, the use of WGS for AST is not yet part of routine
practice in clinical microbiology [116,117].

4.3. Mass Spectrometry
Matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-
TOF MS) was discovered in the 1980s and introduced into the microbiological routine as an
effective tool for bacterial and yeast identification about 15 years ago. It has been applied
to classify the specific bacterial protein contents and their matching protein biomarkers
because of its rapid turnaround time, low sample volume requirements, and per-sample
costs. Several MALDI-TOF MS-based methods have been proposed for rapid detec-
tion of antimicrobial resistance, including monitoring antibiotic modification by bacterial
culture (e.g., beta-lactam hydrolysis [65,119]), acetylation of fluoroquinolones , direct
detection of proteins involved in specific resistance mechanisms [121,122], and detection
of stable isotope labelling that requires expensive, isotopically labelled media [123,124].
The hydrolysis of the target beta-lactam antibiotic, as shown by peak disappearance, is
used to detect beta-lactamase-producing bacteria using MALDI-TOF MS. As a result, the
assay for detecting carbapenemase production automatically determines sensitivity
or resistance depending on the degree of antibiotic hydrolysis. The method had 98% sensi-
tivity and 100% specificity after 30 min of incubation of bacteria with the antibiotic, with
both reaching 100% after 60 min of incubation [126,127]. However, beta-lactam resistance is
only recognized when it is mediated by beta-lactamases; alternative resistance mechanisms
have not been elucidated; therefore, other tests should confirm negative results. Another
assay for the detection of carbapenemases is a rapid and novel method using detonation
nanodiamonds (DNDs) as a platform for the concentration and extraction of A. baumannii
carbapenemase-associated proteins before MALDI-TOF MS analysis. The sensitivity
and the specificity of the proposed platform could reach 96% and 73%, as compared with
traditional imipenem susceptibility testing, and 100% compared with PCR results. This
method may detect the carbapenemases produced by A. baumannii in 90 min and does not
require the addition of a carbapenemase substrate, as other mass spectrometric methods
do. It is efficient for detecting other carbapenemase-producing bacteria.
MALDI Biotyper-Antibiotic Susceptibility Test Rapid Assay (MBT-ASTRA) is an al-
ternative MS-based method for AST which utilises semi-quantitative MALDI-TOF MS to
measure the relative growth rates of bacterial isolates exposed to antibiotics compared
Antibiotics 2022, 11, 427 13 of 26

with untreated controls during a short incubation step. A software tool calculates and
compares the area under the curves (AUCs) of spectra of bacteria either exposed or not
to an antibiotic. In this method, if the microbial strain is susceptible, the AUC of
the bacterial suspension with the antibiotic will be reduced compared with that without
antibiotics, whereas with a resistant strain the AUCs with or without antibiotics will be
comparable. The main advantage of the MBT-ASTRA is that the assay does not depend
on the resistance mechanism and is utilisable with any antibiotic. Moreover, it does
not require specialised media or instrumentation, beyond the MALDI-TOF mass spec-
trometer. However, a drawback of the MBT-ASTRA assay is that the concentration of
antibiotics used and the incubation time must be optimised for each species and antibiotic
combination.
MBT-Resist assay, based on the detection of peak shift after stable isotope labelling, is
an approach that uses the following principle: bacteria are grown in parallel in two distinct
culture mediums, one containing 12C as a carbon component and the other containing
13C. The system compares the mass spectrum of bacteria grown on an isotope-labelled
medium with antibiotics to the mass spectrum of the same strain grown on an unlabelled
medium without antibiotics. Resistant strains can thrive in the presence of antibiotics,
incorporating 13C into the polypeptide, causing a shift in the peak to a higher m/z in the
mass spectrum.
Antibiotic resistance by direct-on-target microdroplet growth assay (DOT-MGA) is
a novel approach for detecting antimicrobial susceptibility in bacteria treated with break-
point concentrations of antibiotic on the target plate of MALDI-TOF MS. The best
performance was obtained by recovering bacteria from positive blood cultures and after a
4 h incubation of microdroplets with or without meropenem at the breakpoint concentra-
tion. Under these conditions, 96.3% validity, 91.7% sensitivity, and 100% specificity were
achieved. Recently, a screening panel for the detection of ESBL and AmpC beta-lactamase
activity was developed. Compared with the PCR results, positive percentage agree-
ment values for ESBL, AmpC, and ESBL + AmpC resistance were 94.4%, 94.4%, and 100%,
and negative percentage agreement values were 100%, 93.7%, and 100%, respectively. The
accuracy of the DOT-MGA achieved results incomparable with those of the BMD assay,
with a time saving of about 14 h, and higher than combination disk tests.
According to Yoon et al., due to the great speed and simple application, MALDI-
TOF MS would be the most suitable for endemic AMR clinical strains in specific set-
tings, i.e., MRSA, VRE, CRAB, CRPA, and ESBL-, AmpC-, and carbapenemase-producing
Enterobacterales.
The advantages and disadvantages of the commonly used methods of antimicrobial
susceptibility testing were summarised in Table 1.

Table 1. Advantages and disadvantages of the common methods of antimicrobial susceptibility testing.

Method Advantage Disadvantage Comments
Broth dilution Well-standardised Time-consuming Quantitative **
Harmonised Individual mistakes
Commercially available tests are easy to perform
Agar Dilution Well-standardised Time-consuming Quantitative
Limited concentration of Possible automation
Suitable for testing a large number of isolates
antimicrobial agents in part
Disk diffusion Simple to perform Time-consuming Qualitative *
Low cost No MIC value
The inability for some
Simple and fast interpretation
antibiotics to be tested
The high number of test antibiotics per test
High flexibility in antibiotic selection
Detection of resistance patterns
Mass use and the possibility of automatisation
A number of a different use (AST, identification, screening, etc.)
Detection of heteroresistant population or contamination
Antibiotics 2022, 11, 427 14 of 26

Table 1. Cont.

Method Advantage Disadvantage Comments
Gradient test Convenient and flexible Relatively expensive Quantitative
Relatively
Simple to perform
long incubation
Does not require expertise
Detection of resistance patterns
Automated
Simple to perform Relatively expensive Semi-quantitative ***
systems
Qualitative with no
Chromogenic Not completely
Mass use and the possibility of automatisation interpretation
media susceptible and specific
criteria (S, I, R)
Simple to perform Time-consuming
Limited spectra or
Simple and fast interpretation
single antibiotic
Relatively expensive
Screening only or
required confirmatory
identification
No MIC value
High cost of the
MALDI-TOF MS Rapid turnaround time
MALDI-TOF MS
Need further
optimisation for each
Simple to perform
species and antibiotic
combination
Low sample volume requirements No MIC value
Low per-sample costs
Genetic methods Rapid Limited spectra Qualitative
Highly accurate Limited throughput Semi-quantitative
Sensitive High cost
Reproducible
Increased ability to detect slow-growing or
non-cultivable organisms
Genomic methods Highly accurate High cost Qualitative
Sensitive Time-consuming
Increased ability to detect slow-growing or Challenging
non-cultivable organisms interpretation of results
* Qualitative; results are expressed as susceptible (S), susceptible, increased exposure (I), or resistant (R) based
on established criteria from EUCAST. ** Quantitative; results are expressed as minimal inhibitory concentration
(MIC) for each drug. Susceptibility reports should include interpretation of MIC, such as S, I, or R. *** Semi-
quantitative; results are expressed as MIC using three to four antimicrobial dilutions for each drug. Precise MIC
values cannot be established if the MIC falls below or above the three to four dilutions used in the test panel.
Susceptibility reports include interpretation of breakpoint MIC as S, I, or R. MALDI-TOF MS—matrix-assisted
laser desorption/ionization time-of-flight mass spectrometry.

5. Selection of Antimicrobial Drugs for Susceptibility Testing, Interpretation,