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Antimicrobial Agents and Chemotherapy, October 1999, p. 2497-2503, Vol. 43, No. 10
0066-4804/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Carbapenem Derivatives as Potential Inhibitors of
Various 
-Lactamases, Including Class B
Metallo--Lactamases
Rie
Nagano,*
Yuka
Adachi,
Hideaki
Imamura,
Koji
Yamada,
Terutaka
Hashizume, and
Hajime
Morishima
Banyu Tsukuba Research Institute, 3 Okubo,
Tsukuba 300-2611, Japan
Received 15 March 1999/Returned for modification 30 May
1999/Accepted 4 August 1999
 |
ABSTRACT |
A variety of 1
-methylcarbapenem derivatives were screened to
identify inhibitors of IMP-1 metallo--lactamase, a class B -lactamase, in an automated microassay system using nitrocefin as a
substrate. The structure-inhibitory-activity relationship study
revealed that three types of 1-methylcarbapenems having benzothienylthio, dithiocarbamate, or pyrrolidinylthio moieties at the
C-2 position showed good inhibitory activity. Among the compounds
screened, J-110,441, having a benzothienylthio moiety at the C-2
position of 1-methylcarbapenem, was the most potent inhibitor of
class B metallo--lactamases with Ki values
of 0.0037, 0.23, 1.00, and 0.83 µM for IMP-1 encoded by the
blaIMP gene, CcrA from Bacteroides
fragilis, L1 from Stenotrophomonas maltophilia, and
type II from Bacillus cereus, respectively. In a further
characterization study, J-110,441 also showed inhibitory activity
against TEM-type class A serine -lactamase and chromosomal class C
serine -lactamase from Enterobacter cloacae with
Ki values of 2.54 and 0.037 µM, respectively.
Combining imipenem or ceftazidime with J-110,441 had a synergistic
effect on the antimicrobial activity against -lactamase-producing
bacteria. Against the isolates of IMP-1-producing Serratia
marcescens, the MICs of imipenem decreased to levels ranging from
1/64 to 1/4 in the presence of one-fourth of the MIC of J-110,441.
Against E. cloacae producing high levels of class C
-lactamase, the MIC of ceftazidime decreased from 64 to 4 µg/ml in
the presence of 4 µg of J-110,441 per ml. This is the first report to
describe a new class of inhibitor of class B and class C -lactamases
including transferable IMP-1 metallo--lactamases.
| |
INTRODUCTION |
One of the most important mechanisms
of microbial resistance to -lactam antibiotics is hydrolysis by
-lactamases. Since carbapenems have a broader antimicrobial spectrum
than do other -lactam antibiotics and are not hydrolyzed by many
clinically relevant serine -lactamases, the medical use of
carbapenems would be expected to increase. However, there are several
carbapenem-hydrolyzing -lactamases that preferentially hydrolyze
carbapenems in addition to penicillins and cephalosporins
(28). The class B metallo--lactamases, which have zinc
atoms at the active site, are a group of such carbapenem-hydrolyzing
enzymes (1, 5) and are minimally inhibited by -lactamase
inhibitors such as tazobactam (4, 23, 28). Besides, widely
used serine -lactamase inhibitors behave as substrates of class B
-lactamases (27).
The first metallo--lactamase-producing Pseudomonas
aeruginosa strain was isolated in Japan in 1991 (38),
and the outbreak of carbapenem-resistant organisms such as members of
the family Enterobacteriaceae, especially Serratia
marcescens, and pseudomonads in various districts in Japan was
reported afterwards (2, 15, 31, 32). The mechanism of
resistance was ascribed to the production of IMP-1
metallo--lactamase encoded on the blaIMP gene
(2). The systematic survey of distribution by Senda et al.
indicated the horizontal spread of blaIMP in
Japan (31), and recently, blaIMP-carrying clinical isolates have been
reported in Korea (19) and Europe (8). Thus, the
spread of metallo--lactamase is a serious concern for antimicrobial
chemotherapy with -lactam antibiotics including carbapenems
(20, 28), because the blaIMP gene is
transferable among gram-negative bacteria (2, 31) and an
effective inhibitor has not been developed yet.
In the screening for IMP-1 metallo--lactamase inhibitors, we found a
potent -lactamase inhibitor, J-110,441, having the benzothienylthio
moiety at the C-2 position of the 1-methylcarbapenem nucleus
(21). In this paper, we describe the relationship between the structure and the -lactamase-inhibitory activity of the
carbapenem derivatives tested and discuss the properties of J-110,441
as a potential inhibitor of various -lactamases.
| |
MATERIALS AND METHODS |
Compounds.
All carbapenems screened in this study (see
Tables 1 to 3) were synthesized at the Tsukuba Research Institute,
Banyu Pharmaceutical Co., Ltd., Tsukuba, Japan. Typical compounds shown
in Table 4 were synthesized as described previously (13, 14, 24,
36). Imipenem, cilastatin sodium, and ampicillin were the
products of Banyu Pharmaceutical Co., Ltd., Tokyo, Japan. The following drugs were commercially available: ceftazidime (Tanabe Pharmaceutical Co., Ltd., Osaka, Japan), aztreonam (Eisai Co., Ltd., Tokyo, Japan), cephaloridine and flomoxef (Shionogi Pharmaceutical Co., Osaka, Japan),
and nitrocefin (Oxoid, Basingstoke, England).
Bacterial strains.
Clinical isolates that produce IMP-1
metallo--lactamase were collected from various districts in Japan
starting in 1994, and the blaIMP gene was
detected by the PCR method (32). P. aeruginosa
GN17203, which harbors blaIMP-carrying plasmid
pMS350, and Bacteroides fragilis GAI30079 were generous
gifts from M. Inoue, School of Medicine, Kitasato University, Kanagawa,
Japan, and K. Watanabe, Institute of Anaerobic Bacteriology, School of Medicine, Gifu University, Gifu, Japan, respectively.
Susceptibility test.
MICs were determined by the twofold
serial broth microdilution method with Mueller-Hinton broth (Difco
Laboratories, Detroit, Mich.) for aerobes and GAM broth (Nissui Seiyaku
Co., Ltd., Tokyo, Japan) for B. fragilis. A culture of
aerobes grown at 37°C for 6 h in Mueller-Hinton broth was
diluted to 107 CFU/ml, and a culture of B. fragilis grown at 37°C for 18 h under anaerobic conditions
in GAM broth was diluted to 108 CFU/ml. Each dilution was
inoculated into the drug-containing broth with an inoculum apparatus
(MIC-2000; Dynatech Laboratories, Inc., Chantilly, Va.). The final
inoculum sizes of aerobes and B. fragilis were
105 and 106 CFU/ml, respectively. The MIC was
defined as the lowest antibiotic concentration that completely
prevented visible growth after incubation at 37°C for 20 h.
The combined effect of J-110,441 with imipenem or ceftazidime was
determined by the checkerboard method (29) under the same conditions as those for the MIC determination described above. To
estimate synergism, the fractional inhibitory concentration (FIC) index
was calculated according to the method of Elison et al. (9).
Preparation of -lactamase.
IMP-1 metallo--lactamase
was purified from P. aeruginosa GN17203 harboring the
blaIMP gene. Cells were incubated at 4°C for 1 h in 10 mM 3-(N-morpholino)propanesulfonic acid
(MOPS) buffer (pH 7.0), containing 27% sucrose and 2 mg of lysozyme
(Sigma Chemical Co., St. Louis, Mo.) per ml, and then disrupted by
sonication. The cellular debris was removed by centrifugation
(16,000 × g, 15 min, 4°C), and supernatant was
precipitated by an 80% saturated ammonium sulfate. This fraction was
dialyzed against 10 mM MOPS buffer (pH 7.0) and applied to a
CM-Sephadex C-50 column (Pharmacia Biotech AB, Uppsala, Sweden)
equilibrated with 10 mM MOPS buffer (pH 7.0), and the enzyme was eluted
with a linear NaCl gradient. The active fractions were pooled, dialyzed
against 10 mM MOPS buffer (pH 7.0) containing 1 µM ZnCl2,
and concentrated by ultrafiltration with a UK-10 ultrafilter (Advantec
Toyo Co., Tokyo, Japan). The purity of the preparation was checked by
sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and the
purified enzyme solution was stored at 
80°C.
CcrA metallo-
-lactamase was prepared from
B. fragilis
GAI30079. Cells were suspended in 50 mM sodium phosphate buffer (pH
7.0) and disrupted by sonication. The cellular debris was removed
by
centrifugation (13,500 ×
g, 15 min, 4°C), and the
supernatant
was dialyzed against 50 mM sodium phosphate buffer (pH
7.8). This
fraction was applied to a DEAE-Toyopearl 650M column (Toso
Co.,
Tokyo, Japan) equilibrated with 50 mM sodium phosphate buffer
(pH
7.8), and the enzyme was eluted with a linear NaCl gradient.
The pooled
active fractions were dialyzed against 50 mM sodium
phosphate buffer
(pH 7.0), concentrated by ultrafiltration with
a UK-10 ultrafilter, and
rechromatographed with a Sephadex G-100
column (Pharmacia Biotech AB)
equilibrated with 50 mM sodium phosphate
buffer (pH 7.0). The
concentrated crude enzyme preparation was
dialyzed against 50 mM sodium
phosphate buffer (pH 7.0) and stored
at
80°C.
L1 metallo-
-lactamase was prepared from
Stenotrophomonas
maltophilia GN12873 as described previously (
30).
Type II metallo-
-lactamase from
Bacillus cereus, TEM-1
penicillinase from
Escherichia coli, and cephalosporinase
from
Enterobacter cloacae were obtained from Sigma Chemical
Co. TEM-1 penicillinase
and
E. cloacae cephalosporinase
correspond to group 2b and group
1 of Bush's classification
(
3),
respectively.
Determination of -lactamase activity.
The activity of the
metallo--lactamase preparation was determined at each step by
monitoring the hydrolysis of 100 µM imipenem (
= 9.04 mM
1 · cm1 at 299 nm) at 30°C in 10 mM MOPS buffer (pH 7.0) containing 100 µM ZnCl2. One unit
of -lactamase activity was defined as the amount of enzyme that
hydrolyzed 1 µmol of imipenem per min at 30°C.
Determination of IC50.
The 50% inhibitory
concentration (IC50) for IMP-1 metallo--lactamase was
determined by measuring the enzymatic hydrolysis of a chromogenic
cephalosporin, nitrocefin, in the presence of inhibitors. This
automated assay system was a modification of a previously reported
method (26). To avoid identifying metal chelators, 10 mM
MOPS buffer (pH 7.0) containing 100 µM ZnCl2 was used in
this microassay. Inhibitors were dissolved in 10 mM MOPS buffer (pH
7.0) or dimethyl sulfoxide at final concentrations of 0.1, 1.0, and 10 µM. After 1 µl of each inhibitor and 25 µl of IMP-1
metallo--lactamase (3 to 6 mU/ml) were mixed in a 98-well microplate, the assay was initiated within 1 min by the rapid addition
of 75 µl of nitrocefin to create a final concentration of 72.7 µM.
The reaction mixtures in the absence of inhibitor, enzyme, or both were
prepared as the controls. Assay plates were incubated with slow shaking
in an M-36 microincubator (Taitec Co., Tokyo, Japan) at 30°C, and the
hydrolysis of nitrocefin was measured after incubation for 15 min by
detecting the increase of absorbance at 492 nm in an MTP-120 plate
reader (Corona Electric Co., Ibaraki, Japan). Under these conditions,
substrate consumption in control experiments was <10% of initial
concentration. The mean initial rates of hydrolysis at each inhibitor
concentration were calculated from the triplicate measurements for each
inhibitor concentration. The IC50s (micromolar
concentrations) were determined by plotting percentages of inhibition
against inhibitor concentrations.
-Lactamase assays.
Kinetic studies were performed at
30°C in 10 mM MOPS buffer (pH 7.0), and the hydrolysis of the
substrate was monitored in a UV-2200 temperature-controlled
spectrophotometer (Shimadzu, Tokyo, Japan). The initial velocity of
test compounds at a 100 µM concentration was determined, and
velocities relative to those of imipenem and cephaloridine for metallo-
and serine -lactamases, respectively, were calculated. The molar
extinction coefficient was as follows: cephaloridine, = 10.2 mM1 · cm1 at 260 nm; J-110,441,
= 18.4 mM1 · cm1 at 306 nm;
compound 3a, = 6.37 mM1 · cm1
at 300 nm; and compound 7a, = 10.5 mM1 · cm1 at 300 nm. Kinetic parameters were derived from at
least two independent experiments by Hanes-Woolf plots of the initial
velocity of substrate hydrolysis. To calculate the
Ki values by Dixon plotting, rates of substrate
hydrolysis at concentrations ranging from 10 to 100 µM were
determined in the presence of various concentrations of inhibitors.
Imipenem and cephaloridine were used for metallo- and serine
-lactamases, respectively. The assay was initiated by the addition
of enzyme to the mixture of substrate and inhibitor. The total reaction
volume was 1.0 ml in all cases.
| |
RESULTS |
Structure-inhibitory-activity relationship.
Several
compounds have been identified as IMP-1 metallo--lactamase
inhibitors in an automated microassay system using nitrocefin as a
substrate. In this assay, IC50s of marketed -lactam
antibiotics such as panipenem, ampicillin, ceftazidime, cephaloridine,
and aztreonam were over 100 µM. Meropenem and flomoxef showed weak inhibitory activity with IC50s of 25 and 60 µM,
respectively. The IC50s of metal chelators such as
dipicolinic acid (39) and EDTA were within the range of 80 to 200 µM. Cilastatin sodium, an inhibitor of renal membrane
dipeptidase (dehydropeptidase I) (16) and a weak inhibitor
of CphA metallo--lactamase from Aeromonas acidophila
(17), did not show inhibitory activity against IMP-1 metallo--lactamase at the concentration of 10 µM.
The structure-inhibitory-activity relationship of J-110,441 having
benzothienylthio moiety as a side chain and related analogs
is
summarized in Table
1. The most
remarkable finding in this
study was that the introduction of a
2-substituted benzothiophene
at the C-2 position of
1
-methylcarbapenem, which resulted in
J-110,441, led to strong
inhibitory activity with an IC
50 of <0.1
µM. Replacement
of the 2-substituted benzothiophene with a 3-substituted
benzothiophene
(compound 1a), a benzothiazole (compound 2a), or
a benzimidazole
(compound 2b) resulted in decreased inhibitory
activity. Introduction
of the methyl ester to the carboxylic acid
of the carbapenem nucleus
(compound 1b) or insertion of a pyrrolidine
ring as a spacer between
the carbapenem nucleus and the benzothienylthio
moiety (compound 1c)
produced a marked reduction in inhibitory
activity.
Dithiocarbamate carbapenems showed relatively good inhibitory activity;
the IC
50s of the compounds tested ranged from <0.1
to 1.8 µM, as shown in Table
2. Among the
dithiocarbamate compounds
tested, those of the
1,2,5,6-tetrahydropyridin-1-ylthiocarbonylthio
series (compounds 3a to
3e) had better inhibitory activity than
did the others (compounds 3f
and 3g). The introduction of a cationic
side chain (compare compounds
3a to 3d with compound 3e) produced
an increase in inhibitory activity,
especially in the case of
dicationic 1,4-diazabicyclo[2,2,2]octane
(DABCO) having a carbamoylmethyl
or hydroxyethyl substituent in the
side chain (compounds 3a and
3b), which had an IC
50 below
0.1 µM. The carbamoylmethyl- or hydroxyethyl-substituted
DABCO itself
did not inhibit IMP-1 metallo-
-lactamase at the
concentration of 10 µM.
The structure-inhibitory-activity relationship of pyrrolidinylthio
carbapenem derivatives is shown in Table
3. The introduction
of an aminomethyl
group to the benzene ring (compare compounds
4a and 4b with 4c) and
alkylation of the nitrogen of pyrrolidine
with hydroxyethyl (compare
compound 6a with 6b) brought about
stronger inhibitory activity. An
additional aminomethyl (compare
compound 4a with 4b) increased
inhibitory activity. A decrease
in inhibitory activity was caused by
(i) replacement of the aminomethyl
group attached to the benzene ring
with hydroxymethyl (compare
compound 6b with 6d), (ii) substitution on
the benzylic methylene
position (compare compound 6b with 6c), (iii)
introduction of
a methyl group on the pyrrolidine ring (compare
compound 5a with
5b), and (iv) use of cyclohexane instead of the
benzene ring (compare
compound 6b with 6e). The thiol side chain of
compound 5a did
not inhibit the enzyme at the concentration of 10 µM,
although
the IC
50 of compound 5a was 0.7 µM
(
21). The important observation
was that direct attachment
of a benzene ring to pyrrolidine was
necessary for inhibitory activity
because the introduction of
spacers between pyrrolidine and the benzene
ring (compound 6f)
or cleavage of the pyrrolidine ring (compound 6g)
caused a decrease
in inhibitory activity.
With respect to the stereochemistry of the pyrrolidine ring of compound
5a, the
Ki values of the compounds with
trans (compound
5a) and
cis configurations were
0.18 and 0.12 µM, respectively.
The results suggested that the C-5
stereochemistry of the pyrrolidine
ring was not a crucial factor for
the inhibitory potential for
IMP-1 enzyme, while the inhibitory
activity was markedly reduced
by inversion of the C-3 chiral center of
the pyrrolidine ring
(IC
50, >10 µM) regardless of C-5
stereochemistry.
It was noteworthy that replacement of the benzene ring with thiophene
(compare compound 7a with 4b) showed increased inhibitory
activity.
Alkylation of the amino group did not affect the inhibitory
activity
(compound 7b); however, a 3-thienyl analog (compound
7c) was over 10 times less potent than the 2-thienyl compound
(compound
7b).
Among the pyrrolidinylthio carbapenems tested, compound 7a was more
stable under the hydrolysis by and more potent against
various
metallo-
-lactamases than was compound 4a or
6a.
Inhibitory activity against various -lactamases.
Some
compounds with an IC50 below 0.1 µM were selected and
were characterized by studying their affinity for class B
metallo--lactamases and class A and class C serine -lactamases
and their stability under hydrolysis by these enzymes (Table
4).
Among all the compounds tested, J-110,441, having a benzothienylthio
moiety at the C-2 position of 1
-methylcarbapenem, was
found to be
the most stable under hydrolysis by all of the metallo-
and serine
-lactamases tested in terms of relative hydrolysis
rate, which
ranged from <1 to 8% for IMP-1, CcrA, L1, and
B. cereus type II metallo-
-lactamases and group 2b and group 1 serine
-lactamases.
In particular, it is noted that J-110,441 exhibited
better inhibitory
activity than did the other inhibitors against
metallo-
-lactamases,
since the
Ki values were
0.0037, 0.23, 1.00, and 0.83 µM for IMP-1
encoded on the transferable
blaIMP gene, CcrA from
B. fragilis,
L1 from
S. maltophilia, and type II from
B. cereus, respectively.
J-110,441 inhibited IMP-1 in a competitive
manner (Fig.
1) and
also showed
inhibitory activity against class A and class C serine
-lactamases
with
Ki values of 2.54 and 0.037 µM,
respectively.
The inhibition by J-110,441 was reversible. Thus,
J-110,441 was
suggested to have potential as a new class of
-lactamase inhibitor
with a broad spectrum.
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|
FIG. 1.
Dixon plot consistent with competitive inhibition of
IMP-1 by J-110,441. Imipenem was used as the substrate at the indicated
concentration (conc.).
|
|
As shown in Table
4, compounds 3a and 7a also showed appreciable
relative stability under hydrolysis by IMP-1 metallo-
-lactamase,
which was similar to that of J-110,441, and the inhibitory activity
against these enzymes was observed as
Ki values
of 0.09 and 0.01
µM, respectively. However, the compounds were more
susceptible
to hydrolysis by the CcrA and L1 enzymes than to that by
the IMP-1
enzyme. Against class A and class C serine
-lactamases,
the inhibitory
activity of these compounds was inferior to that of
J-110,441.
Combined effect on antimicrobial activity.
Table
5 presents the antimicrobial activities
of J-110,441, imipenem, ceftazidime, and their combination against
-lactamase producers. The organisms that produce class B enzymes
showed resistance to imipenem and ceftazidime, while E. cloacae, which is a derepressed producer of class C enzyme,
remained susceptible to imipenem but showed high resistance to
ceftazidime. The activity of imipenem or ceftazidime was potentiated in
the presence of J-110,441. Especially against clinical isolates of
S. marcescens producing IMP-1, the MICs of imipenem, ranging
from 64 to 256 µg/ml, decreased to levels ranging from 4 to 64 µg/ml in the presence of one-fourth of the MIC of J-110,441. Against
class C -lactamase-producing E. cloacae, the MIC of
ceftazidime decreased from 64 to 4 µg/ml in the presence of 4 µg of
J-110,441 per ml. Synergy (FIC index, 
0.5) of imipenem or ceftazidime
with J-110,441 was observed against 9 of 11 strains tested that were
resistant mainly due to the production of class B and/or class C
-lactamases. However, the results indicated that some strains are
still clinically resistant to imipenem even in combination with
J-110,441.
| |
DISCUSSION |
The results described above show that a series of
1-methylcarbapenems exhibited a variety of potencies against IMP-1
metallo--lactamase. The carbapenem nucleus probably played an
important role in the affinity for IMP-1 enzyme, as suggested
previously for B. fragilis metallo--lactamase
(7). Introduction of a thiophene or DABCO moiety to the side
chain brought about stronger inhibitory activity. Conversely,
introduction of a spacer between the carbapenem nucleus and the side
chain or into the side chain caused a marked decrease of inhibitory
activity. In the case of 3,5-disubstituted
pyrrolidinylthio-1-methylcarbapenem, C-5 stereochemistry of the
pyrrolidine ring was not a crucial factor for the inhibitory potential
against IMP-1 enzyme, though it affected the antibacterial activity
(33).
The most remarkable result was that J-110,441 was found to be an
inhibitor of various -lactamases, especially against transferable IMP-1 metallo--lactamase and class C serine -lactamase with Ki values of 0.0037 and 0.037 µM,
respectively. J-110,441 showed strong inhibitory activity against IMP-1
enzyme, but the activity decreased against other metalloenzymes; in
particular, it was over 100-fold less active against the L1 and type II
enzymes. These results may be ascribed to the diversity in
metallo--lactamases (28).
A synergistic effect was observed between J-110,441 and imipenem or
ceftazidime in the bacterial susceptibility study using clinical
isolates of -lactamase producers. Against class C serine -lactamase-producing E. cloacae, the antimicrobial
activity of ceftazidime was potentiated in the presence of J-110,441,
although the possibility of compensatory inhibition of penicillin
binding proteins by cephem and carbapenem antibiotics should not be
excluded. The combined effects of imipenem and J-110,441 showed much
variation among the blaIMP gene-carrying
organisms tested. It might be explained by varied mechanisms of
resistance in clinical isolates such as production of different enzymes
including IMP-1 and chromosomal AmpC enzyme, low outer membrane
permeability (porin deficiency), or efflux (22).
It has been reported elsewhere that the commercially available
-lactamase inhibitors are clinically ineffective against IMP-1 metallo--lactamase and many class C serine -lactamases (3, 23). Also, the inhibitory activity of synthetic
metallo--lactamase inhibitors is reportedly insufficient for
development for clinical use (12, 17, 25, 34, 37). Needless
to say, the spread of metallo--lactamase is a future threat to
antimicrobial chemotherapy with -lactams including carbapenems
(28, 31, 38). The X-ray crystallography studies have
revealed three-dimensional structures of B. cereus type II
(6, 10), CcrA (7, 11), and L1 (35) to
have two zinc atoms at the active sites of these enzymes, and the
models were based on not only native enzyme crystal structures but
those with substrate (7, 10, 35) or inhibitor
(34) at the active site. Recently, two zinc atoms in IMP-1
enzyme were determined enzymatically (18). Because
crystallographic information is still limited, further study is
necessary for the computer modeling for designing effective inhibitors.
Our present data yielded various pieces of information on the
structure-inhibitory-activity relationship and could assist in the
development of specific inhibitors of bacterial -lactamases and/or
an antibiotic stable against various -lactamases.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Banyu Tsukuba
Research Institute, 3 Okubo, Tsukuba 300-2611, Japan. Phone:
81-298-77-2000. Fax: 81-298-77-2029. E-mail:
naganori{at}banyu.co.jp.
| |
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Abstract
Introduction
