Molecular imaging of matrix metalloproteinases in atherosclerotic plaques
Review Article Schattauer 2012 Molecular imaging of matrix metalloproteinases in atherosclerotic plaques Sébastien Lenglet1; Aurélien Thomas2; Pierre Chaurand2; Katia Galan1; François Mach1; Fabrizio Montecucco1 1Cardiology Division, Foundation for Medical Research, Department of Medical Specialties, University of Geneva, Geneva, Switzerland; 2Department of Chemistry, Montréal University, Montréal, Québec, Canada
MMP might be of pivotal relevance in the evaluation of the risk of rup-
Ischaemic stroke and myocardial infarction often result from the ture. New imaging approaches, focused on the visualisation of inflam-sudden rupture of an atherosclerotic plaque. The subsequent arterial mation in the vessel wall and plaque, may emerge as tools for individ-thrombosis occluding the vessel lumen has been widely indicated as ualised risk assessment and prevention of events. In this review, we the crucial acute event causing peripheral tissue ischaemia. A complex
summarize experimental findings of the currently available invasive
cross-talk between systemic and intraplaque inflammatory mediators and noninvasive imaging techniques, used to detect the presence and has been shown to regulate maturation, remodeling and final rupture
activity of MMPs in atherosclerotic plaques.
of an atherosclerotic plaque. Matrix metalloproteinases (MMPs) are proteolytic enzymes (released by several cell subsets within athero-
Keywords
sclerotic plaques), which favour atherogenesis and increase plaque vul-
Matrix metalloproteinase, atherosclerosis, inflammation
nerability. Thus, the assessment of intraplaque levels and activity of
Correspondence to: Financial support:
This research was funded by EU FP7, Grant number 201668, AtheroRemo to Dr. F.
Mach. This work was also supported by the Swiss National Science Foundation Grants
Faculty of Medicine, University of Geneva
to Dr. F. Mach (#310030–118245) and Dr. Montecucco (#32002B-134963/1). This
Avenue de la Roseraie 64, 1211 Geneva 4, Switzerland
work was also funded by a grant from the Swiss Heart Foundation and Novartis Foun-
Tel.: +41 22 372 71 92, Fax: +41 22 382 72 45
dation to Dr. F. Mach. This work was funded by the “Sir Jules Thorn Trust Reg” fund
and Gustave and Simone Prévot fund to Dr. F. Montecucco. Received: October 18, 2011 Accepted after minor revision: December 9, 2011 Prepublished online: January 25, 2012
doi:10.1160/TH11-10-0717 Thromb Haemost 2012; 107: 409–416 Introduction: Inflammation in atherosclerotic able plaques can suddenly rupture this cap and expel their throm- plaques
bogenic content into the blood stream. The subsequent acute formation of a thrombus/embolus occluding the arterial lumen
The main pathologic feature of atherosclerosis is the athero-
and provoking tissue ischaemia represents the most dangerous pa-
sclerotic plaque (also called “atheroma”), which is characterised by
thophysiological event for terminal organs. The morphological
the inflammatory response of the vessel wall to the initial endothe-
traits typically associated with rupture-prone plaques include a
lial dysfunction. Atherosclerotic factors (such as hypercholestero-
large eccentric necrotic core and a thin fibrous cap heavily infil-
laemia or hypertension) might trigger the initial endothelial injury
trated with macrophages and inflammatory cells, spotty calcifi-
that, if not neutralised, favours the establishment of a chronic in-
cation and vasa vorum proliferation (2). The plaque rupture
flammation in the vessel wall. During this phase, both inflamma-
mainly occurs in their shoulder, where active macrophages ac-
tory and vascular cells are recruited and activated within the in-
cumulate to phagocytate apoptotic cells and release proteolytic
flamed arterial sub-intimal space. In particular, they attempt to enzymes (such as matrix metalloproteinases [MMPs]). However, phagocytate the oxidised lipids or apoptotic bodies. To improve atherosclerotic plaques have been described as very heterogeneous this response, these cells also release several soluble mediators, tissues, characterised by different vulnerabilities depending on which attract other inflammatory cells from the blood stream and portions upstream or downstream the blood flow (3). Therefore, increase intraplaque injury. The atherosclerotic lesion can progress
the selective assessment of MMP release and activity within the
to more advanced lesions composed of activated macrophages, T different plaque regions might be a very promising approach to lymphocytes, foam cells and mast cells around a necrotic lipid-rich better evaluate cardiovascular vulnerability (4). core (1), separated from the blood stream by a fibrous cap. Vulner-
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For personal or educational use only. No other uses without permission. All rights reserved. Lenglet et al. Imaging of matrix metalloproteases Enzyme Substrates Author (year) [ref.] Table 1: MMP substrates and localisation in atherosclerotic plaques.
Collagen I, II, III, IV, V, VII, X and XI, Neutrophils, macrophages,
fibronectin, laminin, MMP-7,-8,-11 phages, T-lymphocytes
Fu (2001) [20] Halpert (1996) [20] Newby (2007) [12]
muscle cells, endothelial cells, Johnson (2005) [18] T-lymphocytes
Newby (2007) [12] Schönbeck (1999) [24]
Busti (2010) [15] Newby (2007) [12] Ray (2004) [28] Schneider (2008) [29]
Role of MMPs in atherosclerotic plaque
control system of their protein degrading function. Firstly, MMP
vulnerability
expression might be regulated at the level of the gene transcription and translation. The second control level is represented by the ac-
MMPs are a family of endopeptidases consisting of more than 28 tivation of the pro-MMP by the proteolytic cleavage. Finally, MMP structurally related members that share a Zn2+-based or Ca2+ cata-
might be also blocked after their activation via the interaction with
lytic sites (5). The majority of MMPs is synthesised and secreted as
specific inhibitors (called tissue inhibitors of MMPs [TIMPs]) (8).
inactive pro-enzymes (pro-MMPs) or zymogens. In general, the The misregulation of this complex system is a common patho-activation of these enzymes occurs via the proteolytic cleavage of physiological process of several diseases, such as rheumatoid ar-the pro-peptide domain by other MMPs (6). Considering their thritis, periodontal disease, multiple sclerosis, cancer and athero-structure and specific substrates (major extracellular matrix sclerosis (5). In a normal artery, pro-MMP2, TIMP-1 and TIMP-2 [ECM] components), MMPs have been also classified into differ-
are well detectable and appropriately balanced. Within human
ent groups (including collagenases, gelatinases, stromelysins, atherosclerotic plaques, MMP control systems might be pathologi-membrane-type MMPs [MT-MMPs], and others) (5, 7). The bio-
cally down regulated (9). In particular, TIMP-1 intraplaque ex-
logical relevance of activated MMPs is modulated by an articulated pression has been shown as reduced in symptomatic plaque speci-
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For personal or educational use only. No other uses without permission. All rights reserved. Lenglet et al. Imaging of matrix metalloproteases Table 2: Characteristics of the foremost Technique Advantage Disadvantage Reference molecular imaging techniques used for the identification of MMPs in atherosclerotic plaques.
ground ratio) Limited spatial resolution Restricted to animal studies and ex vivo human artery plaques
* SPECT: single photon emission computed tomography. † PET: positron emission tomography. ‡ HR-MRI: high-resolution magnetic resonance imaging. § NIRF: near-infrared fluorescence.
mens (9). Conversely, TIMP-1 serum levels were not altered in vul-
Single photon emission computed tomography
nerable patients with acute myocardial infarction (10) or is-chaemic stroke (11), when compared with asymptomatic controls.
Radiographic scintigraphic technique, such as single photon
These studies indicate that the intraplaque (instead of systemic) emission computed tomography (SPECT), is designed to image regulation of MMP inhibitory mediators is substantially associ-
systemic disorders such as atherosclerosis. It offers the opportunity
ated with plaque vulnerability and its potential acute rupture. The to specifically identify the various components of inflammation in final result is a dramatic increase of the intraplaque activity of cer-
atherosclerotic plaques (for instance macrophage infiltration,
tain MMPs, such as interstitial collagenases (MMP-1, -8 and -13) apoptosis or foam cell generation) (31). The first studies were con-and gelatinases (MMP-2 and -12). In vulnerable plaques, pro-in-
ducted on New Zealand white rabbits, in which atherosclerosis
flammatory soluble mediators have been shown to sustain MMP lesions were induced by balloon de-endothelisation of the ab-expression and release. These processes are crucial mechanisms dominal aorta followed by a high-fat and high-cholesterol diet (32, driving plaque progression and destabilisation, till its final rupture 33). After intravenous administration, the matrix metalloprotei-(12). The source of MMPs within atherosclerotic plaques is also a nase inhibitor (MPI) uptake in atherosclerosis lesions was clearly matter of debate. Foam cells, macrophages, vascular smooth visualised by micro SPECT imaging. The results were confirmed by muscle cells (VSMC) and endothelial cells (EC) can release numer-
immunohistochemical characterisation and zymography, reveal-
ous MMPs that are capable of digesting ECM proteins (13). More ing that the radiotracer uptake correlated with macrophage infil-recently, neutrophilic MMPs have been also detected within tration as well as with the expression and activity of MMP-2 and atherosclerotic plaque, suggesting that several vascular and inflam-
–9. Furthermore, the MPI uptake was lowered in animals after die-
matory cells might modulate MMP-related plaque vulnerability tary modification and statin treatment, thus confirming previous (14). The functions and the cellular sources of MMPs involved in observations that these treatments substantially decrease the MMP atherogenesis are summarised in ǠTable 1.
activity in atherosclerotic lesions. These first studies patently dem-
The molecular imaging modalities for MMP activity would onstrate that in vivo quantification is feasible by non-invasive tar-
ideally provide the plaque phenotype, thus helping researchers to geted imaging. MMP activity has been also studied in rodents with further clarify the inflammatory pathophysiology of the vulner-
99mtechnetium-labelled broad MMP inhibitors (MPI).
Oshima et al. conducted the same type of experiments in two
transgenic mouse models, namely ApoE-/- and LDLR-/- mice (34). These animals exhibit spontaneous hyperlipidaemia and the de-velopment of extensive atherosclerosis in the aorta and large ar-
Imaging of MMPs in atherosclerotic plaques
teries (35, 36). In these animals, the MPI radiotracer uptake was highest in the most advanced lesions and strongly correlated with
In this part, we provide an overview of the currently available im-
the extent of plaque infiltration and quantitative expression of
aging techniques used to detect MMPs in atherosclerotic plaques. MMP-2 and -9. So, MPI imaging could be used to detect high-risk, Each technique described below possesses its own strengths and unstable lesions since the plaque morphology in these mice is simi-drawbacks, which are summarised in ǠTable 2. On the other lar to that of human atherosclerosis (35–38). hand, ǠTable 3 summarises the results of the available imaging
Kuge et al. suggested that the membrane MMP (MT1-MMP or
techniques targeting MMPs to assess atherosclerotic plaque in-
MMP-14) have a role in the destabilisation of atherosclerotic
flammation and associated vulnerability.
plaques (39). Expression of MT1-MMP has also been found with-
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For personal or educational use only. No other uses without permission. All rights reserved. 412 Lenglet et al. Imaging of matrix metalloproteases Table 3: Summary of MMP molecular imaging techniques in atherosclerotic plaques. Technique Author Molecular Agent/Probe Study subjects Results
Reduced uptake in the diet withdrawal and statin groups
Immunohistochemical correlation between MPI uptake and the macrophage infiltration and MMP-2 and MMP-9 expression
Imaging of MMP activity in atherosclerotic plaques in vivo
Reduced uptake after statin treatment and diet withdra-
Higher MPI uptake in atherosclerotic lesions of mice (both
genotypes) fed with a high-cholesterol diet in comparison with mice fed with a normal chow Significant correlation between MPI and MMP-2 and MMP-9
Watanabe heritable Accumulation of MT1-MMP in Watanabe rabbit aortas is
hyperlipidaemic rab- 5.4-fold higher than that of control rabbits bits
Histological grade of lesions (atheromatous > fibroatheromatous > collagen-rich > neomintimal)
In vivo heterogenous uptake of tracer along the aorta
Significant reduction in RP782 uptake after the diet with-drawal
MMP-2 and MMP-9 activity are detected in vivo and ex
Human symptomatic Ex vivo topographic distribution of MMPs in an athero-
In vivo signal of MMPs activity increases in carotid
plaques in the HCD group Pioglitazone reduces MMPs target-to-background ratio versus HCD
Detection of MMP activity in complicated areas with
ulceration and haemorrhage in comparison with non-complicated areas Weak correlation between the protease activity and the stenosis degree
Human symptomatic High resolution mapping of MMP activity in ex vivo
vulnerable plaque of intact human carotid specimens
Attenuation of MMP-related NIRF signal intensities in
aortas (ex vivo) from mice exercising versus sedentary mice
Good affinity of P947 to human MMP-rich carotid plaques
In vivo detection of atherosclerotic plaques in ApoE-/-
Watanabe heritable Accumulation of P947 in atherosclerotic plaques from hyperlipidaemic rab- rabbit aortas, correlation with the immunohischemical bits
In vivo signal enhancement in the aortic walls
Correlation with MM2, MMP3 and MMP-9 stainings
Ex vivo detection of the specific footprint associated
with MMP-2 and -9 in atherosclerotic plaque cap
* SPECT: single photon emission computed tomography.† MMPs: matrix metalloproteases. ‡ MPI: matrix metalloproteinase inhibitor. § NIRF: near- infrared fluorescence. || MRI: magnetic resonance imaging. # TR-LIFS: time-resolved laser-induced fluorescence spectroscopy.
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For personal or educational use only. No other uses without permission. All rights reserved. Lenglet et al. Imaging of matrix metalloproteases
in human atherosclerotic plaques (40), suggesting that its detec-
To image MMP activity, Deguchi et al. have used a gelatinase
tion may be useful for the assessment of atherosclerotic plaque vul-
probe conjugated with NIRF fluorochromes (48). MMP-2 and –9
nerability. Therefore, Kuge et al. recently designed a 99mTc-labelled recognise and cleave this protease-activable agent and augment the anti-MT1-MMP monoclonal IgG as a radio-probe for imaging probe’s fluorescence in vitro by 200-fold (49). In this study, ApoE-/- atherosclerosis (41). In a rabbit model of atherosclerosis, they mice fed with a high-cholesterol diet received the gelatinase NIRF showed a significantly higher 99mTc-MT1-MMP mAb accumu-
agent. After 24 hours, fluorescence molecular tomography reveal-
lation in atherosclerotic rabbit aortas as compared to controls. ed increased NIRF signals in the aortic root and arch, known sites Moreover, the radiotracer mainly accumulates in atheromatous of atherosclerosis in ApoE-/- mice. Sites of increased gelatinase ac-lesions (type IV according to the classification scheme of the tivity visualised by NIRF co-localised with macrophage accumu-American Heart Association; [42, 43]). This lesion type (consider-
lation, immunoreactive MMP-2 and –9 and gelatinolytic activity
ed to be very similar to human vulnerable plaques) is characterised detected by in situ zymography. Thus, these results validate the use by fibrous connective tissue and a dense accumulation of extracel-
of this gelatinase probe to monitor MMP activity in vivo.
lular lipid and foam cells (44). The study shows that nuclear im-
The first application of NIRF in human carotid artery plaques
aging of MT1-MMP could provide a new diagnostic tool for better was reported by Wallis de Vries et al. (50). They incubated athero-identifying vulnerable atherosclerotic plaques.
sclerotic plaques from endarterectomy with a new activable NIRF
Recently, Razavian et al. used micro-SPECT and 111In-RP782, a agent, the MMPsense 680, and analysed the topographic distribu-
radiotracer that specifically targets the MMP activation epitope, to
tion of MMPs by applying multispectral NIRF imaging. Within the
evaluate anatomic localisation of MMPs in aortas of ApoE-/- mice specimen, the NIRF signals resulted in the identification of cold under high-fat diet (45). The authors also showed a heterogeneous spots (with low NIRF intensity) and hot spots (with high NIRF in-distribution of RP782 uptake along the aorta and this pattern was tensity). In situ zymography and quantitative PCR from excised confirmed by ex vivo autoradiography. Interestingly, RP782 uptake hot and cold spots demonstrated that the gelatinase most abun-heterogeneity along the aorta was more pronounced in athero-
dantly present and enzymatically active is therefore most likely
sclerotic plaques over time progression and the withdrawal of the MMP-9. Thus, this study attests the possibility to detect differential high-fat diet induced a significant reduction in aortic MMP acti-
topographic NIRF signals within an excised atherosclerotic
vation detected by RP782 imaging. Although the relevance of these
plaque. In addition, the possibility of identifying the more vulner-
observations in human beings remains to be determined, these re-
able plaques (to improve the selection criteria for surgical inter-
sults highlight the importance of the in vivo assessment of MMP ventions) was also demonstrated. activity that can be achieved by molecular imaging.
The MMP activity in a bigger cohort of patients undergoing ca-
Although the nuclear imaging technique SPECT is a leading rotid endarterectomy or carotid stenting (captured emboli) has
modality for the detection of MMP, radiation exposure with the been analysed with a fluoregenic cleavable decapeptide (51). Be-radiotracers cited above will limit its widespread use for the moni-
sides the detection of MMP activity within or around complicated
toring of patients with atherosclerotic risk factors. Further clinical areas (ulceration and haemorrhage) of the carotid atheroma, this studies are needed to demonstrate the diagnostic accuracy of this study demonstrates that the degree of carotid stenosis was weakly technique and also investigate the risk-benefit ratio.
positively correlated with the inflammatory proteolytic enzyme-related signal unlike histological imaging. In other words, some in-formative divergence between anatomic and molecular imaging might exist. Thus, this NIRF probe is likely yielding information
Near-infrared fluorescence
more applicable to the pathophysiology of a plaque rupture than conventional imaging (such as immunochemistry, which does not
Another new and promising tool to image proteolytic activity in always distinguish active proteases from inactive precursors). atherosclerotic plaques is the near-infrared fluorescence (NIRF) mo-
Until now, the planar fluorescence methods used can only pro-
lecular imaging. This technique operates in the near-infrared spec-
vide a qualitative indication of the existence of MMP activity
trum of light and uses biocompatible probes that provide fluorescent
rather than an accurate assessment of it specific localisation and
images to detect enzymatic action of MMPs. In its unprocessed distribution. To improve this characteristic, Razansky et al. have form, the probe is designed so that signals from the closely posi-
used the multispectral optoacoustic tomography (MSOT) to pro-
tioned fluorochromes are quenched. Once the probe is cleaved by the
vide volumetric images of MMPsense 680 probe distribution ex
active MMP, the released fluorochrome emits light in the near-in-
vivo within intact human plaques (52). This technology coupled
frared range when excited. Since one enzyme can cleave multiple with tomographic reconstruction and spectral processing allows probes, this approach results in an amplified fluorescence.
indeed three-dimensional imaging of biomarkers in small animals
Considering that the inhibitors used in SPECT bind the MMP (53). MMPsense 680 was applied to human carotid plaques from
enzyme in a 1:1 fashion and thereby provide no signal amplifi-
symptomatic patients and MSOT method had simultaneously
cation, the NIRF probe offers a relevant improvement.
provided maps of both activated and inactive probe distribution in
Another advantage of this modality is the possibility of NIRF these tissues. The MSOT signals were correlated with the inflam-
signals to penetrate tissue up to several centimeters, thus enabling matory activities, the macrophage influx and the MMP activity by in vivo imaging (46, 47).
epifluorescence imaging of cryosections, zymography and immu-
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For personal or educational use only. No other uses without permission. All rights reserved. 414 Lenglet et al. Imaging of matrix metalloproteases
nohistochemistry experiments. On the basis of these results and caps of human carotid plaques using TR-LIFS derived spectro-the successful use of MSOT for whole-body imaging of living mice scopic variables in wavelength bands (59). Importantly, these (54), molecular and morphological characterisation of plaques by amounts of MMPs correlated with the changes in collagen, elastin MSOT with NIRF probes could be a promising method to non-in-
and lipid content in plaques. This approach is very attractive be-
cause TR-LIFS allows the assessment of MMPs content in human plaques without labelling or destroying the measured tissues. Moreover, TR-LIFS interrogation of arteries can be conducted via fiberoptic catheters, which are now in an advanced stage of devel-
Magnetic resonance imaging
opment for the in vivo intravascular use in conjunction with in-travascular ultrasound catheters (61). On the other hand, the main
Magnetic resonance imaging (MRI) can provide information on limitation of this study is that only the MMP expression was as-both plaque volume and composition in multiple arterial territori-
sessed, and not the activity which is primordial for a potential
es (55). It has been shown that MRI of the carotid artery can differ-
entiate several plaque components including fibrous cap, lipid-
To complete this review on imaging techniques of MMP, we
rich/necrotic core, intraplaque hemorrhage and calcification (56).
want to include the imaging mass spectrometry (IMS), which is an
The correlation between clinical symptoms and features of vulner-
emergent and innovative tool for direct analysis of tissue section
able plaque raises the possibility that MRI of the carotid arteries (62, 63). In addition to the MS capacities for monitoring and iden-may have a potential role in the management of symptomatic caro-
tifying biomolecules, IMS will lead to information on the spatial
tid artery disease. Recently, the development of targeted molecular localisation of the target proteins in tissue or individual cells (64). contrast agents has permitted to identify the molecular consti-
Furthermore, it might be possible to map at the same time the evol-
tuents of individual plaques. Among them, the novel MRI contrast ution of the expression profiles of thousands of potential biom-agent P947 (an MMP inhibitor coupled to a gadolinium chelate) arkers in an unbiased and specific way (65, 66). IMS might be per-binds with an affinity at a micromolar range human soluble formed in the same tissue used for other examination procedures, MMP-1,-2,-3,-8,-9 and -13. In human carotid arteries, the ex vivo thus potentially providing unprecedented molecular information P947 concentration is significantly higher in the MMP-rich than in
and enhancing our knowledge and our ability to predict and to
the MMP-poor plaques (57). These results suggest that P947 ac-
treat disease (67, 68). The first study on MMP expression was re-
cumulates within human plaques and is capable of identifying vul-
cently assessed by Muruganatham et al. (69), who have sprayed a
nerable plaques. In the same study, authors have also showed in synthetic Förster resonance energy transfer (FRET) substrate spe-vivo in ApoE-/- mice that P947 might delineate plaques with a pat-
cific for MMPs on rat tissue sections and have used matrix-assisted
tern consistent with that in studies of MMP expression in athero-
laser desorption/ionisation to directly visualising the spatial locali-
sclerotic plaques. Indeed, higher signal intensity at the fibrous cap,
sation of MMP-9 activity. Their results showed a better selectivity
the shoulder regions and the outer layers of plaques were observed.
than fluorescence imaging and constituted a first approach to the
Accordingly, a smaller enhancement in the lipid-rich core regions specific IMS analysis of MMP in tissue section. of plaques was also shown. Amirbekian et al., using confocal laser scanning microscopy with a fluorescent tagged P947 (Eu-P947), have confirmed the colocalisation of specific MMPs and the signals observed with P947 (58). Furthermore, in situ MMP zymography Clinical translation experiments on atherosclerotic aortic sections from ApoE-/- mice have revealed that the fluorescence is due to activated MMPs. Although these new imaging techniques have the capacity to ident- Thereby, MRI with the P947 agent may become a useful imaging ify MMP activity in vivo, two major limitations remain regarding tool for noninvasive detection of MMP activity in the evaluation of the short-term clinical use. Firstly, the agents and probes described atherosclerosis.
in this review will need a full characterisation of their toxic effects, pharmacokinetics and pharmacodynamics. Indeed, radiolabelled antibodies used in nuclear imaging (SPECT) have a relatively slow
Other imaging strategies for detecting protease
clearance from the blood and tissues surrounding the target lesions and accumulate in the liver and the kidneys (41). In MRI studies
activity
using the new contrast agent P947, no data regarding potential toxicity of this probe have been sought (57, 58). At last, among the
An original approach based on a label-free imaging technique has NIRF dyes available, only one (indocyanine green) has been ap-been recently proposed for evaluating MMP-2 and -9 contents proved by the US Food and Drug Administration (FDA) for the use (59). Time-resolved laser-induced fluorescence spectroscopy (TR-
in patients (77, 78). In brief, the in vivo application of these tools
LIFS) is a technique recently shown to be capable of recognising will be impeded until additional research will be conducted on several components associated with plaque vulnerability with high
their toxicity and novel agents/probes developed.
specificity and sensitivity (60). Phipps et al. demonstrated that
The second limitation for the clinical translation is represented
there are distinct levels of MMP-2 and -9, discernible in the fibrotic
by the difficulty for imaging the MMP activity in human coronary
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For personal or educational use only. No other uses without permission. All rights reserved. Lenglet et al. Imaging of matrix metalloproteases
arteries because of their small size and their deep localisation. In-
10. Tanindi A, Sahinarslan A, Elbeg S, et al. Association of matrix metalloprotei-
deed, the MRI approach is inadequate to image small vessels be-
nase-1, matrix metalloproteinase-9, tissue inhibitor of matrix metalloprotei-nase-1, and interleukin-6 with epicardial and myocardial perfusion. Coron Artery
cause of its low sensitivity (58). Since NIRF signal has a limited
depth penetration and quantification, its detection might be more 11. Montecucco F, Di Marzo V, da Silva RF, et al. The activation of the cannabinoid re-accessible in superficial vessels (such as arteries carotids) than in
ceptor type 2 (CB2) reduces neutrophilic protease-mediated vulnerability in atherosclerotic plaques. Eur Heart J 2011; epub ahead of print.
aorta or coronary arteries. To address this need, the development 12. Newby AC. Metalloproteinases and vulnerable atherosclerotic plaques. Trends
of a catheter-based intravascular detection platform will be necess-
ary. An intravascular in vivo approach with a flexible and narrow-
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15. Busti C, Falcinelli E, Momi S, et al. Matrix metalloproteinases and peripheral ar-
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Conclusion
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Conflict of interest
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Patient Education and Counseling 67 (2007) 293–300To err is human: Patient misinterpretations of prescriptionMichael S. Wolf ,Terry C. Davis William Shrank David N. Rapp ,,Pat F. Bass , Ulla M. Connor Marla Clayman , Ruth M. Parker a Health Literacy and Learning Program, Institute for Healthcare Studies, Northwestern University, United Statesb Center for Communication and Medicine, Divi
Additional Information Juan Bustillo, M.D. Professor of Psychiatry and Neurosciences Director, Schizophrenia Research Program Medical Director Spanish Speaking Clinic Attending Psychiatrist, Clozapine Clinic Research Mentor NIH, Scientific Review Group ITVA (Interventions Committee for Adult Disorders). Member: 6/2011 to 2/2014 Exemplary Psychiatrist Award, National Alliance on Mental Il