Recent Advances in the Molecular Imaging of Atherosclerosis.

Atherosclerosis is the major underlying cause of cardiovascular diseases, the prevalence of which is continuously increasing, thus currently standing as the leading global cause of death. This pathology gradually develops over the course of 50 or more years throughout the life of an individual under the influence of a vast number of factors, both environmental and pathophysiological. This wealth of factors has elicited much research into molecular imaging, with purely diagnostic purposes or with the hope of engineering an efficient theranostic tool. To these ends, diverse nanomaterials with desirable, tunable properties have been explored by different teams, as described in this review.

Multimodal molecular imaging of atherosclerosis: Nanoparticles functionalized with scFv fragments of an anti-αIIbß3 antibody.

Due to the wealth of actors involved in the development of atherosclerosis, molecular imaging based on the targeting of specific markers would substantiate the diagnosis of life-threatening atheroma plaques. To this end, TEG4 antibody is a promising candidate targeting the activated platelets (integrin αIIbß3) highly represented within the plaque. In this study, scFv antibody fragments were used to functionalize multimodal imaging nanoparticles. This grafting was performed in a regio-selective way to preserve TEG4 activity and the avidity of the nanoparticles was studied with respect to the number of grafted antibodies. Subsequently, taking advantage of the nanoparticle bimodality, both near infrared fluorescence and magnetic resonance imaging of the atheroma plaque were performed in the ApoE-/- mouse model. Here we describe the design of the targeted nanoparticles, and a quantification method for their detection in mice, both ex vivo and in vivo, highlighting their value as a potential diagnosis agent.

[Monoclonal antibodies for monogenic diseases: a 2019 update]. / Actualités des anticorps monoclonaux dans les maladies monogéniques aujourd'hui.

Monogenic diseases are rare genetic diseases but they are numerous and display a highly variable degree of severity. First uses of monoclonal antibodies to treat monogenic diseases started in the 2000's and many clinical trials are ongoing. Anti-IL-1ß therapies have greatly modified the outcome of auto-inflammatory diseases by modulating inflammatory response and reducing the risk of secondary amyloidosis. Anti-TNF-α are also used in such diseases. In atypical hemolytic and uremic syndrome due to deficiencies in the control of alternative complement pathway, eculizumab, an anti-C5 monoclonal antibody, has improved renal outcome in treated patients. More recently, lanadelumab, an anti-plasma kallikrein antibody, has reinforced the therapeutic arsenal in hereditary angioedema and burosumab, anti-FGF23, that of X-linked hypophosphatemia. Such examples reflect the importance of monoclonal antibody therapy of monogenic diseases, the interest of considering such an option as well as the need for future researches.

TITLE: Actualités des anticorps monoclonaux dans les maladies monogéniques aujourd'hui. ABSTRACT: Les maladies monogéniques sont des maladies génétiques rares mais très nombreuses, avec une sévérité variable. Les premières utilisations des anticorps monoclonaux dans ces maladies remontent aux années 2000 et de nombreux essais sont désormais en cours. Les anticorps monoclonaux anti-(interleukine)IL-1ß ont profondément transformé la prise en charge des maladies auto-inflammatoires en modulant la composante inflammatoire et en diminuant le risque d'amylose secondaire ; les anticorps monoclonaux anti-TNF-α et anti-IL-6 sont également prescrits dans ces maladies. Dans le syndrome hémolytique et urémique atypique lié à des défauts de régulation de la voie alterne du complément, l'éculizumab, un anticorps monoclonal anti-C5, a permis d'améliorer le pronostic rénal des patients traités. Plus récemment, le lanadélumab, un anticorps monoclonal anti-kallicréïne plasmatique, est venu renforcer l'arsenal thérapeutique des angiœdèmes héréditaires et le burosumab, un anticorps monoclonal anti-FGF23, celui du rachitisme hypophosphatémique lié à l'X. Ces exemples illustrent bien l'importance de l'utilisation des anticorps monoclonaux dans la prise en charge des maladies monogéniques, l'intérêt de considérer cette option thérapeutique dans ce domaine et la nécessité de poursuivre des recherches.

Data on atherosclerosis specific antibody conjugation to nanoemulsions.

This article present data related to the publication entitled "Iron oxide core oil-in-water nanoemulsion as tracer for atherosclerosis MPI and MRI imaging" (Prévot et al., 2017) [1]. Herein we describe the engineering in the baculovirus-insect cell system and purification processes of the human scFv-Fc TEG4-2C antibody, specific of platelets within the atheroma plaque. For molecular targeting purpose, atheroma specific antibody was conjugated to nanoemulsions (NEs) using a heterobifunctional linker (DSPE-PEG-maleimide). Atheroma labelling was assayed by immunochemistry on arterial sections from rabbits.

Iron oxide core oil-in-water nanoemulsion as tracer for atherosclerosis MPI and MRI imaging.

PURPOSE: For early atherosclerosis imaging, magnetic oil-in-water nanoemulsion (NE) decorated with atheroma specific monoclonal antibody was designed for Magnetic Particle Imaging (MPI) and Magnetic Resonance Imaging (MRI). MPI is an emerging technique based on direct mapping of superparamagnetic nanoparticles which may advantageously complement MRI. METHODS: NE oily droplets were loaded with superparamagnetic iron oxide nanoparticles of 7, 11 and 18nm and biofunctionalized with atheroma specific scFv-Fc TEG4-2C antibody. RESULTS: Inclusion of nanoparticles inside NE did not change the hydrodynamic diameter of the oil droplets, close to 180nm, nor the polydispersity. The droplets were negatively charged (ζ=-30mV). In vitro MPI signal was assessed by Magnetic Particle Spectroscopy (MPS). NE displayed MRI and MPS signals confirming its potential as new contrast agent. NE MPS signal increase with NPs size close to the gold standard (Resovist). In MRI, NE displayed R2* transversal relaxivity of 45.45, 96.04 and 218.81mM-1s-1 for 7, 11 and 18nm respectively. NE selectively bind atheroma plaque both in vitro and ex vivo in animal models of atherosclerosis. CONCLUSION: Magnetic NE showed reasonable MRI/MPS signals and a significant labelling of the atheroma plaque. These preliminary results support that NE platform could selectively image atherosclerosis.

A Recombinant Human Anti-Platelet scFv Antibody Produced in Pichia pastoris for Atheroma Targeting.

Cells of the innate and adaptive immune system are key factors in the progression of atherosclerotic plaque, leading to plaque instability and rupture, potentially resulting in acute atherothrombotic events such as coronary artery disease, cerebrovascular disease and peripheral arterial disease. Here, we describe the cloning, expression, purification, and immunoreactivity assessment of a recombinant single-chain variable fragment (scFv) derived from a human anti-αIIbß3 antibody (HuAb) selected to target atheromatous lesions for the presence of platelets. Indeed, platelets within atheroma plaques have been shown to play a role in inflammation, in platelet-leucocyte aggregates and in thrombi formation and might thus be considered relevant biomarkers of atherosclerotic progression. The DNA sequence that encodes the anti-αIIbß3 TEG4 scFv previously obtained from a phage-display selection on activated platelets, was inserted into the eukaryote vector (pPICZαA) in fusion with a tag sequence encoding 2 cysteines useable for specific probes grafting experiments. The recombinant protein was expressed at high yields in Pichia pastoris (30 mg/L culture). The advantage of P. pastoris as an expression system is the production and secretion of recombinant proteins in the supernatant, ruling out the difficulties encountered when scFv are produced in the cytoplasm of bacteria (low yield, low solubility and reduced affinity). The improved conditions allowed for the recovery of highly purified and biologically active scFv fragments ready to be grafted in a site-directed way to nanoparticles for the imaging of atherosclerotic plaques involving inflammatory processes and thus at high risk of instability.

Nanoparticles functionalised with an anti-platelet human antibody for in vivo detection of atherosclerotic plaque by magnetic resonance imaging.

Atherosclerosis is an inflammatory disease associated with the formation of atheroma plaques likely to rupture in which platelets are involved both in atherogenesis and atherothrombosis. The rupture is linked to the molecular composition of vulnerable plaques, causing acute cardiovascular events. In this study we propose an original targeted contrast agent for molecular imaging of atherosclerosis. Versatile USPIO (VUSPIO) nanoparticles, enhancing contrast in MR imaging, were functionalised with a recombinant human IgG4 antibody, rIgG4 TEG4, targeting human activated platelets. The maintenance of immunoreactivity of the targeted VUSPIO against platelets was confirmed in vitro by flow cytometry, transmission electronic and optical microscopy. In the atherosclerotic ApoE(-/-) mouse model, high-resolution ex vivo MRI demonstrated the selective binding of TEG4-VUSPIO on atheroma plaques. It is noteworthy that the rationale for targeting platelets within atherosclerotic lesions is highlighted by our targeted contrast agent using a human anti-αIIbß3 antibody as a targeting moiety. FROM THE CLINICAL EDITOR: Current clinical assessment of atherosclerotic plagues is suboptimal. The authors in the article designed functionalized superparamagnetic iron oxide nanoparticles with TEG4, a recombinant human antibody, to target activated platelets. By using MRI, these nanoparticles can be utilized to study the process of atheroma pathogenesis.