Laurence Moine

E-selectin as a target for drug delivery and molecular imaging

E-selectin, also known as CD62E, is a cell adhesion molecule expressed on endothelial cells activated by cytokines. Like other selectins, it plays an important part in inflammation and in the adhesion of metastatic cancer cells to the endothelium. E-selectin recognizes and binds to sialylated carbohydrates present on the surface proteins of certain leukocytes. E-selectin has been chosen as a target for several therapeutic and medical imaging applications, based on its expression in the vicinity of inflammation, infection or cancer. These systems for drug delivery and molecular imaging include immunoconjugates, liposomes, nanoparticles, and microparticles prepared from a wide range of starting materials including lipids, synthetic polymers, polypeptides and organo-metallic structures. After a brief introduction presenting the selectin family and their implication in physiology and pathology, this review focuses on the formulation of these new delivery systems targeting E-selectin at a molecular level.

Elasticity and viscoelasticity of embolization microspheres.

The present study investigates the mechanical properties of three embolization microspheres (E-ms): tris-acryl gelatin microspheres (TG-ms), acrylamido polyvinyl alcohol microspheres (APVA-ms), and polyphosphazene-coated polymethylmethacrylate microspheres (PP-PMMA-ms). Compression and relaxation tests were performed on monolayers of particles and their Youngs moduli and relaxation half times (RHTs) were determined. The elasticity of E-ms was evaluated by applying Hertz theory with the assumptions of incompressibility and a Poissons ratio of 0.5. The Youngs moduli of TG-ms, APVA-ms, and PP-PMMA-ms were 39.6±5.05 kPa, 18.8±4.00 kPa, and 13.6±1.98 kPa, respectively. The RHTs of TG-ms, APVA-ms, and PP-PMMA-ms were 52.3±5.56 s, 59.1±8.16 s, and 31.0±7.01 s, respectively. TG-ms have a high rigidity and deform slightly under a sustained compression since they have a high elasticity. PP-PMMA-ms are soft and deform a lot under sustained compression. They are more viscous than the other two microspheres. APVA-ms have intermediate material properties, having the same low rigidity as PP-PMMA-ms and being more elastic than TG-ms.

Intra-articular fate of degradable poly(ethyleneglycol)-hydrogel microspheres as carriers for sustained drug delivery

A novel degradable microsphere (MS) for intra-articular drug delivery, composed of a polyethylene glycol (PEG) core containing degradable regions made of short poly-(lactic-co-glycolic acid) (PLGA) sequences - named PEG-hydrogel MS - was injected into the cavity of sheep shoulder joint, and compared to non-degradable MS devoid of hydrolysable crosslinker in terms of location, degradation and inflammation. One week after intra-articular injection both groups of MS were localized beneath the synovial lining of the synovial fringes located at bottom of the shoulder joint, while a fraction of particles remained in synovial fluid. Histological analyses made one and 4 weeks after intra-articular injection showed cell proliferation around the non-degradable MS entrapped within the synovium. By contrast, degradable PEG-hydrogel MS were surrounded by few cells. The degradation of degradable PEG-hydrogel MS within the synovium was slow and was not fully complete after four weeks. Our findings indicate that the tissue entrapment of MS below the synovial lining was independent of the material degradability, while degradable PEG-hydrogel MS are less inflammatory than the non-degradable one. Degradable PEG-hydrogel MS offer several advantages over the non-degradable MS as carriers for a sustained drug delivery in synovial tissue according to the low intensity of inflammatory reaction triggered in synovium.

Synthesis of hydrophilic intra-articular microspheres conjugated to ibuprofen and evaluation of anti-inflammatory activity on articular explants.

The main limitation of current microspheres for intra-articular delivery of non-steroidal anti-inflammatory drugs (NSAIDs) is a significant initial burst release, which prevents a long-term drug delivery. In order to get a sustained delivery of NSAIDs without burst, hydrogel degradable microspheres were prepared by co-polymerization of a methacrylic derivative of ibuprofen with oligo(ethylene-glycol) methacrylate and poly(PLGA-PEG) dimethacrylate as degradable crosslinker. Microspheres (40-100 μm) gave a low yield of ibuprofen release in saline buffer (≈2% after 3 months). Mass spectrometry analysis confirmed that intact ibuprofen was regenerated indicating that ester hydrolysis occurred at the carboxylic acid position of ibuprofen. Dialysis of release medium followed by alkaline hydrolysis show that in saline buffer ester hydrolysis occurred at other positions in the polymer matrix leading to the release of water-soluble polymers (>6-8000 Da) conjugated with ibuprofen showing that degradation and drug release are simultaneous. By considering the free and conjugated ibuprofen, 13% of the drug is released in 3 months. In vitro, ibuprofen-loaded MS inhibited the synthesis of prostaglandin E2 in articular cartilage and capsule explants challenged with lipopolysaccharides. Covalent attachment of ibuprofen to PEG-hydrogel MS suppresses the burst release and allows a slow drug delivery for months and the cyclooxygenase-inhibition property of regenerated ibuprofen is preserved.

Preparation of E-selectin-targeting nanoparticles and preliminary in vitro evaluation

Targeted delivery aims to concentrate therapeutic agents at their site of action and thereby enhance treatment and limit side-effects. E-selectin on endothelial cells is markedly up-regulated by cytokine stimulation of inflamed and some tumoral tissues, promoting the adhesion of leukocytes and metastatic tumor cells, thus making it an interesting molecular target for drug delivery systems. We report here the preparation of targeted nanoparticles from original amphiphilic block copolymers functionalized with an analog of sialyl Lewis X (SLEx), the physiological ligand of E-selectin. Nanoparticles, prepared by nanoprecipitation, caused no significant cytotoxicity. Ligand-functionalized nanoparticles were specifically recognized and internalized better by tumor necrosis factor α (TNF-α)-activated human umbilical vein endothelial cells (HUVECs) than control nanoparticles or HUVECs with low E-selectin expression. These nanoparticles are designed to carry the ligand at the end of a PEG spacer to improve accessibility. This system has potential for the treatment of inflammation, inhibition of tumor metastasis, and for molecular imaging.

Targeting and Recanalization after Embolization with Calibrated Resorbable Microspheres versus Hand-cut Gelatin Sponge Particles in a Porcine Kidney Model

PURPOSEnTo report on polyethylene glycol hydrogel-based resorbable embolization microspheres (REM) that were synthesized to resorb in < 24 hours, before inflammation and vascular remodeling, to achieve a complete arterial recanalization and to compare targeting and recanalization of REM of 300-500 µm, 500-700 µm, and 700-900 µm with hand-cut gelatin sponge particles (GSP).nnnMATERIALS AND METHODSnEight pigs underwent polar renal artery embolization with REM or GSP. Angiograms were obtained before embolization and 10 minutes and 7 days after embolization before pigs were sacrificed to determine the occlusion level, the percentage of occlusion, and the recanalization rate for each product. The distribution of embolic material was assessed in pathology, and infarction rate of the kidneys was measured.nnnRESULTSnREM of 300-500 µm occluded more distal vessels than REM of 500-700 µm and 700-900 µm. At day 7, the recanalization rate was complete for the larger REM, whereas it was about 60% for the two smaller sizes. REM were completely degraded, with no residual material or inflammation. GSP occluded more proximal arteries than REM of 700-900 µm, were partly degraded at day 7, and were accompanied by a foreign body reaction in proximal and distal arteries. GSP recanalized at 79%. The infarction rate was higher with the two smaller sizes of REM and with GSP than with the largest REM.nnnCONCLUSIONSnREM of different sizes targeted different occlusion levels in kidney arteries. GSP provided an extended occlusion level without actual targeting. Regardless of embolic material used, angiographic recanalization of renal arteries depended on the extent of necrosis. REM of 700-900 µm demonstrated the lowest infarction rate and the best recanalization rate.

Toxicity of Doxorubicin on Pig Liver After Chemoembolization with Doxorubicin-loaded Microspheres: A Pilot DNA-microarrays and Histology Study

PurposeThe potential mechanisms accounting for the hepatotoxicity of doxorubicin-loaded microspheres in chemoembolization were examined by combining histology and DNA-microarray techniques.MethodsThe left hepatic arteries of two pigs were embolized with 1xa0mL of doxorubicin-loaded (25xa0mg; (DoxMS)) or non-loaded (BlandMS) microspheres. The histopathological effects of the embolization were analyzed at 1xa0week. RNAs extracted from both the embolized and control liver areas were hybridized onto Agilent porcine microarrays. Genes showing significantly different expression (pxa0<xa00.01; fold-changexa0>xa02) between two groups were classified by biological process.ResultsAt 1xa0week after embolization, DoxMS caused arterial and parenchymal necrosis in 51 and 38xa0% of embolized vessels, respectively. By contrast, BlandMS did not cause any tissue damage. Up-regulated genes following embolization with DoxMS (vs. BlandMS, nxa0=xa0353) were mainly involved in cell death, apoptosis, and metabolism of doxorubicin. Down-regulated genes (nxa0=xa0120) were mainly related to hepatic functions, including enzymes of lipid and carbohydrate metabolisms. Up-regulated genes included genes related to cell proliferation (growth factors and transcription factors), tissue remodeling (MMPs and several collagen types), inflammatory reaction (interleukins and chemokines), and angiogenesis (angiogenic factors and HIF1a pathway), all of which play an important role in liver healing and regeneration.ConclusionsDoxMS caused lesions to the liver, provoked cell death, and disturbed liver metabolism. An inflammatory repair process with cell proliferation, tissue remodeling, and angiogenesis was rapidly initiated during the first week after chemoembolization. This pilot study provides a comprehensive method to compare different types of DoxMS in healthy animals or tumor models.

Influence of degradation on inflammatory profile of polyphosphazene coated PMMA and trisacryl gelatin microspheres in a sheep uterine artery embolization model

Embolization with microspheres is widely applied to treat uterine fibroids. However, the foreign body reaction that could result from the degradation of the microspheres remains to be evaluated to adequately appreciate the tissular tolerance to such biomaterials. We compared herein the in situ degradation of PMMA microspheres coated with polyphosphazene (PMMA-PPms) and trisacryl gelatin microspheres (TGms) and we thoroughly investigated the induced local inflammatory responses, at 1 and 4 weeks after uterine artery embolization in sheep, by using immunohistochemistry and microarray analyses. PMMA-PPms underwent an acute and partial degradation that was associated with the early recruitment of phagocytic cells (CD172a+ and MHCII+), and with the up-regulated expression of genes involved in the movement of phagocytes (ALOX5AP, CXCL2, CXCL5, IL8, PTGS2, YARS). By contrast, TGms were not degraded and triggered a different inflammation profile including the recruitment of FBR Giant Cells and T-lymphocytes (CD4+) and the increased expression of genes involved in lymphocyte activation (CXCL10, IL2RG, IRAK4, MALT1). Our results indicate that, in contrast to a non-degradable microsphere such as TGms which is associated to a poorly inflammatory foreign body reaction that rapidly resolves, PMMA-PPms, which is partially degradable, rapidly recruits and activates inflammatory phagocytes, thus delaying the resolution of the foreign body reaction.

Embolization biomaterial reinforced with nanotechnology for an in-situ release of anti-angiogenic agent in the treatment of hyper-vascularized tumors and arteriovenous malformations.

A polymer based material was developed to act as an embolic agent and drug reservoir for the treatment of arteriovenous malformations (AVM) and hyper vascularized solid tumors. The aim was to combine the blocking of blood supply to the target region and the inhibition of the embolization-stimulated angiogenesis. The material is composed of an ethanolic solution of a linear acrylate based copolymer and acrylate calibrated microparticles containing nanospheres loaded with sunitinib, an anti-angiogenic agent. The precipitation of the linear copolymer in aqueous environment after injection through microcatheter results in the formation of an in-situ embolization gel whereas the microparticles serve to increase the cohesive properties of the embolization agent and to form a reservoir from which the sunitinib-loaded nanospheres are released post-embolization. The swollen state of the microparticles in contact with aqueous medium results in the release of the nanospheres out of microparticles macromolecular structure. After the synthesis, the formulation and the characterization of the different components of the material, anti-angiogenic activity was evaluated in vitro using endothelial cells and in vivo using corneal neovascularization model in rabbit. The efficiency of the arterial embolization was tested in vivo in a sheep model. Results proved the feasibility of this new system for vascular embolization in association with an in situ delivery of anti-angiogenic drug. This combination is a promising strategy for the management of arteriovenous malformations and solid tumors.