Self-assembled magnetic fluorescent polymeric micelles for magnetic resonance and optical imaging

Stable and cytocompatible hybrid PEGylated micelles with multimodal imaging capabilities are described. The F₃O₄-encapsulated polymeric micelles composed of cores containing magnetic nanoparticles and polyethylene glycol (PEG) shells are synthesized by self-assembly of amphiphilic poly(HFMA-co-VBK)-g-PEG copolymers and oleic acid stabilized Fe₃O₄ nanoparticles. The Fe₃O₄ magnetic nanoparticles in the core produce T₂-weighted MR imaging functionalities, whereas the small fluorescent monomer carbazole in the polymer shell introduces good fluorescent properties. The multifunctional micelles exhibit excellent paramagnetic properties with the maximum saturation magnetization of 9.61 emu/g and transverse relaxivity rate of 157.44 mm⁻¹ S⁻¹. In vivo magnetic resonance imaging (MRI) studies reveal enhanced contrast between the liver and spleen. Fluorescence spectra show characteristic emission peaks from carbazole at 350 nm and 365 nm and vivid blue fluorescence can be observed by 2-photon confocal scanning laser microscopy (CLSM). In vivo optical imaging demonstrates the unique fluorescent characteristics of the Fe₃O₄-encapsulated polymeric micelles in the liver and spleen and the excellent multifunctional properties suggest potential clinical use as nanocarriers in magnetic resonance imaging and optical imaging.     

Cellular response to nanoscale elastin-like polypeptide polyelectrolyte multilayers

Ionic elastin-like polypeptide (ELP) conjugates are a new class of biocompatible, self-assembling biomaterials. ELPs composed of the repeat unit (GVGVP)(n) are derived from the primary sequence of mammalian elastin and produced in Escherichia coli. These biopolymers exhibit an inverse transition temperature that renders them extremely useful for applications in cell-sheet engineering. Cationic and anionic conjugates were synthesized by the chemical coupling of ELP to polyethyleneimine (PEI) and polyacrylic acid (PAA). The self-assembly of ELP-PEI and ELP-PAA using the layer-by-layer deposition of alternately charged polyelectrolytes is a simple, versatile technique to generate bioactive and biomimetic surfaces with the ability to modulate cell-substratum interactions. Our studies are focused on cellular response to self-assembled multilayers of ionic (GVGVP)(40) incorporated within the polymeric sequence H(2)N-MVSACRGPG-(GVGVP)(40)-WP-COOH. Angle-dependent XPS studies indicated a difference in the chemical composition at the surface ( approximately 10A below the surface) and subsurface regions. These studies provided additional insight into the growth of the nanoscale multilayer assembly as well as the chemical environment that the cells can sense. Overall, cellular response was enhanced on glass substrata coated with ELP conjugates compared with uncoated surfaces. We report significant differences in cell proliferation, focal adhesions and cytoskeletal organization as a function of the number of bilayers in each assembly. These multilayer assemblies have the potential to be successfully utilized in the rational design of coatings on biomaterials to elicit a desired cellular response.     

Erosion of biodegradable block copolymers made of poly(d,l-lactic acid) and poly(ethylene glycol)

Biodegradable block copolymers made of poly(ethylene glycol) monomethylether (Me.PEG) and poly(d,l-lactic acid) (PLA) were investigated for their erosion properties. Wide angle X-ray diffraction (WAXD) and differential scanning calorimetry (DSC) investigations prior to erosion revealed that despite the low content of crystallizable Me.PEG of 10%, Me.PEG5-PLA45 is a partially crystalline polymer. The erosion of the polymer was investigated using cylindrical polymer matrix discs with a diameter of 8mm and a height of 1.5mm. WAXD and DSC spectra obtained from eroded polymer matrix discs suggest that both polymer blocks separate completely during erosion. The crystallinity of Me.PEG5-PLA45 was found to increase during erosion, which is probably due to the improved mobility of Me.PEG inside the polymer with a progressive degree of degradation. The erosion kinetics were found to be similar to that of PLA or poly(lactic-co-glycolic acid). During erosion the polymer matrix weight of dried samples remains constant for 11 weeks after which erosion sets in rapidly. From this observation one can conclude that the impact of the relatively small Me.PEG chains on Me.PEGS-PLA45 erosion is not pronounced. This is beneficial for all those applications that require the stability of the polymer matrix and in which the Me.PEG chain is intended to bring about other effects such as the modification of the surface properties of PLA polymers.     

Erosion of biodegradable block copolymers made of poly( -lactic acid) and poly(ethylene glycol)

Biodegradable block copolymers made of poly(ethylene glycol) monomethylether (Me.PEG) and poly( -lactic acid) (PLA) were investigated for their erosion properties. Wide angle X-ray diffraction (WAXD) and differential scanning calorimetry (DSC) investigations prior to erosion revealed that despite the low content of crystallizable Me.PEG of 10%, Me.PEG5-PLA45 is a partially crystalline polymer. The erosion of the polymer was investigated using cylindrical polymer matrix discs with a diameter of 8mm and a height of 1.5mm. WAXD and DSC spectra obtained from eroded polymer matrix discs suggest that both polymer blocks separate completely during erosion. The crystallinity of Me.PEG5-PLA45 was found to increase during erosion, which is probably due to the improved mobility of Me.PEG inside the polymer with a progressive degree of degradation. The erosion kinetics were found to be similar to that of PLA or poly(lactic-co-glycolic acid). During erosion the polymer matrix weight of dried samples remains constant for 11 weeks after which erosion sets in rapidly. From this observation one can conclude that the impact of the relatively small Me.PEG chains on Me.PEGS-PLA45 erosion is not pronounced. This is beneficial for all those applications that require the stability of the polymer matrix and in which the Me.PEG chain is intended to bring about other effects such as the modification of the surface properties of PLA polymers.     

Cell migration on cell-internalizable ligand microdepots: a phenomenological model

We have shown that collagen ligand associated microdepots (LAMs) at polymer substrates can significantly enhance levels of skin epidermal cell migration (Tjia and Moghe, Tissue Eng. 8:247–259, 2002). In this study, we have further examined the dynamics of cell–LAM interactions, primarily through a phenomenological model to examine the differential effects of LAM–cell binding and LAM internalization within the cells. Based on the experimental data of cell migration and LAM dynamics under selected conditions, the model was solved to yield rates of LAM binding and internalization at various LAM substrate densities. The clearance dynamics of LAMs computed at various times from the model matched well with the LAM clearance kinetics observed experimentally. The model was used to generate simulations of the rates of LAM binding and internalization over time, under conditions of differential exogenous activation. Our model analysis suggests that the rate of cell migration can be sensitively governed by rate of cellular sampling of LAMs, given by differential rates of LAM binding and internalization. Maximal cell migration was found to occur during LAM presentation regimes (LAM spatial density) that engendered concerted changes in the extent of cell activation, as measured via net tyrosine kinase activity, due to LAM sampling dynamics. © 2002 Biomedical Engineering Society. PAC2002: 8714Ee, 8718Ed, 8717Aa, 8715Kg, 8780Rb     

Development of injectable organic/inorganic colloidal composite gels made of self-assembling gelatin nanospheres and calcium phosphate nanocrystals

Colloidal gels are a particularly attractive class of hydrogels for applications in regenerative medicine, and allow for a “bottom-up” fabrication of multi-functional biomaterials by employing micro- or nanoscale particles as building blocks to assemble into shape-specific bulk scaffolds. So far, however, the synthesis of colloidal composite gels composed of both organic and inorganic particles has hardly been investigated. The current study has focused on the development of injectable colloidal organic–inorganic composite gels using calcium phosphate (CaP) nanoparticles and gelatin (Gel) nanospheres as building blocks. These novel Gel–CaP colloidal composite gels exhibited a strongly enhanced gel elasticity, shear-thinning and self-healing behavior, and gel stability at high ionic strengths, while chemical – potentially cytotoxic – functionalizations were not necessary to introduce sufficiently strong cohesive interactions. Moreover, it was shown in vitro that osteoconductive CaP nanoparticles can be used as an additional tool to reduce the degradation rate of otherwise fast-degradable gelatin nanospheres and fine-tune the control over the release of growth factors. Finally, it was shown that these colloidal composite gels support attachment, spreading and proliferation of cultured stem cells. Based on these results, it can be concluded that proof-of-principle has been obtained for the design of novel advanced composite materials made of nanoscale particulate building blocks which exhibit great potential for use in regenerative medicine.     

In vivo biocompatibility of porous silicon biomaterials for drug delivery to the heart

Myocardial infarction (MI), commonly known as a heart attack, is the irreversible necrosis of heart muscle secondary to prolonged ischemia, which is an increasing problem in terms of morbidity, mortality and healthcare costs worldwide. Along with the idea to develop nanocarriers that efficiently deliver therapeutic agents to target the heart, in this study, we aimed to test the in vivo biocompatibility of different sizes of thermally hydrocarbonized porous silicon (THCPSi) microparticles and thermally oxidized porous silicon (TOPSi) micro and nanoparticles in the heart tissue. Despite the absence or low cytotoxicity, both particle types showed good in vivo biocompatibility, with no influence on hematological parameters and no considerable changes in cardiac function before and after MI. The local injection of THCPSi microparticles into the myocardium led to significant higher activation of inflammatory cytokine and fibrosis promoting genes compared to TOPSi micro and nanoparticles; however, both particles showed no significant effect on myocardial fibrosis at one week post-injection. Our results suggest that THCPSi and TOPSi micro and nanoparticles could be applied for cardiac delivery of therapeutic agents in the future, and the PSi biomaterials might serve as a promising platform for the specific treatment of heart diseases.     

mPEG表面修饰的PLGA嵌段共聚物的血液相容性评价

本实验室设计合成了三种不同LA／GA比例的mPEG修饰PLGA（PELGA，含15％mPEG），为了评价它们的血液相容性，我们以硅化玻璃试管为阴性对照，未硅化的试管为阳性对照，参照国际标准（ISO10993）和《中华人民共和国国家标准GB／T16886医疗器械生物学评价》方法进行了体外评价实验。试验包括溶血率实验，血小板黏附实验，动态凝血时间实验，凝血时间实验，血浆复钙时间实验和凝血酶原时间实验等综合评价指标。结果表明，合成材料具有优良的血液相容性，材料制成的纳米粒有望应用于静脉注射。     

载磁性氧化铁CA-PLGA纳米颗粒对宫颈癌细胞的影响

目的 研究纳米四氧化三铁(Fe3O4)颗粒包裹不同外壳材料对宫颈癌细胞HeLa毒性的影响.方法 通过无溶剂热分解法制备磁性纳米Fe3O4颗粒并分别使用聚乳酸-羟基乙酸共聚物(PLGA)和胆酸(CA)修饰的PLGA(CA-PLGA)星型共聚物包裹,对其进行验证表征后,使用激光共聚焦显微镜观察HeLa细胞对纳米颗粒的摄取,并用噻唑蓝(MTT)法测定上述两种材料包裹的纳米Fe3O4颗粒对HeLa细胞的毒性作用.结果 制备的单个纳米Fe3O4颗粒粒径约7 nm,载Fe3O4的PLGA和CA-PLGA纳米颗粒均呈球状,粒径约200 nm,理论载药量为10％.当Fe3O4纳米颗粒的质量浓度相同(25 μg/ml)时,载Fe3O4的CA-PLGA纳米颗粒对HeLa细胞的毒性小于对应的PLGA纳米颗粒.结论 CA-PLGA星型共聚物可降低磁性纳米Fe3O4颗粒的细胞毒性,在生物体内具有广阔的应用前景.     

星型M-PLGA纳米药物制剂用于宫颈癌治疗的研究

目的 本研究合成了一种星型的甘露醇引发的聚（乳酸-羟基乙酸）共聚物（M-PLGA）,旨在提供一种新型的纳米制剂用于宫颈癌的治疗.方法 这种新型的共聚物通过开环聚合合成,利用核磁共振仪进行表征.采用改进的纳米沉淀法制备载多烯紫杉醇M-PLGA纳米粒并在扫描电镜下观察纳米粒的形态.结果 M-PLGA纳米粒粒径分布较窄,在人宫颈癌Hela细胞中的摄取水平要高于PLGA纳米粒.载多烯紫杉醇的M-PLGA纳米粒对Hela细胞的毒性显著高于商用的泰素帝和载多烯紫杉醇的PLGA纳米粒,证明星型M-PLGA聚合物作为纳米药物载体优于线型PLGA聚合物;同时,星型M-PLGA的载药量也明显高于线型聚合物.结论 星型M-PLGA共聚物可作为一种极具潜力的用于宫颈癌治疗的纳米载体材料.     

Cell adhesion mechanisms on laterally mobile polymer films

In contrast with the majority of substrates used to study cell adhesion, the natural extracellular matrix (ECM) is dynamic and remodeled over time. Here we use amphiphilic block copolymers to create self-assembled supported films with tunable lateral mobility. These films are intended to serve as partial mimics of the ECM in order to better understand cell adhesion responses, specifically in the context of dynamic substrates. Block copolymers are end-labeled with RGD peptide ligands to allow for integrin-mediated cell adhesion, and the addition of a trace hydrophobic homopolymer is used to control the film lateral mobility. We find that NIH 3T3 fibroblasts cultured on these biomimetic films exhibit non-linear spreading behavior in response to substrate mobility. In the absence of RGD ligands, however, fibroblasts do not spread. Employing quantitative analysis of focal adhesions (FA) and integrin ligation, we discover the presence of FA-dependent and FA-independent mechanisms responsible for the biphasic cell spreading behavior. The use of designed biomimetic platforms therefore yields insight into ECM mechanosensing by revealing that cells can engage distinct mechanisms to promote adhesion onto substrates with different time-dependent properties.     

Development of novel fluorescent particles applicable for phagocytosis assays with human macrophages

Phagocytosis is a fundamental process for removal of pathogens and for clearance of apoptotic cells. The objective of this work was the preparation of fluorescent microspheres by a simple method and the evaluation of its applicability in phagocytosis assays by using different human derived cells, differentiated THP-1 cell line and blood monocytes, with flow cytometry measurements for functionality assays. Our results show that microparticles are efficiently internalised in a non-opsonised form and in dose-dependent manner by both cellular types. Concerning mechanism we determined that tTG-β3 integrin signaling could be involved in the uptake of these particles.     

Characterization of the thermo- and pH-responsive assembly of triblock copolymers based on poly(ethylene glycol) and functionalized poly(ε-caprolactone)

A series of novel triblock copolymers composed of poly(ethylene glycol) (PEG) and poly(ε-caprolactone)-bearing benzyl carboxylate on the α-carbon of ε-caprolatone were synthesized through ring opening polymerization of α-benzyl carboxylate-ε-caprolactone by dihydroxylated PEG. The debenzylation of the synthesized copolymer, i.e., poly(α-benzyl carboxylate-ε-caprolactone)-b-PEG-b-poly(α-benzyl-carboxylate-ε-caprolactone) (PBCL-b-PEG-b-PBCL), in the presence of hydrogen gas using different levels of catalyst, was carried out to achieve copolymers with various degrees of free α-carboxyl to α-benzyl-ε-carboxylate groups on the hydrophobic block. Incomplete reduction of PBCL led to the formation of poly(α-carboxyl-co-benzyl caboxylate-ε-caprolactone) PCBCL in the lateral blocks at 27%, 50% and 75% carboxyl group substitution. The molecular weight and polydispersity of the resultant copolymers were estimated by ¹H NMR and MALDI-TOF. Synthesized triblock copolymers formed stable micelles at low concentrations (critical micellar concentrations (CMC) of 0.34–12.5 μg ml⁻¹). Polymers containing carboxyl groups in their structure showed a pH-dependent increase in CMC. As the pH was raised from 4.0 to 9.0, CMC increased from 0.76 to 1.06 μg ml⁻¹, for 27% debenzylated polymer, and from 1.30 to 2.20 μg ml⁻¹, for 50% debenzylated polymers. In contrast, the CMC in polymers without carboxyl group was independent of pH (0.55 μg ml⁻¹). Different changes in micellar size as a function of temperature was observed depending on the degree of debenzylation on the PCBCL block: polymers with 27% degree of debenzylation illustrated a rise in micelle size from ∼38 to 55 nm as the temperature increased above 29 °C, while polymers with 50% debenzylation showed a decrease in micelle size, from ∼52 to 38 nm, with increase in temperature. A similar trend was observed at pH 4.5, 7.0 and 9.0 for polymers containing carboxyl groups on their hydrophobic block. The temperature for the onset of size change and/or the extent of aggregate size change was found to be dependent on the pH of the medium and the polymer concentration. The results point to a potential for the formation of thermo- and pH-responsive micelles from triblock copolymers of PEG and carboxyl substituted caprolactone. The results also imply a potential for the 27% debenzylated PCBCL-b-PEG-b-PCBCL copolymers to form a biodegradable thermoreversible gel with a transition temperature a few degrees below 37 °C.     

Remineralization of human dentin using ultrafine bioactive glass particles

Bioactive glass nanoparticles synthesized by flame spray synthesis were tested for their remineralization capabilities in vitro. After artificial demineralization with EDTA, human dentin was treated with 20–50 nm size bioactive glass nanoparticles or a micrometer-sized, commercial reference material (PerioGlas) for up to 30 days. The degree of remineralization was measured using quantitative gravimetric methods (thermogravimetry, elemental analysis) and element-sensitive scanning electron microscopy imaging to detect new mineral precipitated on or within the demineralized tooth matrix. After treatment with bioactive glass nanoparticles for 10 or 30 days a pronounced increase in mineral content of the dentin samples suggested a rapid remineralization. The mechanical properties of the remineralized dentin samples were well below the stability of natural dentin. It is suggested that this lack of mechanical reconstitution may be attributed to an imperfect arrangement of the newly deposited mineral within the demineralized tooth matrix. Nevertheless, the substantially higher remineralization rate induced by nanometer-sized vs. micrometric bioactive glass particles corroborated the importance of particle size in clinical bioglass applications.     

Synthesis of functional polyester for fabrication of nano-fibrous scaffolds and its effect on PC12 cells

An ideal scaffold should mimic the advantageous characteristics of a natural extracellular matrix for cell attachment, proliferation, and differentiation. In this study, well-defined block copolymer with functional groups was synthesized. The structure of the block copolymer was characterized by nuclear magnetic resonance, gel permeation chromatography, and differential scanning calorimetry. Thermally induced phase separation was employed to fabricate nano-fibrous scaffolds based on the synthesized block copolymer. The scaffold, with fiber diameter ranging from 400 to 500 nm, was fabricated for in vitro culture of PC12 cells. The carboxyl groups on the side chain resulted in increased hydrophilicity of nano-fibrous scaffolds and enhanced cell proliferation. In addition, this scaffold structure was beneficial in directing the growth of regenerating axons in nerve tissue engineering. Results of 3-(4,5-dimethylthiazol-2yl)-2,5-diphenyltetrazolium bromide (MTT) assay and scanning electron microscopy confirmed that the nano-fibrous scaffolds with functional groups were suitable for PC12 cells growth. Moreover, the carboxyl groups were suitable for coupling with biological signals. Thus, the nano-fibrous scaffolds have potential applications in tissue engineering.     

Cell adhesion on phase-separated surface of block copolymer composed of poly(2-methacryloyloxyethyl phosphorylcholine) and poly(dimethylsiloxane)

We investigated the morphological effect of phase-separated block copolymer surfaces composed of poly(2-methacryloyloxyethyl phosphorylcholine (MPC)) (PMPC) and poly(dimethylsiloxane) (PDMS) on protein adsorption and cell adhesion behavior. We observed three different types of phase-separated surface morphologies by TEM and AFM. The elemental composition of phosphorus on the surface increases with the PMPC composition. Furthermore, the polymer surface formed by a block copolymer-containing a higher MPC unit composition shows a slightly lower static water contact angle. This result indicates that the elemental surface ratio of the surface depends on the MPC composition in the block copolymer. Protein adsorption tests revealed that only hydrophobic PDMS domains showed selective protein adsorption. Cell adhesion tests revealed that the number of adhered cells increased with increasing hydrophobic PDMS domain size of block copolymers in serum-containing media. In contrast, no cells adhered onto block copolymer surfaces in serum-free media, whereas a large amount of adhered cells were observed on the hydrophobic PDMS surface. This result indicates that segregated hydrophobic domains on a biocompatible PMPC surface strongly affect serum protein adsorption, thereby promoting considerable cell adhesion, although the surface is hydrophilic. Thus, both the composition of MPC units and the segregated hydrophobic surface morphology are important considerations in biomaterial surface design.     

Docetaxel-loaded nanoparticles based on star-shaped mannitol-core PLGA-TPGS diblock copolymer for breast cancer therapy

A star-shaped biodegradable polymer, mannitol-core poly(d,l-lactide-co-glycolide)-d-α-tocopheryl polyethylene glycol 1000 succinate (M-PLGA-TPGS), was synthesized in order to provide a novel nanoformulation for breast cancer chemotherapy. This novel copolymer was prepared by a core-first approach via three stages of chemical reaction, and was characterized by nuclear magnetic resonance, gel permeation chromatography and thermogravimetric analysis. The docetaxel-loaded M-PLGA-TPGS nanoparticles (NPs), prepared by a modified nanoprecipitation method, were observed to be near-spherical shape with narrow size distribution. Confocal laser scanning microscopy showed that the uptake level of M-PLGA-TPGS NPs was higher than that of PLGA NPs and PLGA-TPGS NPs in MCF-7 cells. A significantly higher level of cytotoxicity was achieved with docetaxel-loaded M-PLGA-TPGS NPs than with commercial Taxotere®, docetaxel-loaded PLGA-TPGS and PLGA NPs. Examination of the drug loading and encapsulation efficiency proved that star-shaped M-PLGA-TPGS could carry higher levels of drug than linear polymer. The in vivo experiment showed docetaxel-loaded M-PLGA-TPGS NPs to have the highest anti-tumor efficacy. In conclusion, the star-like M-PLGA-TPGS copolymer shows potential as a promising drug-loaded biomaterial that can be applied in developing novel nanoformulations for breast cancer therapy.     

Biodegradable and amphiphilic block copolymer–doxorubicin conjugate as polymeric nanoscale drug delivery vehicle for breast cancer therapy

Polymeric nanoparticles have shown great promise as attractive vehicles for drug delivery. In this study, we designed, prepared and characterized biodegradable amphiphilic triblock HPMA copolymer–doxorubicin (copolymer–DOX) conjugate based nanoparticle as enzyme-sensitive drug delivery vehicle. The enzyme-sensitive peptide GFLGKGLFG was introduced to the main chain of the copolymer with hydrophilic and hydrophobic blocks. The triblock HPMA polymer–DOX conjugate with high molecules (Mw 90 kDa) can be degraded to product with low molecule weight (Mw 44 kDa) below the renal threshold. The copolymer–DOX conjugate can self-assemble into compact nanoparticle, which was characterized by scanning electron microscope (SEM) and atomic force microscope (AFM) studies. This polymeric nanoparticle substantially enhanced antitumor efficacy compared to the free DOX, exhibiting much higher effects on inhibiting proliferation and inducing apoptosis on the 4T1 murine breast cancer model confirmed by the evidences from mice weight shifts, tumor growth curves, tumor growth inhibition (TGI), immunohistochemical analysis and histological assessment. The in vivo toxicity evaluation demonstrated that the polymeric nanoparticle reduced DOX-induced toxicities and presented no significant side effects to normal organs of both tumor bearing and healthy mice as measured by body weight shift, blood routine test and histological analysis. Therefore, the triblock HPMA copolymer–DOX conjugate based nanoparticle is promising as a potential drug delivery vehicle for breast cancer therapy.     

Surface plasma modification and tropoelastin coating of a polyurethane co-polymer for enhanced cell attachment and reduced thrombogenicity

Polymers currently utilized for dermal and vascular applications possess sub-optimal biocompatibility which reduces their efficacy. Improving the cell-binding and blood-contacting properties of these polymers would substantially improve their clinical utility. Tropoelastin is a highly extensible extracellular matrix protein with beneficial cell interactive and low thrombogenic properties. We transferred these benefits to the polyurethane block copolymer Elast-Eon E2A through a specific combination of surface plasma modifications and coating with human tropoelastin. The cell-binding activity of bound tropoelastin was modulated by ion implantation of the underlying polymer, and correlated with surface hydrophobicity, carbon and oxygen content. This combined treatment enhanced human dermal fibroblast (HDF) and human umbilical vein endothelial cell (HUVEC) attachment, cytoskeletal assembly and viability, combined with elevated PECAM-1 staining of HUVEC cell junctions. The thrombogenicity of the polymer was ameliorated by tropoelastin coating. We propose that a combination of metered plasma treatment and tropoelastin coating of Elast-Eon can serve to improve the biological performance of implantable devices such as vascular conduits.     

Elucidating the molecular mechanism for the intracellular trafficking and fate of block copolymer micelles and their components

Block copolymer micelles have shown promise for the intracellular delivery of chemotherapeutic agents, proteins, and nucleic acids. Understanding the mechanism of their intracellular trafficking and fate, including the extracellular efflux of the polymers, will help improve their efficacy and minimize their safety risks. In this Leading Opinion paper, we discuss the molecular mechanism of block copolymer micelle trafficking, from intracellular uptake to extracellular efflux, on the basis of studies with HeLa cells. By using FRET (fluorescence resonance energy transfer) with confocal microscopy, we found that, following their intracellular transport via endocytosis, the micelles dissociated into their polymeric components in late endosomes and/or lysosomes. Furthermore, we confirmed that the intrinsic proteins NPC1 and ORP2 are involved in the intermembrane transfer of polymers from the endosome to the plasma membrane via the ER (endoplasmic reticulum) by using knockdown experiments with siRNAs. After the polymers were transported to the plasma membrane with the aid of ORP2, they were extruded into the cell medium via ABC transporter, ABCB1. Experiments with ABCB1-expressing vesicles indicated that the polymer itself, and not the fluorescent compounds, was recognized by the transporter. These findings, and the analysis of related mechanisms, provide valuable information that should help minimize the potential risks associated with the intracellular accumulation of block copolymer micelles and to improve their therapeutic efficacy.