Mini Review

Controlling Amphiphilic Functional Block Copolymers’ Self-Assembly: From Structure to Size

Fei Liu¹*, Yuan Sun² and Chen Kang³

¹Department of Chemistry, University of Alabama at Birmingham, USA

²Department of Chemistry and Biochemistry, The Ohio State University, USA

³Division of Pharmacology, The Ohio State University, USA

Submission: May 25, 2016; Published: June 17, 2016

*Corresponding author: Fei Liu, Department of Chemistry, University of Alabama at Birmingham, Birmingham, AL, 35209, USA, Tel: 205-935-0670; Email: yiyaoleo@g

How to cite this article: Fei L, Yuan S ,Chen K. Controlling Amphiphilic Functional Block Copolymers’ Self-Assembly: From Structure to Size. Glob J Nano. 2016; 1(1): 555553. DOI: 10.19080/GJN.2016.01.555553

Abstract

Nanostructure of self-assembled particles, such as micelles and polymersomes play an important role in drug delivery, especially in tumor therapy. Particles with various structures and proper sizes (20~500 nm) are regarded as perfect candidates for controlled drug delivery due to controllable size that benefits the extended permeation and retention (EPR) and high payload that increases drug delivery efficiency. In this review, we summarized recent representative studies in controlling the size and structure of Amphiphilic block copolymers self-assembled particles with pH- and temperature responsiveness.

Keywords: Nanoparticles; Self-assembly; Size; Structure

Abbreviations: EPR: Extended Permeation and Retention; RAFT: Reversible Addition-Fragmentation Chain Transfer; PAA-b-PSt: Poly (Acrylic Acid)-b-Polystyrene; PNIPAM: Poly (N-isopropylacrylamide); PVCL: Caprolactam; PVPON-PVCL: Poly (Vinyl Pyrrolidone)-b-poly (N-vinylcaprolactam); PEO-b-PVCL: Polyethylene Oxide-b-Poly(N-vinylcaprolactam); PVCL-PDMS-PVCL: Poly(N-vinylcaprolactam)-Poly(dimethylsiloxane)-Poly(N-vinylcaprolactam); PCL-b-PVCL: Poly (ε-caprolactone)-b-Poly (N-vinylcaprolactam)

Introduction

Nanostructure of self-assembled particles, such as micelles and polymersomes play an important role in drug delivery, especially in tumor therapy. Particles with various structures are regarded as perfect candidates for controlled drug delivery due to highly selective cellular uptake and exceptional payload that increases drug delivery efficiency [1-4]. Size, as another benefit that can be controlled precisely from self-assembly provided the possibilities of positive targeting. Controllable size (20 ~ 500 nm) benefits the extended permeation and retention (EPR) and enhances the tumor therapy as reported by several studies [5-8].

Recently, it becomes an attractive trend to enable specialized functionalities on the self-assembled particles due to the tumor tissues’ specific micro-environment, such as low pH, high temperature and re-dox potential [9]. Environment-dependent selective drug release of particles with various structure and sizes pioneers a novel platform in cancer therapy with minimized side-effect and heighten drug delivery efficiency. In this review, we will summary current methods that are utilized in functionalizing self-assembled particles with different structures and sizes.

Amphiphilic block copolymers

Amphiphilic block copolymers are consisted of more than two covalent bond connected blocks with different affinities to solvent. Variable hydrophobicity and packing number of the polymer chains among all the blocks initiate the polymers’ self-assembly and result in particles with diverse morphology and structures, such as micelles, rods and polymersomes. Recent studies have shown the possibility to precisely control the self-assembly structure of block copolymers by targeting at dimensionless packing parameter, p as defined below:

Where v is the volume of the hydrophobic chains, a0 is the optimal head group area, and lc is the length of the hydrophobic tail. The structure of particles can be predicted from the value of p. Spherical micelles are favored when p is below 1/3, micellar rods can form when p is between 1/3 and 1/2 whereas polymersomes are favored when p is greater than 1/2 and less than 1 [10].

More recently, Discher and Eisenberg have attempted to unify the experimental results obtained from different Amphiphilic block copolymers [11-13]. Reasoning from a series of examples drawn from the literature, they proposed a unifying rule for the formation of polymersomes (polymer-based vesicles) in water: i.e. a ratio f of the mass of the hydrophilic part to the total mass 35±10%. An asymmetric molecule with a cylindrical shape and f<50% presumably reflects a certain balance between its hydrated part and a disproportionately large hydrophobic fraction. Finally, molecules with f>45% are expected to form micelles and those with f<23% are expected to self-assemble into inverted structures. Base on this theory, the morphologies of assemblies from Amphiphilic block copolymers can also be expected.

Functionalization of amphiphilic block-copolymers and self-assemblies

It is always challenging to achieve Amphiphilic block copolymers with accurate controlled hydrophobic chain length and the self-assembly behavior. Reversible additionfragmentation chain transfer (RAFT) polymerization is one of the most powerful and versatile methods among the existing controlled polymerizations that provide the possibility to precisely construct the PVCL based block copolymers with well controlled block chain length and composition. Both molecular weight and molecular weight distribution of desired macromolecules can be well controlled by RAFT polymerization.

PH-responsive self-assemblies

Besides the structure control over the block copolymers’ self-assembly, RAFT also provides the possibility to functionalize block copolymers and the related self-assembled particles due to the ease of tuning properties on molecular level with various stimuli-responsiveness, such as pH, redox potential, light and temperature. Muller et al have previously synthesized pHresponsive Amphiphilic block copolymer poly (acrylic acid)- b-polystyrene (PAA-b-PSt) with different hydrophobicity [14]. Different self-assembled structure can be achieved by varying block length, solvent and preparation route. It was reported that as the hydrophobic content of Polystyrene continues increasing, the morphology of self-organized particles transit from spherical micelles, to warm-like micelles and polymersomes when it reaches the highest content. In addition, the formed particles present size increase when the chain length of polystyrene increases along with the structure transition occurs. It shifts from micelles of 26 nm to large polymersomes with 1μm diameter. Similar applications of RAFT were also reported by Charleux and Tam et al resulting in both size and structure adjustable pH-responsive particles [15-17].

Thermo-responsive self-assemblies

Other than pH-responsiveness, temperature response of drug vehicles self-assembled from block copolymers is also an appealing property that can be utilized to advance anti-cancer drug delivery. Temperature sensitivity is one of the most interesting properties in stimuli-responsive polymers. In addition, temperature is one of the safest, the most controllable and achievable external stimuli. Since the temperature responsive polymer segments can be incorporated to either micelle shells or cores, the polymeric micelles can be classified into two categories, i.e. micelles with temperature responsive polymers as hydrophilic shell-forming segments below the LCST and micelles with temperature responsive polymers as hydrophobic core-forming segments above the LCST. It was reported that the elevated temperature (40-42 °C) in tumors will cause the vehicle morphology changes and trigger the cargo release. However, only a few studies on temperatureresponsive particles with various structures have been reported whereas the majority is poly (N-isopropylacrylamide) (PNIPAM) -related system which has inherent limitation in vivo due to the lack of biocompatibility and toxicity after hydrolysis. Compared to PNIPAM related polymersomes, polyvinyl caprolactam (PVCL) exhibits high cell viability and low cytotoxicity making it a strong candidate in biomaterial applications such as drug delivery systems. Recently, PVCL has been utilized to fabricate temperature responsive micelles and polymersomes that have various size ranges and temperature responsiveness. poly(vinyl pyrrolidone)-b-poly(N-vinylcaprolactam) (PVPON-PVCL), polyethylene oxide-b-poly(N-vinylcaprolactam) (PEO-b-PVCL) and poly(N-vinylcaprolactam)-poly(dimethylsiloxane)-poly(Nvinylcaprolactam) (PVCL-PDMS-PVCL) et al have all been developed to form temperature responsive particles with different morphology, structure and sizes [18-20]. Youk et al have applied RAFT polymerization to synthesize Amphiphilic block polymers poly (ε-caprolactone)-b-poly (N-vinylcaprolactam) (PCL-b-PVCL) with controlled thermo-sensitiveness. Repetitive aggregation and dispersion were observed between heating and cooling cycles from 20 to 40 °C with formation of micelles at 55 ± 25 nm. It was also reported that increasing hydrophilic component PVCL dominates the self-assembly process by decreasing the selfassembled particles’ size and shifts the responsiveness toward lower temperature range.

Conclusion and Perspectives

We summarized the recent progress of functional particles’ self-assemblies from Amphiphilic block-copolymers and the control over size and structure. The significant achievements recently people made in controlling functional Amphiphilic block copolymers self-assembly will pave a new way for targeting drug delivery and give strong inspirations to researchers in both academia and industry for exploring new systems in efficient drug delivery. Enhanced therapeutic effects of well-designed particles provide enormous possibilities for scientists to overcome diseases associated with traditional chemotherapy methods. On the other hand, the role of particles’ shape has attracted more attentions in cellular uptake and targeting drug delivery. People utilized inorganic particles in polymer’s self-assembly process and achieved versatile shapes particle. The hybrid particles showed great potential and provide more possibilities for researchers to regulate the properties in self-assembly.

References

1. Gu Y, Liu F, Fang C, Qian Z, Achilefu S (2010) In vivo investigation of pharmacokinetics of model drug: comparison of near infrared technique with high-performance liquid chromatography. In Bios (pp. 75760A-75760A).International Society for Optics and Photonics.
2. Kain V, Liu F, Kozlovskaya V, Ingle KA, Khedkar S, et al. (2016) Resolution Agonist 15-epi-Lipoxin A4 Directs FPR2 to Expedite Healing Phase Post-Myocardial Infarction. The FASEB J 30(1): 302-306.
3. Chen J, Chen H, Cui S, Xue B, Tian J, et al. (2012) Glucosamine derivative modified nanostructured lipid carriers for targeted tumor delivery. J Materials Chemistry 22(12): 5770-5783.
4. Xue B, Deng DW, Cao J, Liu F, Li X, et al. (2012) Synthesis of NAC capped near infrared-emitting CdTeS alloyed quantum dots and application for in vivo early tumor imaging. Dalton Transactions 41(16): 4935-4947.
5. Kim SH, Kaplan JA, Sun Y, Shieh A, Sun HL, et al. (2015) The Self‐Assembly of Anticancer Camptothecin–Dipeptide Nanotubes: A Minimalistic and High Drug Loading Approach to Increased Efficacy. Chemistry–A European J 21(1): 101-105.
6. Liu F, Kozlovskaya V, Zavgorodnya O, Martinez-Lopez C, Catledge S, et al. (2014) Encapsulation of anticancer drug by hydrogen-bonded multilayers of tannic acid. Soft matter 10(46): 9237-9247.
7. Deng D, Zhang W, Chen X, Liu F, Zhang J, et al. (2009) Facile Synthesis of High‐Quality, Water‐Soluble, Near‐Infrared‐Emitting PbS Quantum Dots. European J Inorganic Chem 2009(23): 3440-3446.
8. He Y, Li Z, Simone P, Lodge TP (2006) Self-assembly of block copolymer micelles in an ionic liquid. J Am Chem Soc 128(8): 2745-2750.
9. Mai Y, Eisenberg A (2012) Self-assembly of block copolymers. Chemical Society Reviews 41(18): 5969-5985.
10. Cox J K, Eisenberg A, Lennox RB (1999) Patterned surfaces via selfassembly. Current opinion in colloid & interface science 4(1): 52-59.
11. Srinivas G, Discher DE, Klein ML (2004) Self-assembly and properties of diblock copolymers by coarse-grain molecular dynamics. Nature materials 3(9): 638-644.
12. He WD, Sun XL, Wan WM, Pan CY (2011) Multiple morphologies of PAA-b-PSt assemblies throughout RAFT dispersion polymerization of styrene with PAA Macro-CTA. Macromolecules 44(9): 3358-3365.
13. Yusa S, Fukuda K, Yamamoto T, Ishihara K, Morishima Y (2005) Synthesis of well-defined Amphiphilic block copolymers having phospholipids polymer sequences as a novel biocompatible polymer micelle reagent. Biomacromolecules 6(2): 663-670.
14. Dai S, Ravi P, Tam KC (2008) pH-Responsive polymers: synthesis, properties and applications. Soft Matter 4(3): 435-449.
15. Dai S, Ravi P, Tam KC (2008) pH-Responsive polymers: synthesis, properties and applications. Soft Matter 4(3): 435-449.
16. Rieger J, Osterwinter G, Bui C, Stoffelbach F, Charleux B (2009) Surfactant-free controlled/living radical emulsion (co) polymerization of n-butyl acrylate and methyl methacrylate via RAFT using Amphiphilic poly (ethylene oxide)-based trithiocarbonate chain transfer agents. Macromolecules 42(15): 5518-5525.
17. Verbrugghe S, Laukkanen A, Aseyev V, Tenhu H, Winnik FM (2003) Light scattering and microcalorimetry studies on aqueous solutions of thermo-responsive PVCL-g-PEO copolymers. Polymer 44(22): 6807- 6814.
18. Beija M, Marty JD, Destarac M (2011) Thermo responsive poly (N-vinyl caprolactam)-coated gold nanoparticles: sharp reversible response and easy tunability. Chemical Communications 47(10): 2826-2828.
19. Liang X, Liu F, Kozlovskaya V, Palchak Z, Kharlampieva E (2015) Thermo responsive micelles from double LCST-poly (3-methyl-Nvinylcaprolactam) block copolymers for cancer therapy. ACS Macro Letters 4(3): 308-311.
20. Liu F, Kozlovskaya V, Medipelli S, Xue B, Ahmad F, et al. (2015) Temperature-sensitive polymersomes for controlled delivery of anticancer drugs. Chemistry of Materials 27(23): 7945-7956.
21. Sun Y, Kang C, Zhang A, Liu F, Hu J, et al. (2016) Co-delivery of dualdrugs with nanoparticles to overcome multidrug resistance. European Journal of Biomedical Research 2(2): 12-18.