There has been considerable interest in the application of photochromism to photo-responsive systems which has led to the development of new tailored smart materials for photonics and biomedical fields. Within a polymeric matrix photochromic isomerizations can be stimulated by light to reversibly alter the physical and chemical properties of a material such as LC phase, shape, surface wettability, permeability, solubility, self-assembly, size and fluorescence. The underlying principles behind photoresponsive behavior, subsequent applications and relevant examples are discussed in this review.
Reversible
photocycloaddition reactions have previously been employed
in chemical cross-linking for the preparation of biomaterial scaffolds.
However, the processes require activation by high-energy UV light,
rendering them unsuitable for modification in biological environments.
Here we demonstrate that the [2 + 2] photocycloaddition of styrylpyrene
can be activated by visible light at λ = 400–500 nm,
enabling rapid and effective conjugation and cross-linking of poly(ethylene
glycol) (PEG) in water and under mild irradiation conditions (I = 20 mW cm–2). Notably, the reversion
of the cycloaddition can be triggered by low-energy UV light at λ
= 340 nm, which allows for efficient cleavage of the dimer adduct.
Using this wavelength-gated reversible photochemical reaction we are
able to prepare PEG hydrogels and modulate their mechanical properties
in a bidirectional manner. We also demonstrate healing of the fractured
hydrogel by external light triggers. Furthermore, we show that human
mesenchymal stem cells can be encapsulated within the gels with high
viability post encapsulation. This photochemical approach is therefore
anticipated to be highly useful in studies of cell mechanotransduction,
with relevance to disease progression and tissue regeneration.
RAFT polymerization was used to prepare copolymers of acrylic acid (AA) and styrene (STY) with mole fractions of STY (F STY ) ranging from 0.1 to 0.3 and targeted degrees of polymerization between 50 and 150. The high reactivity of AA-terminal radicals towards STY in this system (r AA ¼ 0.082) resulted in the spontaneous formation of composition gradients, resulting in polymers with block-like structures comprising a STY-rich segment, a relatively short transitional segment, and a segment of AA homopolymer. Atomic force microscopy analysis of thin films of the copolymer revealed phase separated structures which developed after exposure to water. Dynamic light scattering measurements showed pH-responsive amphiphilicity that resulted in dissolved polymer at neutral and basic pH and self-assembly in weakly acidic solutions.
Hydrogels are often employed as temporary platforms for cell proliferation and tissue organization in vitro. Researchers have incorporated photodegradable moieties into synthetic polymeric hydrogels as a means of achieving spatiotemporal control over material properties. In this study protein-based photodegradable hydrogels composed of methacrylated gelatin (GelMA) and a crosslinker containing o-nitrobenzyl ester groups have been developed. The hydrogels are able to degrade rapidly and specifically in response to UV light and can be photopatterned to a variety of shapes and dimensions in a one-step process. Micropatterned photodegradable hydrogels are shown to improve cell distribution, alignment and beating regularity of cultured neonatal rat cardiomyocytes. Overall this work introduces a new class of photodegradable hydrogel based on natural and biofunctional polymers as cell culture substrates for improving cellular organization and function.
Cholesterol is a ubiquitous molecule in biological systems, and in particular plays various important roles in mammalian cellular processes. The presence of cholesterol is integral to the structure and behavior of biological membranes, and profoundly influences membrane involvement in cellular mechanisms. This review focuses on the incorporation of cholesterol into synthetic nanomaterials and assemblies, focusing on LC phase behavior, morphology/self-organization and hydrophobic interactions, all important factors in the design of nanomedicines. We highlight cholesteryl conjugates, liposomes and polymeric micelles, focusing on self-assembly capabilities, drug encapsulation and intracellular delivery. An area of considerable interest identified in this review is the use of cholesteryl-functional vectors to deliver drugs or nucleic acids. Such applications depend on the ability of the nanoparticle carrier to associate with both the cellular and endosomal membrane.
We report the synthesis of poly(methacrylic acid)-co-(oleyl methacrylate) with three different amounts of oleyl methacrylate and compare the ability of these polymers with that of poly(methacrylic acid)-co-(cholesteryl methacrylate) (PMA(c)) to noncovalently anchor liposomes to polymer layers. We subsequently assembled ∼1 μm diameter PMA(c)-based capsosomes, polymer hydrogel capsules that contain up to ∼2000 liposomal subcompartments, and investigate the potential of these carriers to deliver water-insoluble drugs by encapsulating two different antitumor compounds, thiocoraline or paclitaxel, into the liposomes. The viability of lung cancer cells is used to substantiate the cargo concentration-dependent activity of the capsosomes. These findings cover several crucial aspects for the application of capsosomes as potential drug delivery vehicles.
Naphthopyran polymer conjugates of various rigidities were synthesized by atom transfer radical polymerization (ATRP), and their photochromic properties were tested within a rigid host matrix. Broad tuning of photochromic kinetics was displayed as a result of polymer conjugation because of its ability to alter the local environment of the naphthopyran within the host. End-functionalized conjugates, synthesized from a naphthopyran-functionalized ATRP initiator, allowed systematic tuning of kinetics via modulation of chain length of attached polymer. Reducing the rigidity of the conjugate resulted in an acceleration of kinetics and an increase in colorability. Pronounced chain lengths of poly(methyl methacrylate) (>18 000 g/mol) were required for decoloration kinetics to be effectively depressed compared with an unconjugated naphthopyran control. Random in-chain incorporation of the naphthopyran was afforded by copolymers made with naphthopyran-functionalized monomers. At the expense of a defined placement of the dye moiety with respect to the conjugated polymer chain, such conjugates displayed a pronounced ability to influence the kinetics. Persistent color due to thermally stable isomer populations was observed for all samples and found to be uninfluenced by polymer conjugation.
Naphthopyran-poly(n-butyl acrylate) conjugates with different geometries were assembled using ATRP. First, within a rigid lens matrix, an investigation of the photochromic behavior of various poly(n-butyl acrylate), p(n-BA), homopolymers showed that midplacement of a single dye moiety, made possible using a Y-branching difunctional photochromic initiator, gave superior fade kinetics per chain length of conjugated polymer compared to end-functionalized homopolymers. Furthermore, having the dye pendant from the chain opposed to directly within the chain was also found to be advantageous. Fading kinetics became faster when chain length was increased, except in the case of linear random copolymers made by copolymerization of n-butyl acrylate with a naphthopyran acrylate. A gradient copolymer made with a nonphotochromic difunctional initiator and a naphthopyran methacrylate displayed superior kinetics. Films consisting of ABA triblock copolymers, incorporating the photochromic in the middle of a soft p(n-BA) section, gave slower switching speeds compared to lens samples, with responses that were highly tunable and dependent on the amount of soft section inhabited by the photochromic moiety. Scheme 2. Atom Transfer Radical Polymerization Synthesis of Naphthopyran-Poly(n-butyl acrylate) Conjugates Displaying Molecular Weights of Purified Samples Tested in Survey (dNbpy = 4,4 0 -Dinonyl-2,2 0 -bipyridine)
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.