A simple process is developed to fabricate metallo‐supramolecular nanogels (MSNs) by the metallo‐supramolecular‐coordinated interaction between histidine and iron‐meso‐tetraphenylporphin. MSNs are composed of histidine‐modified dextran (DH) and iron‐meso‐tetraphenylporphin (Fe–Por) and exhibit excellent biocompatibility and stability. MSNs show pH responsiveness in the intracellular mildly acidic environment, which has great potential for acid‐triggered drug release delivery. In vitro drug release profiles demonstrate that the pH‐dependent disassembly of MSNs to histidine and Por results in a quicker release rate of loaded‐DOX at pH 5.3, while at pH 7.4 MSNs could hinder the release of loaded‐DOX due to the enhanced stability of MSNs.
To compare the chemotherapeutic efficacy determined by extra‐ and intracellular drug release strategies, poly(ortho ester amide)‐based drug carriers (POEAd‐C) with well‐defined main‐chain lengths, are successfully constructed by a facile method. POEAd‐C3‐doxorubicin (DOX) can be rapidly dissolved to release drug at tumoral extracellular pH (6.5–7.2), while POEAd‐C6‐DOX can rapidly release drug following gradual swelling at intracellular pH (5.0–6.0). In vitro cytotoxicity shows that POEAd‐C3‐DOX exhibits more toxic effect on tumor cells than POEAd‐C6‐DOX at extracellular pH, but POEAd‐C6‐DOX has stronger tumor penetration and inhibition in vitro and in vivo tumor models. So, POEAd‐C6‐DOX with the intracellular drug release strategy has stronger overall chemotherapeutic efficacy than POEAd‐C3‐DOX with extracellular drug release strategy. It is envisioned that these poly(ortho ester amides) can have great potential as drug carriers for efficient chemotherapy with further optimization.
In this contribution, amphiphilic star copolymers (H40‐star‐PCL‐a‐PEG) with an H40 hyperbranched polyester core and poly(ε‐caprolactone)‐a‐poly(ethylene glycol) copolymer arms linked with acetal groups are synthesized using ring‐opening polymerization and a copper (I)‐catalyzed alkyne‐azide cycloaddition click reaction. The acid‐cleavable acetal groups between the hydrophilic and hydrophobic segments of the arms endow the amphiphilic star copolymers with pH responsiveness. In aqueous solution, unimolecular micelles can be formed with good stability and a unique acid degradability, as is desirable for anticancer drug carriers. For the model drug of doxorubicin, the in vitro release behavior, intracellular release, and inhibition of proliferation of HeLa cells show that the acid‐cleavable unimolecular micelles with anticancer activity can be dissociated in an acidic environment and efficiently internalized by HeLa cells. Due to the acid‐cleavable and biodegradable nature, unimolecular micelles from amphiphilic star copolymers are promising for applications in intracellular drug delivery for cancer chemotherapy.
Antimicrobial nanogels, aggregates, and films are prepared by complexation of the antiseptic and bacteriostatic agent chlorhexidine (CHX) for medical and dental applications. A series of α‐, β‐, and γ‐cyclodextrin methacrylate (CD‐MA) containing hydrophobic poly(methyl methacrylate) (PMMA) based nanogels are loaded quantitatively with CHX in aqueous dispersion. The results show that CHX is enhancedly complexed by the use of CD‐MA domains in the particles structure. β‐CD‐MA nanogels present the highest uptake of CHX. Furthermore, it is observed that the uptake of CHX in nanogels is influenced by the hydrophobic PMMA structure. CHX acts as external cross‐linker of nanogels by formation of 1:2 (CHX:CD‐MA) inclusion complexes of two β‐CD‐MA units on the surfaces of two different nanogels. The nanogels adsorb easily onto glass surfaces by physical self‐bonding and formation of a dense crosslinked nanogel film. Biological tests of the applied CHX nanogels with regard to antimicrobial efficiency are successfully performed against Staphylococcus aureus .
Novel biodegradable polymers with specific properties, structures, and tailorable designs or modifications are in great demand. Poly(phosphoester)s with good biocompatibility and degradability, as well as other adjustable properties have been studied widely because of their potential in biomedical applications. To meet more versatile and diverse biomedical applications, a novel multiarm star‐shaped phosphorester triblock copolymer poly(amido amine)‐block‐poly(2‐butynyl phospholane)‐block‐poly(2‐methoxy phospholane) (PAMAM‐PBYP‐PMP) is synthesized via organo‐catalyzed sequential ring‐opening polymerization. Supramolecular micelles with good architectural stability are self‐assembled into uniform spherical morphology in aqueous solution. Doxorubicin (DOX) can be encapsulated into the micelles with efficient loading capacity. A slow and sustained release in the environment of simulated intracellular lysosome (pH 5.0 with phosphodiesterase I) is observed. In addition, the copolymers and DOX‐loaded supramolecular micelles exhibit low cell‐toxicity and excellent anticancer activity toward HeLa cells. As a consequence, this multiarm star‐shaped PAMAM‐PBYP‐PMP has great potential in drug delivery system for tumor treatment.
Thermoresponsive linear polymers and their corresponding aggregates or nanogels typically show similar thermoresponsive profiles. In this study, the authors demonstrate reversible chemical switching between linear polymers and their cross‐linked nanogels. The linear polymers exhibit sharp thermal transitions typical of common thermoresponsive polymers but the cross‐linked nanogels exhibit “linear” thermal transitions over a relatively broad temperature range. The reversible switching between these two different polymer architectures with distinct thermoresponses represents a unique example of how the responsive properties of smart polymers can be significantly manipulated via polymer architecture engineering.
Integration of electrogenic microorganisms remains a challenge in biofuel cell technology. Here, synthetic biocomposites (“artificial biofilms”) are proposed. Bacteria (Shewanella oneidensis ) are embedded in a hydrogel matrix (poly(vinyl alcohol)) via wet‐ and electrospinning, creating fibers and nonwoven gauzes. The bacteria remain viable and metabolically active. The performance is compared to S. oneidensis suspension cultures and “natural” biofilms. While lower than with the suspension cultures, the power output from the fuel cells with the artificial biofilms is higher than with the natural one. Handling, reproducibility, and stability are also better. Artificial biofilms can therefore contribute to resolving fundamental issues of design, scale up, and monosepsis in biofuel cell technology.
The aim of this study is to design a polymeric nanogel system with tailorable degradation behavior. To this end, hydroxyethyl methacrylate‐oligoglycolates‐derivatized poly(hydroxypropyl methacrylamide) (pHPMAm‐Gly‐HEMA) and hydroxyethyl methacrylamide‐oligoglycolates‐derivatized poly(hydroxyethyl methacrylamide) (pHEMAm‐Gly‐HEMAm) are synthesized and characterized. pHEMAm‐Gly‐HEMAm shows faster hydrolysis rates of both carbonate and glycolate esters than the same ester groups of pHPMAm‐Gly‐HEMA. pHEMAm‐Gly‐HEMAm nanogels have tailorable degradation kinetics from 24 h to more than 4 d by varying their crosslink densities. It is shown that the release of a loaded macromolecular model drug is controlled by degradation of nanogels. The nanogels show similar cytocompatibility as PLGA nanoparticles and are therefore considered to be attractive systems for drug delivery.
The ability to tune supramolecular properties such as size, morphology, or metabolic stability is of paramount importance in the field of supramolecular chemistry. Peptide amphiphiles (PAs) are a family of functional self‐assembling biomaterials that have garnered widespread attention due to their broad applicability in medicine. PAs are generally comprised of an amino acid sequence connected to lipid tail(s) allowing them to self‐assemble into supramolecular structures with diverse morphologies. Herein, this study describes the synthesis of a new class of polyamine‐based “hybrid” PAs (PPAs) as novel self‐assembling systems. The described molecules possess diverse polyamine head groups with the goal of tuning physicochemical properties. The findings indicate that small changes in the polyamine head groups result in altered PPA morphologies (nanofibers, micelles, nanoworms). The PPAs present a wide range of physicochemical characteristics, show superior resistance to aggregation, a diverse metabolic profile, and varied assembling kinetics. Most of the PPAs do not show toxicity in the human cells lines evaluated. The PPAs described herein hold promising potential as a safe and nontoxic option for drug delivery, targeting, and tissue engineering applications.
Platinum‐based chemotherapy has been widely used to treat cancers including ovarian cancer; however, it suffers from dose‐limiting toxicity. Judiciously designed drug nanocarriers can enhance the anticancer efficacy of platinum‐based chemotherapy while reducing its systemic toxicity. Herein the authors report a stable and water‐soluble unimolecular nanoparticle constructed from a hydrophilic multi‐arm star block copolymer poly(amidoamine)‐b‐poly(aspartic acid)‐b‐poly(ethylene glycol) (PAMAM‐PAsp‐PEG) conjugated with both cRGD (cyclo(Arg‐Gly‐Asp‐D‐Phe‐Cys) peptide and cyanine5 (Cy5) fluorescent dye as a platinum‐based drug nanocarrier for targeted ovarian cancer therapy. Carboplatin is complexed to the poly(aspartic acid) inner shell via pH‐responsive ion–dipole interactions between carboplatin and the carboxylate groups of poly(aspartic acid). Based on flow cytometry and confocal laser scanning microscopy analyses, cRGD‐conjugated unimolecular nanoparticles exhibit much higher cellular uptake by ovarian cancer cells overexpressing αvβ3 integrin than nontargeted (i.e., cRGD‐lacking) ones. Carboplatin‐complexed cRGD‐conjugated nanoparticles also exhibit higher cytotoxicity than nontargeted nanoparticles as well as free carboplatin, while empty unimolecular nanoparticles show no cytotoxicity. These results indicate that stable unimolecular nanoparticles made of individual hydrophilic multi‐arm star block copolymer molecules conjugate with tumor‐targeting ligands and dyes (i.e., PAMAM‐PAsp‐PEG‐cRGD/Cy5) are promising nanocarriers for platinum‐based anticancer drugs for targeted cancer therapy.
The fabrication of nanodiamond (ND)‐based drug carriers for tumor‐targeted drug delivery is described. The ND clusters with an average size of 52.84 nm are fabricated using a simple fluidic device combined with a precipitation method and then conjugated with folic acid (FA) and doxorubicin (Dox) via carbodiimide chemistry to obtain FA/Dox‐modified ND (FA/Dox‐ND) clusters. Cell culture experiments revealed that KB (folate receptor‐positive) cells are preferentially ablated by FA/Dox‐ND clusters compared to A549 (folate receptor‐negative) cells. In vivo results revealed that FA/Dox‐ND clusters are specifically accumulated in tumor tissues after intravenous injection into tumor‐bearing mice, effectively reducing the volume of tumor. Based on these results, this study suggests that FA/Dox‐ND clusters can be a good candidate as tumor‐targeted nanovehicles for delivery of antitumor drug.
Complementary nucleobase‐functionalized polymeric micelles, a combination of adenine‐thymine (A‐U) base pairs and a blend of hydrophilic–hydrophobic polymer pairs, can be used to construct 3D supramolecular polymer networks; these micelles exhibit excellent self‐assembly ability in aqueous solution, rapid pH‐responsiveness, high drug loading capacity, and triggerable drug release. In this study, a multi‐uracil functionalized poly(ε‐caprolactone) (U‐PCL) and adenine end‐capped difunctional oligomeric poly(ethylene glycol) (BA‐PEG) are successfully developed and show high affinity and specific recognition in solution owing to dynamically reversible A‐U‐induced formation of physical cross‐links. The U‐PCL/BA‐PEG blend system produces supramolecular micelles that can be readily adjusted to provide the desired critical micellization concentration, particle size, and stability. Importantly, in vitro release studies show that doxorubicin (DOX)‐loaded micelles exhibit excellent DOX‐encapsulated stability under physiological conditions. When the pH value of the solution is reduced from 7.4 to 5.0, DOX‐loaded micelles can be rapidly triggered to release encapsulated DOX, suggesting these polymeric micelles represent promising candidate pH‐responsive nanocarriers for controlled‐release drug delivery and pharmaceutical applications.
There is a need for new and smart formulations that will help overcome the limitations of organic dyes used in photodynamic (PDT) and photothermal (PTT) therapy and significantly accelerate their clinical translation. Therefore the aim of this work was to create a responsive nanogel scaffold as a smart vehicle for dye administration. We developed a methodology that enables the conjugation of organic dyes to thermoresponsive nanogels and yields biocompatible, nanometer‐sized products with low polydispersity. The potential of the dye‐nanogel conjugate as a photothermal and photodynamic agent has been demonstrated by an in vitro evaluation with a model human carcinoma cell line. Additionally, confocal cell images showed their cellular uptake profile and their potential for bioimaging and intracellular drug delivery. These conjugates are a promising scaffold as a theranostic agents and will enable further applications in combination with controlled drug release.
In this study, heparin‐mimicking hydrogel thin films are covalently attached onto poly(ether sulfone) membrane surfaces to improve anticoagulant property. The hydrogel films display honeycomb‐like porous structure with well controlled thickness and show long‐term stability. After immobilizing the hydrogel films, the membranes show excellent anticoagulant property confirmed by the activated partial thromboplastin time values exceeding 600 s. Meanwhile, the thrombin time values increase from 20 to 61 s as the sodium allysulfonate proportions increase from 0 to 80 mol%. In vitro investigations of protein adsorption and blood‐related complement activation also confirm that the membranes exhibit super‐anticoagulant property. Furthermore, gentamycin sulfate is loaded into the hydrogel films, and the released drug shows significant inhibition toward E. coli bacteria. It is believed that the surface attached heparin‐mimicking hydrogel thin films may show high potential for the applications in various biological fields, such as blood contacting materials and drug loading materials.
A novel and non‐cytotoxic self‐healing supramolecular elastomer (SE) is synthesized with small‐molecular biological acids by hydrogen‐bonding interactions. The synthesized SEs behave as rubber at room temperature without additional plasticizers or crosslinkers, which is attributed to the phase‐separated structure. The SE material exhibits outstanding self‐healing capability at room temperature and essential non‐cytotoxicity, which makes it a potential candidate for biomedical applications.
Recombinant protein design allows modular protein domains with different functionalities and responsive behaviors to be easily combined. Inclusion of these protein domains can enable recombinant proteins to have complex responses to their environment (e.g., temperature‐triggered aggregation followed by enzyme‐mediated cleavage for drug delivery or pH‐triggered conformational change and self‐assembly leading to structural stabilization by adjacent complementary residues). These “smart” behaviors can be tuned by amino acid identity and sequence, chemical modifications, and addition of other components. A wide variety of domains and peptides have smart behavior. This review focuses on protein designs for self‐assembly or conformational changes due to stimuli such as shifts in temperature or pH.
Polyglycerol nanogels (nPG) have a huge impact in biomedical applications as drug deliverer due to their high biocompability. For such nPG nanogels, particle degradation is widely used as drug delivery method. The knowledge of this degradation process is limited up to date. In this communication, a real time visualization of such a degradation process is presented for pH‐responsive nPG nanogels via atomic force microscopy (AFM) under ambient and in liquid conditions. The particle height plays a major role in the degradation process and decays exponentially in the beginning of this process. The particle width increases during the process indicating a “decross‐linking” step of the particles into their starting monomers. Measurements under ambient conditions confirm this assumption and provide further insight in the “decross‐linking” step of the nanogels into individual dendritic particles. The present work gives a detailed insight in the particle degradation process, which is essential for further progress for the development of new drug delivery systems.
In this study, double‐emulsion capsules (DECs) capable of concealing drug‐incorporated targeted‐supermolecules are developed to achieve “on‐demand” supermolecule release and enhanced sequential targeting for magneto‐chemotherapy. These water‐in‐oil‐in‐water DECs less than 200 nm in diameter are synthesized using a single component of PVA (polyvinyl alcohol) polymer and the magnetic nanoparticles, which are capable of encapsulating large quantities of targeted supermolecules composed of palitaxel‐incorporated beta‐cyclodextrin decorated by hyaluronic acid (HA, a CD44‐targeting ligand) in the watery core. The release profiles (slow, sustained and burst release) of the targeted supermolecules can be directly controlled by regulating the high‐frequency magnetic field (HFMF) and polymer conformation without sacrificing the targeting ability. Through an intravenous injection, the positive targeting of the supermolecules exhibited a 20‐fold increase in tumor accumulation via the passive targeting and delivery of DECs followed by positive targeting of the supermolecules. Moreover, this dual‐targeting drug‐incorporated supermolecular delivery vehicle at the tumor site combined with magneto‐thermal therapy suppressed the cancer growth more efficiently than treatment with either drug or supermolecule alone.
By anchoring alkynylplatinum(II) terpyridine molecular tweezer/pyrene recognition motif on the chain‐ends of telechelic polycaprolactone, high‐molecular‐weight supramolecular polymers have been successfully constructed via noncovalent chain extension, which demonstrate fascinating rheological and thermal properties. Moreover, the resulting assemblies exhibit interesting temperature‐ and solvent‐responsive behaviors, which are promising for the development of adaptive functional materials.
Polysaccharides are abundant in nature, renewable, nontoxic, and intrinsically biodegradable. They possess a high level of functional groups including hydroxyl, amino, and carboxylic acid groups. These functional groups can be utilized for further modification of polysaccharides with small molecules, polymers, and crosslinkers; the modified polysaccharides have been used as effective building blocks in fabricating novel biomaterials for various biomedical applications such as drug delivery carriers, cell‐encapsulating biomaterials, and tissue engineering scaffolds. This review describes recent strategies to modify polysaccharides for the development of polysaccharide‐based biomaterials; typically self‐assembled micelles, crosslinked microgels/nanogels, three‐dimensional hydrogels, and fibrous meshes. In addition, the outlook is briefly discussed on the important aspects for the current and future development of polysaccharide‐based biomaterials, particularly tumor‐targeting intracellular drug delivery nanocarriers.
下载免费PDF全文