Polymers have played an integral role in the advancement of drug delivery technology by providing controlled release of therapeutic agents in constant doses over long periods, cyclic dosage, and tunable release of both hydrophilic and hydrophobic drugs. From early beginnings using off-the-shelf materials, the field has grown tremendously, driven in part by the innovations of chemical engineers. Modern advances in drug delivery are now predicated upon the rational design of polymers tailored for specific cargo and engineered to exert distinct biological functions. In this review, we highlight the fundamental drug delivery systems and their mathematical foundations and discuss the physiological barriers to drug delivery. We review the origins and applications of stimuli-responsive polymer systems and polymer therapeutics such as polymer-protein and polymer-drug conjugates. The latest developments in polymers capable of molecular recognition or directing intracellular delivery are surveyed to illustrate areas of research advancing the frontiers of drug delivery.
CONSPECTUS The ability to non-invasively monitor and treat physiological conditions within the human body has been an aspiration of researchers and medical professionals for decades. The emergences of nanotechnology opened up new possibilities for effective vehicles that could accomplish non-invasive detection of diseases and localized treatment systems to be developed. In turn, extensive research efforts have been spent on the development of imaging moiety that could be used to seek out specific diseased conditions and can be monitored with convention clinical imaging modalities. Nanoscale detection agents like these have the potential to increase early detection of pathophysiological conditions because they have the capability to detect abnormal cells before they even develop into diseased tissue and/or tumors. Once the diseased cells are detected it would be constructive to just be able to treat them simultaneously. From here, the concept of multifunctional carriers that could target, detect, and treat diseased cells emerged. The term “theranostics” has been created to describe this promising area of research that focuses on the combination of diagnostic detection agents with therapeutic drug delivery carriers. Targeted theranostic nanocarriers offer an attractive improvement to disease treatment because of their ability to simultaneously diagnose, image, and treat at targeted diseased sites. Research efforts in the field of theranostics encompass a broad variety of drug delivery vehicles, detection agents, and targeting modalities for the development of an all-in-one, localized, diagnostic and treatment system. Nanotheranostic systems that utilize metallic or magnetic imaging nanoparticles have the added capability to be used as thermal therapeutic systems. This review aims to explore recent advancements in the field of nanotheranostics and the various fundamental components of an effective theranostic carrier.
Polymeric nanoparticles are emerging as an attractive treatment options for cancer due to their favorable size distribution, drug carrying capacity, and tunable properties. In particular, intelligent nanoparticles that respond to biological cues are of interest because of their ability to provide controlled release at a specific site. Tumor sites display abnormal pH profiles and pathophysiology that can be exploited to provide localized release. In this expert opinion, we discuss passive and active targeting of nanoparticles and several classes of pH-responsive nanoparticles.
As stem cells are a cornerstone of regenerative medicine, research efforts have been extensively focused on controlling their self-renewal and differentiation. It is well known that stem cells are tightly regulated by a combination of physical and chemical factors from their complex extracellular surroundings; thus, conventional cell culture approaches based purely on using soluble factors to direct stem cell fate have resulted in limited success. To account for the complexities of native stem-cell niches, biomaterials are actively investigated as artificial extracellular matrices in order to mimic the natural microenvironment. This Perspective highlights important areas related to the design of biomaterials to control stem cell behavior, such as cell-responsive ligands, mechanical signals, and delivery of soluble factors.
Polymerization of multifunctional acrylate monomers generates crosslinked polymers that are noted for their mechanical strength, thermal stability, and chemical resistance. A common reactive diluent to photopolymerizable formulations is N‐vinyl pyrrolidone (NVP), which is known to reduce the inhibition of free radical photopolymerization by atmospheric oxygen. In this work, the copolymerization behavior of NVP was examined in acrylate monomers with two to five functional groups. At concentrations as low as 2 wt %, NVP increases the polymerization rate in copolymerization with multifunctional acrylate monomer. The relative rate enhancement associated with adding NVP increases dramatically as the number of acrylate double bonds changes from two to five. The influence of NVP on polymerization kinetics is related to synergistic cross‐propagation between NVP and acrylate monomer, which becomes increasingly favorable with diffusion limitations. This synergy extends bimolecular termination into higher double bond conversion through reaction diffusion controlled termination. Copolymerizing concentrations of 5–30 DB% NVP with diacrylate or pentaacrylate monomer also increases Young's modulus and the glass transition temperature (Tg) in comparison to neat acrylate polymers. © 2007 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 45: 4062–4073, 2007
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