nanogels

A nanogel is a polymer-based, crosslinked hydrogel particle on the sub-micron scale. These complex networks of polymers present a unique opportunity in the field of drug delivery at the intersection of nanoparticles and hydrogel synthesis. Nanogels can be natural, synthetic, or a combination of the two and have a high degree of tunability in terms of their size, shape, surface functionalization, and degradation mechanisms. Given these inherent characteristics in addition to their biocompatibility and capacity to encapsulate small drugs and molecules, nanogels are a promising strategy to treat disease and dysfunction by serving as delivery vehicles capable of navigating across challenging physiological barriers within the body. Nanogels are not to be confused with nanogel aerogel, a lightweight thermal insulator, or with nanocomposite hydrogels (NC gels), which are nanomaterial-filled, hydrated, polymeric networks that exhibit higher elasticity and strength relative to traditionally made hydrogels. ==Synthesis== The synthesis of nanogels can be achieved using a vast array of different methods. However, two critical steps typically included in each method are polymerization and crosslinking, with physical and chemical crosslinking the most common. These steps can be completed concomitantly or in sequential order depending on the synthesis method and eventual nanogel application. Here, several different synthesis mechanisms are described briefly. thumb|713x713px|Graphical representation of seven different methods of synthesizing polymeric nanogels. ===Desolvation/coacervation and precipitation=== In desolvation or coacervation, a non-solvent is added to a homogeneous polymer solution to produce individual, nanosized polymer complexes dispersed in the same solution. These complexes then undergo crosslinking to form nanogels with surface functionalization an optional next step. In precipitation, initiators and crosslinking agents are added to a homogenous monomer solution to induce a polymerization reaction. When the polymer chain reaches the desired length, the reaction is halted and a polymer colloidal suspension is formed. Surfactants are the final addition to produce nanosized polymers. ===Electrostatic and hydrophobic interactions=== Electrostatic interactions can form nanogels through the combination of anionic and cationic polymers in an aqueous solution. The size and surface charge of the resulting nanogels can be modulated by changing the molecular weight or the charge ratio of the two different polymers. Ionotropic gelation can also leverage electrostatic interactions between multivalent anions and cations to form nanogels. Hydrophobic interactions rely heavily on physical crosslinking to form nanogels. In this method, hydrophobic groups are added to hydrophilic polymers in an aqueous solution to induce their self-assembly into nanogels. When thiolated polymers (thiomers) are used for this preparation process, nanogels can be further stabilized by the formation of inter- and intrachain disulfide bonds due to oxidation. In the following the oppositely charged oligo- or polymers can even be removed. ===Inverse-emulsion=== Inverse-emulsion, or reverse miniemulsion, requires an organic solvent and a surfactant or emulsifying agent. Nanosized droplets are produced when an aqueous monomer solution is dispersed in the organic solvent in the presence of the surfactant or emulsifying agent. Upon removal of the organic solvent and further chemical and physical crosslinking of the droplets, nanogels are formed. The size of nanogels synthesized using this method can vary greatly depending on the type of surfactant and reaction medium used. Purifying nanogels produced using an emulsifying agent may also pose a challenge. ===Microtemplate polymerization=== The addition of a monomer precursor solution and crosslinking agent to a microtemplate, or mold-type device, can initiate polymerization and the formation of nanogels. This method can be used to create nanogels in specific shapes and load them with various small molecules. Lithographic microtemplate polymerization is a similar process that uses a photoinitiator and light to trigger the formation of nanogels. Lithographic microtemplate polymerization can produce smaller nanogels on a length scale of 700 nm are most effective, such as indocyanine green, but encounter limitations with reduced circulation time and nonspecific interactions with other biological factors that affect the fluorescence. pH-sensitive nanogels with functionalized surface receptors to target cancer cells were loaded with a fluorescent dye that was only released upon endocytosis. These nanogels successfully generated a fluorescent signal from within the cancer cells and many other groups have developed similar technologies.

===Regenerative medicine=== thumb|516x516px|Various applications of nanogels in regenerative medicine contexts including as injectable delivery vehicles and as components of implantable polymeric scaffolds. ====Wound healing==== Nanogels are a promising technology being explored to aid in the wound healing process. Given their ability to encapsulate various types of cargo, nanogels can strategically deliver anti-inflammatory agents, antimicrobial drugs, and necessary growth factors to facilitate new tissue growth and blood vessel formation. Chitosan-based nanogels have demonstrated an improved wound healing effect in previous studies. Chitosan-based nanogels encapsulating interleukin-2 were successfully used to stimulate the immune system and advance the wound healing process. Additionally, chitosan-based nanogels carrying an antibiotic, silver sulfadiazine, were found to decrease the size of second-degree burns in one in vivo study. In another study, silver-loaded nanogels were synthesized in a natural polymer-based solution containing aloe vera, and the presence of aloe vera led to increased healing and a decrease in wound size. With the goal of preventing infection and accelerating the healing process, one group has also published a new nanogel design consisting of an encapsulating core and a functionalized outer surface capable of targeting bacteria present in wounds.