22.3 Binding Techniques for Biofunctionalization of Nanoparticles
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supramolecular assembly using host–guest interaction by Ma and Zhao [8], binding
of carbohydrate–protein–nanoparticle by Penadés, Davis, and Seeberger [9], binding
of nanoparticles to biomolecules using hydrophobic–hydrophilic interaction by
Chen and Jiang [10], binding using “dock and lock” mechanism by Gong et al.
[11], DNA nanoparticle functionalization by Seeman [12], and self-assembly of
high-affinity protein to nanoparticles by Gurunatha et al. [13].
22.3.3
Encapsulation
Nanoencapsulation is a method of entrapment of nanoparticles, which can be
in any form, i.e. solid, liquid, or gas, inside another shell or matrix made up
of different materials. The particles entrapped in a shell are also referred to as
core/active nanoparticle, which have the conjugated active ingredients. The outer
shell provides selective interaction of nanoparticles with the environment of the
application. It can be fabricated in such a way that the shell remains throughout
the application, or there is a breakdown of the outer shell in response to a stimulus
like pH/temperature change or any enzymatic activity. Several types of material
could be used for shell fabrication. Enclosing matrices are chosen on the basis
of essential properties required for the desired use. Some protein-encapsulating
matrices include albumin, gelatine, lecithin, and legumin. Polysaccharide-based
matrices include starch, alginates, chitosan, dextrin, and gums. There are numer-
ous more examples of matrices used for the encapsulation of nanoparticles like
liposomes, biopolymers, micelles, metal/polymeric/emulsion nanoparticles, den-
drimers, organogels, or various other kinds of functionalized/non-functionalized
nanoparticles. Nanoencapsulation can be done by chemical, physicochemical, or
physico-mechanical technique. The chemical technique follows synthesis through
nucleation and growth, incorporating the building blocks. Encapsulation involving
suspension, emulsion, precipitation, sol–gel, and polymerization are some of the
methods used in chemical encapsulation of nanomaterials. Compared to other
techniques, the chemical technique provides uniform size, high purity, and good
chemical homogeneity. The physicochemical encapsulation technique is based on
both physical and chemical synthesis procedures. Physicochemical encapsulation
includes phase inversion nanoencapsulation, coacervation and phase separation,
inclusion complexes, solid lipid nanoparticles, layer-by-layer deposition, and con-
trolled encapsulation. The physico-mechanical process of encapsulation exploits the
physical properties of nanoparticles and mechanical instrumentation for the entrap-
ment of nanoparticles. Some techniques for physico-mechanical encapsulation
include spray drying, electro-encapsulation, and solvent extraction/evaporation.
Enhanced pollution-degrading capabilities were seen in a comparative study where
alginate polymer-encapsulated nano-zero-valent iron (nZVI) was used. The native
technique was able to remove 43–56% of the pollutant, while 50–75% polycyclic
aromatic hydrocarbons (PAHs) removal was seen using encapsulated nZVI. Encap-
sulation also helps in protecting enzyme-conjugated nanoparticles from protease
attack.