Nanopharmaceutical Advanced Delivery Systems. Группа авторов

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СКАЧАТЬ (natural or synthetic), lipids, or metals are used in the preparation of nanoparticulate carriers, which impart characteristic properties to these carriers. The composition and method of preparation of nanocarriers define the micromeritics, surface morphology, chemical properties, mechanical properties, magnetic properties, conductivity, and stability [1] Owing to their nanosize, these carriers can be transported via active or passive mechanisms across the biological barriers/tissues/cells and deliver drug at the target site [2, 3]. Endocytic absorption of nanocarriers is one such mechanism that results in improved bioavailability of drugs, especially the poorly soluble ones. Alongside drugs, nanocarriers are also being used for delivery of genetic material, viz. DNA or RNA [5].

2.2 Classification of Nanoparticulate Carriers

Broadly, the nanoparticulate carriers (Figure 2.1) can be categorized as lipid-based systems, micelles, thernostics, polymeric carriers, and self-emulsifying drug delivery systems (SEDDSs) (Table 2.1a). The lipid-based systems consist of concentric assemblies of one or more lipid bilayers, formed from amphiphilic building blocks in the presence of water. Liposomes, solid lipid nanoparticles (SLNs), nanolipid carriers (NLCs), etc. belong to this category. SEDDSs correspond to the emulsion-based lipidic systems prepared using surface active agents that self-emulsify in the gastrointestinal tract. Micelles, reverse micelles, etc. employ micellar solubilization of drug in the aqueous phase. Each of these categories has been briefly discussed in the following sections. The list and the classification, though exhaustive, are not limited. Various parameters need to be considered while choosing the carrier system for drug delivery, viz. the interactive forces between the nanocarriers and the biological environment, morphology of the target tissue, conductivity and mechanical properties, composition, size and surface characteristics, drug loading and drug retention capacity, and mechanism of release of drug from the carriers. Recently, due to non-responsiveness to the conventional treatment therapy, application of nanocarriers for the treatment of tuberculosis is also being proposed. Table 2.1b mentions various types of nanoparticulate carriers that are being studied for treatment of tuberculosis.

      2.2.1 Lipid-Based Nanocarriers

Liposomes, solid lipid nanoparticles (SLNs), nanolipid carriers (NLCs), phytosomes, etc., are lipid-based nanocarriers. The functionality of lipid-based carrier systems is based on the type and arrangement of the constituent lipids [11, 12]. Both solid and liquid lipids can be used in the preparation of these carrier systems. Alec Bangham discovered liposomes in early 1960s and defined them as vesicular structures consisting of bilayers of phospholipids and hydrophilic aqueous compartment(s) arranged concentrically [13]. The fluidity of the bilayer depends on the degree of saturation of phospholipids used in the preparation of liposomes. Relatively rigid and stable bilayers are formed by saturated phospholipids with long acyl chains (e.g., dipalmitoylphosphatidylcholine) in comparison to those formed using unsaturated lipids like phosphatidylcholine from natural sources (egg or soybean phosphatidylcholine) [14].

Figure 2.1 Diagrammatic representation of various nanoparticulate carriers: (a) liposome; (b) gold nanoparticle (GNP); (c) dendrimers; (d) quantum dots; (e) solid lipid nanoparticle (SLN); (f) nanostructured lipid carriers (NLC); (g) nanoemulsion; (h) micelles; (i) polymeric nanoparticle (nanocapsules); (j) polymeric nanoparticle (nanospheres); (k) nanoscaffolds; and (l) inverse micelle.

Table 2.1a Classification of nanoparticulate carrier systems.

Nanoparticulate carrier systems
Lipid-based systems	Micellar systems	Thernostics	Polymer-based systems	Self-emulsifying drug delivery systems
LiposomesSolid lipid nanoparticlesNanolipid carriers pH-sensitive lipid carriersThermo-responsive lipid carriers	Micelles	Gold nanoparticlesIron oxide nanoparticlesQuantum dots	Polymeric nanoparticles	Self-emulsifying drug delivery systems (SEDDSs)Self-micro-emulsifying drug delivery systems (SMEDDSs)

Table 2.1b Targeted treatment of tuberculosis using various nano-carrier-based drug delivery system.

Nanoparticulate carriers	Mechanism of action	Effect	References
Chitosan-based nanoparticles (CNPs)	Cellular uptake and upregulate expression of CD-80/86/40/MHC-II molecule on RAW264.7 cells	ROS generation and oxidative stress may lead to DNA damage	[6]
Ag85B-ESAT6-PLGA nanoparticle	Internalized by the THP-1 human macrophages increase in the production of total serum IgG, IFNγ, and TNFα cytokine levels	Immunomodulation and protection against Mtb	[7]
Pep-H conjugated gold nanoparticles (Pep-H-AuNPs)	Antimycobacterial activity against in vitro active as well as dormant tubercle bacilli	Pep-H showed marked reduction in intracellular mycobacterial growth & modulate host immune system	[8]
SPIO-MtbsAb-nanoparticles	Endocytosis	Target mycobacterial antigen and diagnose extrapulmonary TB	[9]
G5 RIF-EDA-PPI mannosylated dendrimer	Inhibition of the subunit of the bacterial RNA polymerase, which inhibits gene transcription	Increase in the cellular uptake of RIF-loaded mannosylated PPI dendrimers in alveolar macrophages (AM)	[10]

Depending on the number of lipid bilayers, the liposomes can be classified as unilamellar vesicles (ULVs) or multilamellar vesicles (MLVs). ULVs consist of a single lipid bilayer (50–250 nm in diameter) with a large aqueous core, providing a suitable site for loading of hydrophilic drugs. Having an onion-peel arrangement of concentric lipid bilayers up to 5 μm in diameter, MLVs can be used to incorporate lipid-soluble drugs in higher concentrations [15]. Based on the lipid concentration present in the liposomes, rate and extent of drug release vary, the fastest being from ULVs. The liposomes are prepared most commonly by thin-film hydration method; however, СКАЧАТЬ