Stable Discoidal Bicelles: Formulation, Characterization, and Functions.

Bicellar mixtures have been used as alignable membrane substrates under a magnetic field applicable for the structural characterization of membrane-associated proteins. Recently, it has shown that bicelles can serve as nanocarriers to effectively deliver hydrophobic therapeutic molecules to cancer cells with a three- to ten-fold enhancement compared to that of liposomes of a chemically identical composition. In this chapter, detailed preparation protocol, common structural characterization methods, the structural stability, the cellular uptake and a few unique functions of bicellar nanodiscs are discussed.

Combinational Effects of Active Targeting, Shape, and Enhanced Permeability and Retention for Cancer Theranostic Nanocarriers.

Combinatory modulation of the physical and biochemical characteristics of nanocarrier delivery systems is an emergent topic in the field of nanomedicine. Here, we studied the combined effects of incorporation of active targeting moieties into nanocarriers and their morphology affecting the enhanced permeation and retention effect for nanomedicine cancer therapy. Self-assembled lipid discoidal and vesicular nanoparticles with low-polydispersity sub-50 nm size range and identical chemical compositions were synthesized, characterized, and correlated with in vitro cancer cellular internalization, in vivo tumor accumulation and cancer treatments. The fact that folate-associated bicelle yields the best outcome is indicative of the preference for discoidal carriers over spherical carriers and the improved targeting efficacy due to the targeting ligand/receptor binding. The approach is successfully adopted to design the nanocarriers for photodynamic therapy, which yields a consistent trend in in vitro and in vivo efficacy: folate nanodiscs > folate vesicles > nonfolate nanodiscs > nonfolate vesicles. Folate discs not only have shown a higher tumor uptake and photothermal therapeutic efficiency, but also minimize skin photosensitivity side effects. The advantages of nanodiscoidal bicelles as nanocarriers, including well-defined size, robust formation, easy encapsulation of hydrophobic molecules (therapeutics and/or diagnostics), easy incorporation of targeting molecules, and low toxicity, enable the scalable manufacturing of a generalized in vivo multimodal delivery platform.

Stable Discoidal Bicelles: A Platform of Lipid Nanocarriers for Cellular Delivery.

Bicellar mixtures have been used as alignable membrane substrates for the structural characterization of membrane-associated proteins. Most recently, it has been shown that bicelles can serve as nanocarriers to effectively deliver hydrophobic molecules to cancer cells with a 3- to 10-fold enhancement compared to that of chemically identical liposomes. In this chapter, a detailed preparation protocol, common structural characterization methods, the structural stability and the cellular uptake of bicellar nanodisks are discussed.

The Morphology of Self-Assembled Lipid-Based Nanoparticles Affects Their Uptake by Cancer Cells.

The morphology of nanoparticles (NPs) has been presumed to play an important role in cellular uptake and in vivo stability. This report experimentally demonstrates such dependence by using two types of uniform-sized self-assembled lipid-based NPs, namely nanodiscs and nanovesicles, composed of identical lipid composition. The morphology is characterized by small angle neutron scattering, dynamic light scattering and transmission electron microscopy. Both NPs have similar bio-stability in serum and cellular cytotoxicity. However, cellular uptake of the nanodiscs at 37 °C is consistently and significantly higher than that of the vesicles according to the uptake results of several human cancer cell lines, i.e., CCRFCEM, KB, and OVCAR-8, indicating a strong morphological dependence of cellular internalization. Further studies on such morphological dependence using CCRF-CEM reveals that vesicles only use Clathrin- and caveolae-mediated endocytic pathways, while nanodiscs also take the additional routes of macropinocytosis and microtubule-mediated endocytosis.