Tripolar Bolalipids as Key Components of Sustained-Release Drug Delivery Systems.

Controlling passive diffusion through an amphiphilic membrane is a key factor for the development of future smart generations of drug delivery systems. It also plays a crucial role in understanding fundamental biological systems through the design of new artificial cell models. We report herein a new concept of bolalipids designed as key components for the control of the membrane's permeability.

Design of light-responsive amphiphilic self-assemblies: A novel application of the photosensitive diazirine moiety.

Diazirine is one of the smallest photo-sensitive moieties discovered to date. When incorporated in the structure of phospholipids, its minimal size has a low impact on the morphology of the resultant liposomes. A DMPC-diazirine analogue was designed and subsequently used to generate liposomes with a lower permeability and a lower phase-transition temperature compared to control DMPC liposomes.

Enhancing the photosensitizing activity of natural flavins: Tuning the heavy-atom effect in the isoalloxazine series.

Structure-photosensitizing activity relationships for a series of flavin analogues were investigated with the final goal of identifying the most potent photosensitizer in these series. The main structural modifications involved the introduction of various halogen atoms in C- and/or C-positions on the isoalloxazine ring. These compounds were synthesized by reacting judiciously-functionalized anilines with alloxan.

Investigating the photosensitization activities of flavins irradiated by blue LEDs.

Due to their ability to easily absorb light and to generate highly reactive species, photosensitizers emerged as promising tools in a wide variety of physico-chemical and biological processes. Natural photosensitizers have the benefit of a life-compatible toxicological profile. Porphyrins and flavins are such examples that already proved their efficiency as photo-dynamic therapeutics.

Flavin-Conjugated Nanobombs: Key Structural Requirements Governing Their Self-Assemblies' Morphologies.

In contrast to artificial molecules, natural photosensitizers have the benefit of excellent toxicity profiles and of life-compatible activating energy ranges. Flavins are such photosensitizers that were selected by nature in a plethora of light-triggered biochemical reactions. Flavin-rich nanoparticles could thus emerge as promising tools in photodynamic therapies and in active-targeting drug delivery.

In Silico Identification of a Key Residue for Substrate Recognition of the Riboflavin Membrane Transporter RFVT3.

Because of its specific physicochemical properties (fluorescence, photosensitizing, and redox reactions), vitamin B2, also called riboflavin (RF), has been generating a lot of interest in the fields of nanotechnology and bioengineering in the last decade. RF, by targeting its riboflavin transporters (RFVTs) overexpressed in some cancers, is particularly used to functionalize nanovectors for anticancer drug delivery. From a physiopathological point of view, an RF deficiency has been implicated in various pathologies, including mendelian diseases.

Photoacoustic imaging of tumor targeting with riboflavin-functionalized theranostic nanocarriers.

Photoacoustic imaging is an emerging method in the molecular imaging field, providing high spatiotemporal resolution and sufficient imaging depths for many clinical applications. Therefore, the aim of this study was to use photoacoustic imaging as a tool to evaluate a riboflavin (RF)-based targeted nanoplatform. RF is internalized by the cells through a specific pathway, and its derivatives were recently shown as promising tumor-targeting vectors for the drug delivery systems.

Amphiphilic Phospholipid-Based Riboflavin Derivatives for Tumor Targeting Nanomedicines.

Riboflavin (RF) is an essential vitamin for cellular metabolism. Recent studies have shown that RF is internalized through RF transporters, which are highly overexpressed by prostate and breast cancer cells, as well as by angiogenic endothelium. Here, we present an optimized synthesis protocol for preparing tailor-made amphiphilic phospholipid-based RF derivatives using phosphoramidite chemistry.

Genotoxic and oxidative responses in coelomocytes of Eisenia fetida and Hediste diversicolor exposed to lipid-coated CdSe/ZnS quantum dots and CdCl2.

The emerging of Quantum Dots utilization in industrial or medicinal fields involved a potentially increase of these nanoparticles in environment. In this work, the genotoxic (comet assay) and oxidative effects (SOD activity, TBARS) of functionalized-QDs and cadmium chloride were investigated on Hediste diversicolor and Eisenia fetida coelomocytes. Results demonstrated that functionalized-QDs (QDNs) and cadmium chloride induced DNA damages through different mechanisms that depended on the nano- or ionic nature of Cd.

Quantum dot lipid oligonucleotide bioconjugates: toward a new anti-microRNA nanoplatform.

The construction of new nanotools is presented here using the example of fluorescent semiconductor nanocrystals, quantum dots (QDs). In this study, the implementation of the new lipid oligonucleotide conjugate-functionalized quantum dots (LON-QDs) is realized in four steps: (i) the synthesis of the lipid oligonucleotide conjugates (LONs), (ii) the encapsulation of QDs by nucleolipids and LONs, (iii) the study of the duplex formation of LON-QDs with the complementary ON partners, and (iv) the cellular uptake of the LON-QD platform and hybridization with the target ONs (microRNA and miR-21).

Formation of supramolecular systems via directed Nucleoside-Lipid recognition.

We report the synthesis of a new series of Ketal Nucleoside Lipids (KNLs) featuring saturated hydrophobic double chains and either adenosine or uridine as nucleosides (KNL(A) and KNL(U), respectively). Physicochemical studies (differential scanning calorimetry, small angle X ray scattering, transmission electronic microscopy, atomic force microscopy, Langmuir isotherm, infrared spectroscopy) show that the KNLs form hydrogels below the main phase transition temperature (Tm), whereas fluid lamellar phases are obtained above T(m). Mixing complementary KNLs affords a new stable Combined Supramolecular Systems (CSSs) due to complementary A-U recognition.

Chemical details on nucleolipid supramolecular architecture: molecular modeling and physicochemical studies.

Nucleolipids are currently under investigation as vectors for oligonucleotides (ON) delivery thanks to their supramolecular organization properties and their ability to develop specific interactions (i.e., stacking and potential Watson and Crick hydrogen bonds) for lipoplexes formation.

Hybrid lipid oligonucleotide conjugates: synthesis, self-assemblies and biomedical applications.

Hybrid lipid oligonucleotide conjugates are finding more and more biotechnological applications. This short critical review highlights their synthesis, supramolecular organization as well as their applications in the field of biotechnology (111 references).

Sensitive liposomes encoded with oligonucleotide amphiphiles: a biocompatible switch.

DNA-tagged liposomes made of DOPC specifically bind to a fluorescently labelled complementary ss-DNA with virtually no influence from the lipid bilayer despite the absence of a linker; depending on an external stimulus, either physical (temperature) or chemical (competitive complementary ON sequences), the liposomes switch between an on and off fluorescent state depending on the location of the probe either at the surface or in the bulk.

Real time imaging of supramolecular assembly formation via programmed nucleolipid recognition.

Supramolecular assembly formation resulting from molecular recognition between complementary nucleolipids has been visualized in real time at the micrometer scale.

Two-dimensional self-assembly and complementary base-pairing between amphiphile nucleotides on graphite.

2D supramolecular structures on HOPG by self-assembly of physisorbed amphiphile nucleotides have been successfully imaged by high resolution STM. The organization of the systems depends on the nature of nucleic bases. In the case of the thymidine derivative a head-to-tail self-assembly is observed, whereas the amphiphile adenosine affords head-to-head nanostructures.