Marie-Christine Jones

Polymeric micelles - a new generation of colloidal drug carriers.

Polymeric micelles have recently emerged as a novel promising colloidal carrier for the targeting of poorly water soluble and amphiphilic drugs. Polymeric micelles are considerably more stable than surfactant micelles and can solubilize substantial amounts of hydrophobic compounds in their inner core. Due to their hydrophilic shell and small size they sometimes exhibit prolonged circulation times in vivo and can accumulate in tumoral tissues. This review examines the chemical nature of polymeric micelles as well as the methods used to characterize them with regard to drug delivery. Special emphasis is put on the determination of critical micelle concentration and on drug loading procedures. Potential medical applications, especially in cancer chemotherapy, are described and discussed.

Polymeric micelles for oral drug delivery.

In the case of chronic therapies, the oral route is often the preferred route for drug administration given its acceptability and convenience. However, various factors which limit drug absorption through the gastro-intestinal (GI) mucosa contribute to restricting the bioavailability of the drug, that is, the actual amount which reaches the bloodstream. Among these factors, poor drug permeability through the GI mucosa and/or low aqueous solubility are of central importance. Polymeric micelles, which form upon self-assembly of amphiphilic macromolecules, can act as vehicles for the oral delivery of these drugs. This manuscript summarizes the literature in relation to the design of these micellar systems and their characterization with respect to drug loading and retention properties as well as the ability to withstand dissociation and drug discharge upon oral administration. Also, the role of certain polymers in improving drug absorption through the GI mucosa, either by increasing membrane permeability to the drug and/or carrier or by inhibiting drug efflux transporters in the GI mucosa, is discussed. Finally, this review reports other drug delivery strategies such as using bioadhesive polymers which may lengthen residence time in the GI tract and promote drug permeation, or rendering the polymeric micelles pH-sensitive in order to ensure drug release from the carrier at its site of absorption.

Reverse polymeric micelles for pharmaceutical applications

Star-shaped (4- to 8-arms) and linear poly(glycidyl methacrylate)s were synthesized by atom transfer radical polymerization as precursors of poly(glycerol methacrylate)s (PG(OH)MAs). The water-soluble PG(OH)MA backbones were modified through the esterification of pendant hydroxyl functions with acyl chlorides (12 to 18 carbons). Alkyated PG(OH)MAs were shown to self-assemble into reverse micelles (RMs) in organic solvents and/or oil. The resulting nanosized aggregates (20-60 nm) were able to reversibly extract anionic dyes from water and solubilise them in an organic phase. Furthermore, the encapsulation of vasopressin, a model peptide, in RMs significantly improved its solubility in an oily vehicle. This observation led to the development of water-free peptide formulations. In vitro release studies showed that the entrapped peptide slowly diffused out of an oily RM solution (<15% in 7 days). The release rate could be significantly increased upon emulsification of the oleaginous phase. In vivo, the subcutaneous administration of loaded RMs to rats significantly prolonged the pharmacological effect of vasopressin (>48 h vs. 8-10 h for an aqueous solution). These results highlight the ability of RMs to act as solubilizers for hydrophilic solutes in organic media, a property that may be exploited for applications in organic chemistry and pharmaceutical technology.

Quantitative assessment of nanoparticle surface hydrophobicity and its influence on pulmonary biocompatibility.

To date, the role of nanoparticle surface hydrophobicity has not been investigated quantitatively in relation to pulmonary biocompatibility. A panel of nanoparticles spanning three different biomaterial types, pegylated lipid nanocapsules, polyvinyl acetate (PVAc) and polystyrene nanoparticles, were characterized for size, surface charge, and stability in biofluids. Surface hydrophobicity of five nanoparticles (50-150nm) was quantified using hydrophobic interaction chromatography (HIC) and classified using a purpose-developed hydrophobicity scale: the HIC index, range from 0.00 (hydrophilic) to 1.00 (hydrophobic). This enabled the relationship between the nanomaterial HIC index value and acute lung inflammation after pulmonary administration to mice to be investigated. The nanomaterials with low HIC index values (between 0.50 and 0.64) elicited little or no inflammation at low (22cm(2)) or high (220cm(2)) nanoparticle surface area doses per animal, whereas equivalent surface area doses of the two nanoparticles with high HIC index values (0.88-0.96) induced neutrophil infiltration, elevation of pro-inflammatory cytokines and adverse histopathology findings. In summary, a HIC index is reported that provides a versatile, discriminatory, and widely available measure of nanoparticle surface hydrophobicity. The avoidance of high (HIC index>~0.8) surface hydrophobicity appears to be important for the design of safe nanomedicines for inhalation therapy.

Reverse micelles from amphiphilic branched polymers

It is well established that micellar structures can form in non-aqueous solutions. The resulting nanostructures, commonly referred to as ‘reverse micelles’, are characterized by a polar core and hydrophobic shell. Such micelles have typically been generated from hydrophobically-modified polar branched polymers and evaluated as solubilizing agents for low molecular-weight anionic dyes. From these studies, critical elements, such as micelle composition and size, have been identified as being determinants of micellar behavior. In this manuscript, the synthesis and characterization of amphiphilic branched polymers that have been used in the preparation of reverse micelles are reviewed, with a particular focus on the factors dictating their ability to interact with hydrophilic guest molecules.

Surface Chemistry of Photoluminescent F8BT Conjugated Polymer Nanoparticles Determines Protein Corona Formation and Internalization by Phagocytic Cells

Conjugated polymer nanoparticles are being developed for a variety of diagnostic and theranostic applications. The conjugated polymer, F8BT, a polyfluorene derivative, was used as a model system to examine the biological behavior of conjugated polymer nanoparticle formulations stabilized with ionic (sodium dodecyl sulfate; F8BT-SDS; ∼207 nm; -31 mV) and nonionic (pegylated 12-hydroxystearate; F8BT-PEG; ∼175 nm; -5 mV) surfactants, and compared with polystyrene nanoparticles of a similar size (PS200; ∼217 nm; -40 mV). F8BT nanoparticles were as hydrophobic as PS200 (hydrophobic interaction chromatography index value: 0.96) and showed evidence of protein corona formation after incubation with serum-containing medium; however, unlike polystyrene, F8BT nanoparticles did not enrich specific proteins onto the nanoparticle surface. J774A.1 macrophage cells internalized approximately ∼20% and ∼60% of the F8BT-SDS and PS200 delivered dose (calculated by the ISDD model) in serum-supplemented and serum-free conditions, respectively, while cell association of F8BT-PEG was minimal (<5% of the delivered dose). F8BT-PEG, however, was more cytotoxic (IC50 4.5 μg cm(-2)) than F8BT-SDS or PS200. The study results highlight that F8BT surface chemistry influences the composition of the protein corona, while the properties of the conjugated polymer nanoparticle surfactant stabilizer used determine particle internalization and biocompatibility profile.

Adenosine monophosphate is elevated in the bronchoalveolar lavage fluid of mice with acute respiratory toxicity induced by nanoparticles with high surface hydrophobicity

Abstract Inhaled nanomaterials present a challenge to traditional methods and understanding of respiratory toxicology. In this study, a non-targeted metabolomics approach was used to investigate relationships between nanoparticle hydrophobicity, inflammatory outcomes and the metabolic fingerprint in bronchoalveolar fluid. Measures of acute lung toxicity were assessed following single-dose intratracheal administration of nanoparticles with varying surface hydrophobicity (i.e. pegylated lipid nanocapsules, polyvinyl acetate nanoparticles and polystyrene beads; listed in order of increasing hydrophobicity). Broncho-alveolar lavage (BAL) fluid was collected from mice exposed to nanoparticles at a surface area dose of 220 cm2 and metabolite fingerprints were acquired via ultra pressure liquid chromatography-mass spectrometry-based metabolomics. Particles with high surface hydrophobicity were pro-inflammatory. Multivariate analysis of the resultant small molecule fingerprints revealed clear discrimination between the vehicle control and polystyrene beads (p < 0.05), as well as between nanoparticles of different surface hydrophobicity (p < 0.0001). Further investigation of the metabolic fingerprints revealed that adenosine monophosphate (AMP) concentration in BAL correlated with neutrophilia (p < 0.01), CXCL1 levels (p < 0.05) and nanoparticle surface hydrophobicity (p < 0.001). Our results suggest that extracellular AMP is an intermediary metabolite involved in adenine nucleotide-regulated neutrophilic inflammation as well as tissue damage, and could potentially be used to monitor nanoparticle-induced responses in the lung following pulmonary administration.

A nano-enabled cancer-specific ITCH RNAi chemotherapy booster for pancreatic cancer

UNLABELLED Gemcitabine is currently the standard therapy for pancreatic cancer. However, growing concerns over gemcitabine resistance mean that new combinatory therapies are required to prevent loss of efficacy with prolonged treatment. Here, we suggest that this could be achieved through co-administration of RNA interference agents targeting the ubiquitin ligase ITCH. Stable anti-ITCH siRNA and shRNA dendriplexes with a desirable safety profile were prepared using generation 3 poly(propylenimine) dendrimers (DAB-Am16). The complexes were efficiently taken up by human pancreatic cancer cells and produced a 40-60% decrease in ITCH RNA and protein expression in vitro (si/shRNA) and in a xenograft model of pancreatic cancer (shRNA). When co-administered with gemcitabine (100 mg/kg/week) at a subtherapeutic dose, treatment with ITCH-shRNA (3x 50 mg/week) was able to fully suppress tumour growth for 17 days, suggesting that downregulation of ITCH mediated by DAB-Am16/shRNA sensitizes pancreatic cancer to gemcitabine in an efficient and specific manner. FROM THE CLINICAL EDITOR Gemcitabine delivery to pancreatic cancer often results in the common problem of drug resistance. This team overcame the problem through co-administration of siRNA and shRNA dendriplexes targeting the ubiquitin ligase ITCH.

Lung inflammation does not affect the clearance kinetics of lipid nanocapsules following pulmonary administration

Lipid nanocapsules (LNCs) are semi-rigid spherical capsules with a triglyceride core that present a promising formulation option for the pulmonary delivery of drugs with poor aqueous solubility. Whilst the biodistribution of LNCs of different size has been studied following intravenous administration, the fate of LNCs following pulmonary delivery has not been reported. We investigated quantitatively whether lung inflammation affects the clearance of 50nm lipid nanocapsules, or is exacerbated by their pulmonary administration. Studies were conducted in mice with lipopolysaccharide-induced lung inflammation compared to healthy controls. Particle deposition and nanocapsule clearance kinetics were measured by single photon emission computed tomography/computed tomography (SPECT/CT) imaging over 48 h. A significantly lower lung dose of (111)In-LNC50 was achieved in the lipopolysaccharide (LPS)-treated animals compared with healthy controls (p<0.001). When normalised to the delivered lung dose, the clearance kinetics of (111)In-LNC50 from the lungs fit a first order model with an elimination half-life of 10.5±0.9h (R(2)=0.995) and 10.6±0.3h (R(2)=1.000) for healthy and inflamed lungs respectively (n=3). In contrast, (111)In-diethylene triamine pentaacetic acid (DTPA), a small hydrophilic molecule, was cleared rapidly from the lungs with the majority of the dose absorbed within 20min of administration. Biodistribution to lungs, stomach-intestine, liver, trachea-throat and blood at the end of the imaging period was unaltered by lung inflammation. This study demonstrated that lung clearance and whole body distribution of lipid nanocapsules were unaffected by the presence of acute lung inflammation.

The oral and intranasal delivery of propofol using chitosan amphiphile nanoparticles

The intravenous anaesthetic propofol acts on gamma amino butyric acid A (GABAA) receptors in the brain. Propofol is often used as a procedural sedative and is also effective (at sub-anaesthetic doses) against intractable migraine and non-migraine headaches. However intravenous propofol is associated with pain on injection and with peripherally mediated hypotension. Here we introduce N-palmitoyl-N-monomethyl-N,N-dimethyl-N,N,N-trimethyl-6-O-glycolchitosan (GCPQ) - propofol nanoparticles and demonstrate, for the first time, that propofol nanoparticles are centrally active via the oral and the intranasal routes. Utilising these routes would abolish the pain on injection and, with respect to the nasal route, reduce peripheral exposure. The nanoparticles are 40-500 nm in size and stable for 21 days at room temperature. Brain drug exposure with orally administered GCPQ-propofol nanoparticles (350 mg kg-1 propofol) was not significantly different from a comparable oral dose of Diprivan. However there was less inter-individual variability with the GCPQ formulation (brain concentration coefficient of variation at the 5 minute peak time point = 1.24 and 0.72 for the Diprivan and GCPQ nanoparticle formulations respectively). Furthermore there was increased inter-individual variability in the pharmacodynamic response to oral Diprivan when compared to oral GCPQ-propofol, as measured by the loss of righting reflex (LORR) time. The LORR time after oral doses of 250 mg kg-1 and 350 mg kg-1 propofol as Diprivan was 15.7±24.6 minutes and 47.2±35.70 minutes respectively while the LORR time after oral 250 mg kg-1 and 350 mg kg-1 GCPQpropofol was 0 minutes and 52.7±22.9 minutes respectively. These data have implications for the safety of oral Diprivan. Via the intranasal route, the LORR time with Diprivan (4mg kg-1 propofol) was not significantly different from that of intranasal saline, while the intranasal administration of GCPQ-propofol formulations (4 mg kg-1 and 8 mg kg-1 propofol) produced significantly higher LORR times than when saline was administered. In summary, these animal data demonstrate that GCPQ-propofol nanoparticles may provide an effective method of administering non-parenteral propofol for potential use in non-anaesthetic settings.