Lomustine Nanoparticles Enable Both Bone Marrow Sparing and High Brain Drug Levels - A Strategy for Brain Cancer Treatments.

PURPOSE: The blood brain barrier compromises glioblastoma chemotherapy. However high blood concentrations of lipophilic, alkylating drugs result in brain uptake, but cause myelosuppression. We hypothesised that nanoparticles could achieve therapeutic brain concentrations without dose-limiting myelosuppression. METHODS: Mice were dosed with either intravenous lomustine Molecular Envelope Technology (MET) nanoparticles (13 mg kg(-1)) or ethanolic lomustine (6.5 mg kg(-1)) and tissues analysed. Efficacy was assessed in an orthotopic U-87 MG glioblastoma model, following intravenous MET lomustine (daily 13 mg kg(-1)) or ethanolic lomustine (daily 1.2 mg kg(-1) - the highest repeated dose possible). Myelosuppression and MET particle macrophage uptake were also investigated. RESULTS: The MET formulation resulted in modest brain targeting (brain/ bone AUC0-4h ratios for MET and ethanolic lomustine = 0.90 and 0.53 respectively and brain/ liver AUC0-4h ratios for MET and ethanolic lomustine = 0.24 and 0.15 respectively). The MET formulation significantly increased mice (U-87 MG tumours) survival times; with MET lomustine, ethanolic lomustine and untreated mean survival times of 33.2, 22.5 and 21.3 days respectively and there were no material treatment-related differences in blood and femoral cell counts. Macrophage uptake is slower for MET nanoparticles than for liposomes. CONCLUSIONS: Particulate drug formulations improved brain tumour therapy without major bone marrow toxicity.

Physical characterisation and long-term stability studies on quaternary ammonium palmitoyl glycol chitosan (GCPQ)--a new drug delivery polymer.

N-palmitoyl-N-monomethyl-N,N-dimethyl-N,N,N-trimethyl-6-O-glycolchitosan (GCPQ) is a self-assembling polymer, which enables the oral bioavailability of peptide and hydrophobic drugs. In preparation for clinical testing, here we examine GCPQ's synthesis reproducibility, pKa, thermal, and rheological properties. GCPQ was synthesised by acid degradation of glycol chitosan (GC), reaction with palmitic acid N-hydroxysuccinimide (PNS) and methylation. A GC monomer, PNS molar feed ratio of 0.92 together with a gravimetric feed ratio for N-palmitoyl-6-O-glycolchitosan, methyl iodide of 3.3, reproducibly produces GCPQ48 (Mw = 19.9 ± 9.9 kDa, Mn = 13.1 ± 2.4 kDa, mol % palmitoylation = 23 ± 2.7, mol % quaternisation = 10 ± 0.23, n = 56). GCPQ48 decomposes at 218 ± 4.3 °C, is glassy at room temperature (Tg = 164.4 ± 8.5 °C), is a weak base (pKa = 5.99 ± 0.15), and produces micellar dispersions at neutral pH. Below a concentration of 0.07 g mL(-1) , GCPQ48 dispersions showed Newtonian rheological behaviour but at higher concentrations, the polymer undergoes shear thinning because of the chain disentanglement at high shear rates. GCPQ48 forms a network of micelles and concentrated (0.09 g mL(-1) ) dispersions are viscoelastic, with the storage modulus exceeding the loss modulus at high frequencies. Solid GCPQ48 was stable when stored at room temperature for 18 months.

Claw amphiphiles with a dendrimer core: nanoparticle stability and drug encapsulation are directly proportional to the number of digits.

There are numerous pharmaceutical, food, and consumer product applications requiring the incorporation of hydrophobic solutes within aqueous media. Often amphiphiles and/or polymers are used to produce encapsulating nanostructures. Because the encapsulation efficiencies of these nanostructures directly impact on the process or product, it is often desirable to optimize this parameter. To produce these advanced functional materials, we hypothesized that an amphiphile with a claw shape would favor polymer aggregation into nanoparticles and hydrophobic compound encapsulation. Claw amphiphiles were prepared by attaching one end of comb-shaped chitosan amphiphile chains [N,N,N-trimethyl, N,N-dimethyl, N-monomethyl, N-palmitoyl, N-acetyl, 6-O-glycol chitosan (GCPQA)] to a central dendrimer core [generation 3 diaminobutane poly(propylenimine) dendrimer (DAB)] to give DAB-GCPQA. The linear chitosan amphiphile (GCPQA) forms the digits of the claw. These claw amphiphiles were very stable and had a high encapsulating efficiency. DAB-GCPQAs (Mn = 30 and 70 kDa) had extremely low critical micelle concentrations [CMCs = 0.43 µg mL(-1) (13 nM) and 0.093 µg mL(-1) (0.9 nM), respectively], and their CMCs were lower than that of linear GCPQA [Mn = 14 kDa, CMC = 0.77 µg mL(-1) (38 nM)]. The claw amphiphile CMCs decreased linearly with the number of digits (r(2) = 0.98), and drug encapsulation (hydrophobic drug propofol) in 4 mg mL(-1) dispersions of the amphiphiles increased linearly (r(2) = 0.94) with the number of digits. DAB-GCPQA70 (4 mg mL(-1), 0.058 mM) encapsulated propofol (7.3 mg mL(-1), 40 mM). Finally, despite their stability, claw amphiphile nanoparticles are able to release the encapsulated drug in vivo, as shown with the claw amphiphile-propofol formulations in a murine loss of righting reflex model.

Polyamine aza-cyclic compounds demonstrate anti-proliferative activity in vitro but fail to control tumour growth in vivo.

Cationic polyamines such as the poly(propylenimine) dendrimers (DAB16) are anti-tumour agents (Dufes et al., 2005, Cancer Res 65:8079-8084). Their mechanism of action is poorly understood, but the lack of in vivo toxicity suggests cancer specificity. To explore this polyamine pharmacophore we cross-linked the aza-cyclic compound, hexacyclen, with 1,4-dibromobutane or 1,8-dibromooctane to yield the polyamines [poly(butylhexacyclen)--CL4] or [poly(octylhexacyclen)--CL8] respectively, both free of primary amines. We characterised the compounds and their respective nanoparticles and examined their interaction with the putative targets of the cationic polyamines: the cell membrane and DNA. Like DAB 16, CL4 and CL8 bind plasmid DNA and all three compounds interrupted the cell cycle of A431 epidermoid carcinoma cells in the S-phase. Additionally all three compounds disrupted erythrocyte membranes, with CL8 and DAB 16 being more active, in this respect, than CL4. CL4 (IC(50) =775.1 µg mL(-1)) and CL8 (IC(50) =8.4 µg mL(-1)), in a similar manner to DAB 16, were anti-proliferative against A431 cells; although unlike DAB 16, CL4 and CL8 were not tumouricidal against A431 xenografts in mice, indicating that primary amines may play an important role in the in vivo activity of DAB 16.

The molecular shape of poly(propylenimine) dendrimer amphiphiles has a profound effect on their self assembly.

The shape of dendrimer amphiphiles has an unexpected effect on their self-assembly. A series of diaminobutane poly(propylenimine) generation 3 dendrimer (DAB-dendr-(NH(2))(16)) amphiphiles has been synthesized, bearing an average of five (PD5), three (PD3) and one (PD1) palmitoyl group(s) per dendrimer molecule. Additionally DAB-dendr-(NH(2))(16) was derivatized with a layer of poly(ethylene glycol) (PEG, degree of polymerization = 12) groups and conjugated to an average of 1 palmitoyl group at the PEG end (PPD1). A final amphiphile resulted from the conjugation of DAB-dendr-(NH(2))(16) with 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-succinimidylpropionate (DSPE-PEG(3400)-SPA), i.e.: DPD5 (with 4 DSPE-PEG arms). The critical micellar concentration in aqueous media followed the trend: DPD5 < PD5 = PD3 < PD1 < PPD1 and amphiphiles eventually formed 10-20 nm monomolecular or multimolecular micelles and/or 200 nm spheres or tubules. Aggregation was entropy driven, as expected, for DPD5, PD5 and PD1 and enthalpy driven with the most hydrophilic compound PPD1, but was unexpectedly enthalpy driven for PD3. PD3 aggregates formed low capacity hydrophobic domains with a limited capacity for encapsulation of cyclosporine A; encapsulation levels (mole drug per mole polymer) were 0.099, 0.014, 0.099, and 0.735 for PD1, PD3, PD5, and DPD5 and, respectively. We conclude that star shaped amphiphiles such as PD3 are sterically hindered from self-assembling into high capacity hydrophobic domains in aqueous media. Amphiphile-membrane interactions were promoted by hydrophobic groups, but diminished by PEG moieties. DPD5 is the most suitable amphiphile for biomedical applications.

Polymeric amphiphile branching leads to rare nanodisc shaped planar self-assemblies.

Self-assembly is fundamental to the biological function of cells and the fabrication of nanomaterials. However, the origin of the shape of various self-assemblies, such as the shape of cells, is not altogether clear. Polymeric, oligomeric, or low molecular weight amphiphiles are a rich source of nanomaterials, and controlling their self-assembly is the route to tailored nanosystems with specific functionalities. Here, we provide direct evidence that a particular molecular architecture, polymeric branching, leads to a rare form of self-assembly, the planar nanodisc. Cholesterol containing self-assemblies formed from amphiphilic linear or branched cetyl poly(ethylenimine) (Mn approximately 1000 Da) or amphiphilic cetyl poly(propylenimine) dendrimer derivatives (Mn approximately 2000 Da) show that branching, by reducing the hydrophilic headgroup area, alters the shape of the self-assemblies transforming closed 60 nm spherical bilayer vesicles to rare 50 nm x 10 nm planar bilayer discs. Increasing the hydrophilic headgroup area, by the inclusion of methoxy poly(ethylene glycol) moieties into the amphiphilic headgroup, transforms the planar discs to 100 nm spherical bilayer vesicles. This study provides insight into the key role played by molecular shape on molecular self-organization into rare nanodiscs.

Thermally responsive core-shell nanoparticles self-assembled from cholesteryl end-capped and grafted polyacrylamides:; drug incorporation and in vitro release.

The thermally responsive cholesteryl end-capped poly(N-isopropylacrylamide-co-N,N-dimethylacrylamide) and cholesteryl grafted poly[N-isopropylacrylamide-co-N-(hydroxymethyl) acrylamide] amphiphilic polymers were synthesized and utilized to encapsulate cyclosporin A (CyA) and indomethacin (IND) within core-shell nanoparticles by a membrane dialysis method. The blank and drug-loaded nanoparticles were characterized using various analytical tools. The blank nanoparticles had a mean diameter less than 100 nm, whereas the drug-loaded nanoparticles were between 100 and 200 nm in diameter. The CAC value of cholesteryl end-capped and grafted polymers in PBS (pH 7.4) was estimated to be 16 and 8.5mg/l, respectively. The LCST value for both nanoparticle systems in PBS (pH 7.4) was determined to be 33.4 degrees C and 38.3 degrees C, respectively. The presence of proteins in PBS reduced the LCST. The core-shell nanoparticles provided great capacity for drug loading. In particular, the cholesteryl grafted polymer yielded a higher encapsulation efficiency for drugs. Compared to CyA, better entrapment was observed for IDN. A reduced fabrication temperature provided greater drug encapsulation efficiency. An increase in the initial drug content yielded lower drug encapsulation efficiencies at 10 degrees C and 15 degrees C. Increasing the polymer concentration increased drug encapsulation efficiency. The drug-loading process was analyzed to understand the effect of various fabrication parameters on drug encapsulation efficiency. IND release from the nanoparticles was responsive to temperature changes, being faster at a temperature around the LCST than below the LCST.