Sara Bersani

In Situ Growth of Side-Chain PEG Polymers from Functionalized Human Growth Hormone—A New Technique for Preparation of Enhanced Protein−Polymer Conjugates

The application of atom transfer radical polymerization (ATRP) for preparation of a novel class of protein-polymer bioconjugates is described, exemplified by the synthesis of a recombinant human growth hormone (rh-GH) poly(ethylene glycol) methyl ether methacrylate (PEGMA) hybrid. The rh-GH protein was activated via a bromo-ester functionalized linker and used as a macroinitiator to polymerize the hydrophilic monomer PEGMA under solely aqueous conditions at 4 degrees C. ATRP conditions resulted in controlled polymer growth from rh-GH with low-polydispersity polyPEGMA chains. The rh-GH PEGMA product exhibited properties consistent with the presence of attached hydrophilic polymer chains, namely, high stability to denaturation and proteolysis. The polymerization conditions and conjugation proceeded with retention of the biological activity of the hormone. The rh-GH PEGMA was administered subcutaneously to rats and the activity compared to native rh-GH. The rh-GH PEGMA exhibited similar activity as the native rh-GH in vivo when a daily dose of 40 microg was administered. However, when a higher dose of 120 microg was administered with 3 days between injections the bioavailability of the rh-GH PEGMA was significantly better than that of the native. The results therefore demonstrate that ATRP can be successfully used as a general alternative approach to direct polymer conjugation, namely, PEGylation, to produce PEG-like protein conjugates. This technique can be exploited to design and synthesize protein-polymer derivatives with tailored therapeutic properties.

New cyclodextrin bioconjugates for active tumour targeting

A new cyclodextrin-based carrier for active targeting of low soluble and degradable drugs has been synthesized and characterized. β-Cyclodextrins were first reacted with excess hexamethylene diisocyanate and the resulting CD–(C6–NCO)5 derivative was reacted with 700 Da diamino-PEG to yield CD–(C6–PEG–NH2)5. About one out of five free amino groups of PEG were functionalised with folic acid (FA) as a tumour targeting moiety. The chemical structures of the intermediates as well as the final product, CD–(C6–PEG)5–FA, were characterized by 1H and 13C NMR, reverse phase and gel permeation chromatography, and UV-Vis spectroscopy. After modification, the haemolytic activity of β-cyclodextrins decreased by about 70%. In the presence of the new carrier, the β-estradiol solubility increased by more than 300 fold and the chlorambucil degradation rate decreased by 50–60%. CD–(C6–PEG)5–FA formed an inclusion complex with curcumin displaying an association constant of 954,732 M− 1. The new carrier increased the curcumin solubility by about 3200 fold as compared to native β-cyclodextrins and reduced its degradation rate at pH 6.5 and 7.2 by 10 and 45 fold, respectively. FA receptor-overexpressing human nasopharyngeal tumour KB cell lines and non-folic acid receptor-expressing human breast cancer MCF7 cells were used to evaluate the targeting properties of the new drug delivery system. The in vitro studies demonstrate that the new carrier possesses potential selectivity for the folate receptor-overexpressing tumour cells as ED50 values of 52 μM, 58 μM and 21 μM were obtained with curcumin-loaded CD–(C6–PEG–NH2)5, curcumin in foetal serum medium and CD–(C6-PEG)5–FA, respectively.

Novel folated and non-folated pullulan bioconjugates for anticancer drug delivery

Two new anticancer polymer therapeutics were designed for tumour cell targeting. The bioconjugates were synthesised by pullulan derivatisation with either doxorubicin or doxorubicin and folic acid. Pullulan was activated by periodate oxidation and functionalised by reductive conjugation with cysteamine and 1.9 kDa PEG(NH(2))(2). The cysteamine thiol groups were conjugated to doxorubicin through a pH-sensitive hydrazone spacer while the pending PEG-NH(2) functions of one derivatised pullulan batch were conjugated to folic acid to obtain one of the two polymer therapeutics. The reaction intermediates and the final products were characterised by mass spectrometry, UV-vis analysis and reverse phase and gel permeation chromatography. The folic acid-free derivative [(NH(2) PEG)-Pull-(Cyst-Dox)] contained 6.3% (w/w) doxorubicin while the folic acid-doxorubicin-coupled derivative [(FA-PEG)-Pull-(Cyst-Dox)] contained 6% (w/w) doxorubicin and 4.3% (w/w) folic acid. Photon correlation spectroscopy showed that (NH(2) PEG)-Pull-(Cyst-Dox) and (FA-PEG)-Pull-(Cyst-Dox) assembled into particles of about 150 and 100 nm diameter, respectively. The two bioconjugates displayed similar drug release profiles either at pH 7.4 buffer or in plasma, where less than 20% of doxorubicin was released within three days. At pH 5.5, both conjugates underwent complete drug release in about 40 h. In vitro studies carried out with KB tumour cells over-expressing folic acid receptor showed that both free doxorubicin and (FA-PEG)-Pull-(Cyst-Dox) were rapidly taken up by the cells, while the internalisation of the non-folated derivative was significantly slower. Cell viability studies did not show relevant difference between the two bioconjugates. After 72 h of incubation with folic acid receptor non-expressing MCF7 cells, the IC(50) values of doxorubicin, (NH(2)PEG)-Pull-(Cyst-Dox) and (FA-PEG)-Pull-(Cyst-Dox) were 0.3 μM, 1.2 μM and 3.1 μM, respectively. After incubation with KB cells over-expressing folic acid receptor, the IC(50) values were 0.4 μM, 1.8 μM and 1.1 μM, respectively. Pharmacokinetic studies showed that 4 h after intravenous administration of the conjugates to Balb/c mice about 40% of the administered drug equivalent dose was present in the bloodstream while in the case of unconjugated doxorubicin, 80% of the drug was cleared within 30 min. These findings suggest that the novel doxorubicin-pullulan bioconjugates possess suitable properties for passive tumour targeting. On the other hand, folic acid conjugation has been found to have limited effect on selective cell up-take.

Biopharmaceutical characterisation of insulin and recombinant human growth hormone loaded lipid submicron particles produced by supercritical gas micro-atomisation

Homogeneous dispersions of insulin and recombinant human growth hormone (rh-GH) in tristearin/phosphatidylcholine/PEG mixtures (1.3:1.3:0.25:0.15 w/w ratio) were processed by supercritical carbon dioxide gas micro-atomisation to produce protein-loaded lipid particles. The process yielded spherical particles, with a 197+/-94 nm mean diameter, and the insulin and rh-GH recovery in the final product was 57+/-8% and 48+/-5%, respectively. In vitro, the proteins were slowly released for about 70-80 h according to a diffusive mechanism. In vivo, the insulin and glucose profiles in plasma obtained by subcutaneous administration of a dose of particles containing 2 microg insulin to diabetic mice overlapped that obtained with 2 microg of insulin in solution. Administration of a dose of particles containing 5 microg insulin resulted in faster and longer glycaemia reduction. Oral administration of 20 and 50 microg insulin equivalent particles produced a significant hypoglycaemic effect. The glucose levels decreased since 2h after administration, reaching about 50% and 70% glucose reduction in 1-2h with the lower and higher dose, respectively. As compared to subcutaneous administration, the relative pharmacological bioavailability obtained with 20 and 50 microg equivalent insulin particles was 7.7% and 6.7%, respectively. Daily subcutaneous administration of 40 microg of rh-GH-loaded particles to hypophysectomised rats induced similar body weight increase as 40 microg rh-GH in solution. The daily oral administration of 400 microg rh-GH equivalent particles elicited a slight body weight increase, which corresponded to a relative pharmacological bioavailability of 3.4% compared to subcutaneous administration.

pH-sensitive stearoyl-PEG-poly(methacryloyl sulfadimethoxine) decorated liposomes for the delivery of gemcitabine to cancer cells

Novel, acid-sensitive liposomes that respond to physiopathological pH for tumour targeting applications were obtained by surface decoration with 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-[methoxy(polyethylene glycol)] (mPEG-DSPE) and stearoyl-poly(ethylene glycol)-poly(methacryloyl sulfadimethoxine) copolymer (stearoyl-PEG-polySDM). The pH-sensitive stearoyl-PEG-polySDM copolymer contained an average of seven methacryloyl sulfadimethoxines per molecule and was found to possess an apparent pKa of 7.2. Preliminary cloud point studies showed that the hydrophilic/hydrophobic copolymer conversion occurred at pH 7.0. The copolymer was soluble above pH 7.0 and underwent aggregation at lower pH. Liposome formulations were prepared with 0.2:0.6:100, 0.5:1.5:100 and 1:3:100 mPEG-DSPE/stearoyl-PEG-polySDM/lipids molar ratios. All of the liposome formulations were stable at pH 7.4, even in the presence of foetal bovine serum, but they underwent rapid size increase at pH 6.5. TEM analysis showed that, at pH 6.5, the formulations coated with a stearoyl-PEG-polySDM/lipids molar ratio greater than 1:100 underwent aggregation. At pH 7.4, the liposomes showed negative zeta potential that significantly decreased after incubation at pH 6.5. Cell-culture studies indicated that the liposomes were not toxic up to 10mg/mL. Fluorescence spectroscopy, cytofluorimetry and confocal microscopy showed that at pH 6.5, the incubation of MCF-7 tumour cells with fluorescein-labelled 1:3:100 mPEG-DSPE/stearoyl-PEG-polySDM/lipids molar ratio liposomes resulted in time-dependent cell association, while at pH 7.4 the cell interaction was significantly lower. The same pH-responsive liposome formulation loaded with gemcitabine (98.2±4.7nmol gemcitabine/lipid μmol loading capacity) was stable at pH 7.4 for several hours, while at pH 6.5 it rapidly aggregated. At pH 6.5, these liposomes displayed higher cytotoxicity than at pH 7.4 or compared to non-responsive control liposomes at both incubation pH. Notably, treatment with free gemcitabine did not yield cytotoxic effects, indicating that the carrier can efficiently deliver the anticancer drug to the cytosolic compartment.

Tailored PEG for rh-G-CSF analogue site-specific conjugation.

A new end-tailored monomethoxypoly(ethylene glycol) (PEG) for site-directed protein conjugation was synthesized according to a three-step procedure: (1) linear 20 kDa PEG-NH(2) was conjugated to 12-(Boc-amino)dodecanoic acid; (2) PEG-NHCO(CH(2))(11)-Boc was deprotected by TFA treatment; (3) PEG-NHCO(CH(2))(11)-NH(2) was conjugated to 6-maleimidohexanoic acid to yield PEG-NHCO-(CH(2))(11)-NHCO(CH(2))(5)-Mal (PEG-C(18)-Mal). The chemical intermediates as well as the final product were purified by solvent precipitation/extraction and characterized by (1)H NMR spectroscopy and colorimetric analysis. The synthesis procedure yielded over 90% activated product [PEG-NHCO-(CH(2))(11)-NHCO(CH(2))(5)-Mal/PEG-NH(2) molar ratio, %]. Both PEG-C(18)-Mal and the commercial maleimido activated 20 kDa linear PEG (PEG-Mal) were used for conjugation to (17)Cys of recombinant human granulocyte colony stimulating factor (rh-G-CSF). Under denaturing conditions, at pH 7.0, both activated PEGs yielded over 90% protein conjugation. Under native conditions, about 55% and 7% PEGylated protein were obtained with PEG-C(18)-Mal and PEG-Mal, respectively. Circular dichroism analysis showed that the PEGylation does not induce detectable alteration of the protein secondary structure. On the other hand, the PEGylation conditions were found to affect significantly the protein stability. The derivatives obtained either with the two polymers by unfolding/refolding process or with PEG-Mal under native conditions displayed rapid aggregation with half-life ranging from 30 to 90 min. The derivative obtained with PEG-NHCO-(CH(2))(11)-NHCO(CH(2))(5)-Mal in the absence of guanidinium chloride displayed remarkably higher stability with aggregation half-life of about 60 h.

Self-assembling nanocomposites for protein delivery: supramolecular interactions between PEG-cholane and rh-G-CSF.

PEG(5 kDa)-cholane, PEG(10 kDa)-cholane and PEG(20 kDa)-cholane self-assembling polymers have been synthesised by the end-functionalisation of 5, 10 and 20 kDa linear amino-terminating monomethoxy-poly(ethylene glycol) (PEG-NH(2)) with 5β-cholanic acid. Spectroscopic studies and isothermal titration calorimetry showed that the CMC of the PEG-cholane derivatives increased from 23.5 ± 1.8 to 60.2 ± 2.4 μM as the PEG molecular weight increased. Similarly, light scattering analysis showed that the micelle size increased from 15.8 ± 4.9 to 23.2 ± 11.1 nm with the PEG molecular weight. Gel permeation studies showed that the polymer bioconjugates associate with recombinant human granulocyte colony stimulating factor (rh-G-CSF) to form supramolecular nanocomposites according to multi-modal association profiles. The protein loadings obtained with PEG(5 kDa)-cholane, PEG(10 kDa)-cholane and PEG(20 kDa)-cholane were 7.4 ± 1.1, 2.7 ± 0.3 and 2.1 ± 0.4% (protein/polymer, w/w %), respectively. Scatchard and Klotz analyses showed that the protein/polymer affinity constant increased and that the number of PEG-cholane molecules associated to rh-G-CSF decreased as the PEG molecular weight increased. Isothermal titration calorimetry confirmed the protein/polymer multi-modal association. Circular dichroism analyses showed that the polymer association alters the secondary structure of the protein. Nevertheless, in vitro studies performed with NFS-60 cells showed that the polymer interaction does not impair the biological activity of the cytokine. In vivo studies performed by intravenous and subcutaneous administrations of rh-G-CSF to rats showed that the association with PEG(5 kDa)-cholane prolongs the body exposure of the protein. After subcutaneous administration, the protein t(max) values obtained with rh-G-CSF and 1:14 and 1:21 rh-G-CSF/PEG(5 kDa)-cholane (w/w ratio) nanocomplexes were 2, 8 and 24h, respectively. The 1:21 (w/w) rh-G-CSF/PEG(5kDa)-cholane formulation resulted in 149% relative bioavailability, and the pharmacokinetic behaviour was similar to that obtained with an equivalent protein dose of rh-G-CSF chemically conjugated with one linear 20-kDa PEG. A single administration of a 1.5mg/kg dose of a 1:21 (w/w) rh-G-CSF/PEG(5 kDa)-cholane formulation induced a high production of white blood cells for 96 h.

Polysaccharide-Based Anticancer Prodrugs

So far, polysaccharides have been widely used in pharmaceutical technology as first choice excipients for production of traditional formulations. Nevertheless, in the recent years these natural and semisynthetic macromolecules have been addressed for new challenging applications as functional materials for innovative formulations. Their peculiar physicochemical and biological properties have been exploited to develop macromolecular prodrugs which can exhibit favorable biopharmaceutical properties and enforce the therapeutic performance of the parent drugs. These polymers display, in fact, high biocompatibility and biodegradability, multiple insertion points, and biological properties that can be advantageously exploited in drug delivery. In particular, the multifunctional structures of these polymers are anchoring points for conjugation of several anticancer drugs, which usually suffer from poor physicochemical, biopharmaceutical, and therapeutic properties that limit their therapeutic performance and proper use in anticancer treatment. Polysaccharide-based anticancer prodrugs can be designed to endow derivatives with new bioresponse, targeting, or environmental triggering properties or to combine molecules with synergistic therapeutic effect. Over the years, a variety of synthetic protocols have been set up to conjugate anticancer drugs to the polysaccharide backbone via specific linkages or through spacers which convey to the conjugates selective drug-delivery properties. Furthermore, the intrinsic antitumor activity and cell-targeting properties of few polysaccharides represent an additional value to the final therapeutic systems. Anticancer drugs with different pharmacodynamic, pharmacokinetic, and physicochemical properties have been successfully conjugated to various natural and semisynthetic polysaccharides highlighting the interesting perspectives for exploitation of new promising anticancer polymer therapeutics.

pH-responsive lipid core micelles for tumour targeting.

A new acid-sensitive drug-delivery nanocarrier has been developed for tumour targeting. The self-assembling co-polymer stearoyl-PEG-poly-sulfadimethoxine methacrylate (stearoyl-PEG-polySDM) was prepared to obtain micelles with responsive behaviour in the physiopathologic pH range. Stearoyl-PEG-polySDM was synthesised using a multi-step procedure that includes pH-sensitive sulfadimethoxine methacrylate polymerisation by AGET-ATRP at the amino terminal side of stearoyl-PEG-NH2. Chemical analysis showed that the stearoyl-PEG-polySDM co-polymer contained a mean of seven methacryloyl sulfadimethoxines per molecule. Potentiometric and turbidimetric analyses showed that stearoyl-PEG-polySDM has an apparent pKa of 7.2 and a cloud point at pH 7.0. In water at pH 7.4, the co-polymer assembled spontaneously into 13.2±3.1 nm micelles with a critical micelle concentration (CMC) of 36 μM. Cell-culture studies showed that the material was more biocompatible with respect to the control Brij-700®. The paclitaxel loading capacity of the micelles was 3.25±0.25% (w/w, %). The colloidal formulations were stable at pH 7.4 for several hours, while at pH 6.5, they rapidly rearranged and aggregated. Fluorescence spectroscopic and cytofluorimetric studies showed that the incubation of MCF-7 tumour cells with fluorescein-labelled stearoyl-PEG-polySDM at pH 6.5 resulted in massive time-dependent cell association, while the incubation at pH 7.4 showed significantly lower cell interaction. Confocal microscopy confirmed that at pH 6.5, the micelles are taken up by cells and that the fluorescein-labelled stearoyl-PEG-polySDM is distributed into the cytosol. At pH 6.5, paclitaxel-loaded stearoyl-PEG-polySDM micelles had a higher cytotoxic effect than the micelles incubated at pH 7.4. The former displayed similar cytotoxic activity to free paclitaxel.

Star-Like Oligo-Arginyl-Maltotriosyl Derivatives as Novel Cell-Penetrating Enhancers for the Intracellular Delivery of Colloidal Therapeutic Systems

A novel nonpeptide, multiarmed oligo-arginyl derivative was engineered as a cell-penetration enhancer for the delivery of bioactive macromolecules and colloidal drug systems. Hepta-arginyl-maltotriosylamido-N-acetyl-dodecanoyl acid (Arg(7)-Malt-NAcC(12) acid) was synthesized through a carefully designed multistep chemical protocol, as follows: (1) maltotriose derivatization with 12-amino-dodecanoic acid and acetylation of the free amino group; (2) esterification of the maltotriosyl hydroxyl groups with 2-bromo-isobutyryl bromide; and (3) synthesis of star-like oligomer bearing multiple copies of arginine moieties under atom transfer radical polymerization (ATRP) conditions. The intermediates and final product were characterized by (1)H NMR, IR, mass spectrometry, colorimetric assays, and elemental analysis. Cytotoxicity studies on the final polymeric material showed that this novel cell-penetrating enhancer does not have significant toxic effects on MCF-7 and MC3T3-E1 cell lines. The IC(50) was greater than 100 μM with both cell lines, while the polyethylenimine with similar average molecular mass (M(n)) that was used as a reference showed an IC(50) of 30 and 40 μM, for MCF-7 and MC3T3-E1, respectively. The biological properties of the novel bioconjugate were investigated using a fluorescein-labeled bovine serum albumin (FITC-BSA) as a hydrophilic cargo model. MCF-7 and MC3T3-E1 cells were incubated for 60 min with the Arg(7)-Malt-NAcC(12)-conjugated FITC-BSA [(Arg(7)-Malt-NAcC(12))(2)-FITC-BSA] or FITC-BSA, and the intracellular fluorescence level was analyzed by spectrofluorimetric analysis of cell lysate, cytofluorimetry, and confocal microscopy. The fluorescence of the lysate of MCF-7 and MC3T3-E1 cells that were incubated with (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA at 37 °C was approximately 4.5 times higher than the fluorescence obtained with cells incubated with FITC-BSA. At 4 °C, the cell uptake of (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA was only 2 times higher than that of FITC-BSA. Cytofluorimetric studies showed that, after (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA treatment, over 80% of MCF-7 cells and over 95% of MC3T3-E1 cells displayed enhanced fluorescence. Confocal investigations showed punctuated fluorescence within the cytosol in both cell lines, indicating that (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA was confined to endosomes, with no fluorescence observed in the nucleus.