Recent development of silica nanoparticles as delivery vectors for cancer imaging and therapy

In spite of significant advances in early detection and combined treatments, a number of cancers are often diagnosed at advanced stages and thereby carry a poor prognosis. Developing novel prognostic biomarkers and targeted therapies may offer alternatives for cancer diagnosis and treatment. Recent rapid development of nanomaterials, such as silica based nanoparticles (SiNPs), can just render such a promise. In this article, we attempt to summarize the recent progress of SiNPs in tumor research as a novel delivery vector. SiNP-assisted imaging techniques are used in cancer diagnosis both in vitro and in vivo. Meanwhile, SiNP-mediated drug delivery can efficiently treat tumor by carrying chemotherapeutic agents, photosensitizers, photothermal agents, siRNA, and gene therapeutic agents. Finally, SiNPs that contain at least two different functional agents may be more powerful for both tumor imaging and therapy.From the Clinical EditorThis paper summarizes recent progress on the field of silica nanoparticles research as novel delivery vectors for cancer-specific imaging as well as drug delivery of chemotherapeutics, photosensitizers, photothermal agents, siRNA, and gene therapy agents.     

New diketopiperazines as vectors for peptide protection and brain delivery: Synthesis and biological evaluation

New strategies allowing the transfer of molecules, especially peptides, through the blood‐brain barriers are a major pharmacological challenge for the treatment of brain diseases. The present study aims at evaluating in vivo the cerebral bioavailability of carrier systems, based on small and functionalizable 2,5‐diketopiperazine (DKP) motifs. We studied 2 different cyclo(Lys‐Lys) DKP scaffolds alone and a cyclo(Lys‐Gly) DKP carrier bearing as peptide model, the tau protein hexapeptide VQIVYK sequence. The different carrier systems were synthesized and radiolabeled using one of the free domains. The stability, biodistribution, and ability to cross blood‐brain barrier were investigated in vivo in mice for ^99mTc‐DKP scaffolds, ^99mTc‐HVQIVYK peptide alone, and ^99mTc‐DKP‐VQIVYK. ¹²⁵I‐labelled bovine serum albumin was used as negative control for brain uptake. Both radiolabeled DKPs scaffolds and ^99mTc‐DKP‐VQIVYK showed a high stability, while peptide ^99mTc‐HVQIVYK alone was quickly degraded in vivo. The presence of ^99mTc‐DKPs scaffolds and ^99mTc‐DKP‐VQIVYK was observed in the ventricular and subarachnoid spaces and to a lower extent in the brain parenchyma up to 45 minutes post‐injection in mice. This work highlights the potentiality of DKP scaffolds as vectors to transport peptides into the brain by limiting proteolysis and favoring cerebral bioavailability.     

Dual-targeting delivery system for bone cancer: synthesis and preliminary biological evaluation

Chemotherapy in treatment of malignant tumors has many side effects due to the poor physiochemical properties and the toxicity to normal tissues. The dual-targeting drug delivery system combining two high-affinity ligands can target anticancer drug primary to the diseased tissue, then to the tumor, which provides both greater efficacy of treatment and less harm to normal tissues. In this paper, a novel dual-targeting moiety RGD₇ (R-G-D-D-D-D-D-D-D; Nonapeptide for bone cancer combining D₆ peptide as bone target moiety and RGD peptide as tumors target moiety was contracted. A series of bone and/or tumor targeting conjugates have been synthesized in a convergent approach and well characterized by nuclear magnetic resonance (NMR) and mass spectrometry (MS) techniques. The hydroxyapatite (HAP) binding, water solubility, the drug release and the distribution in vivo were evaluated. All the conjugates were water-soluble and able to release the parent drugs in vitro. The bone-targeting property of the dual-targeting delivery system was enhanced from the results of the HAP binding and the distribution in vivo. The experiment for verifying tumor targeting property was underway. These results provided an effective entry to the development of a new dual-targeting delivery system for bone cancer.     

Physicochemical and biological evaluation of cationic polymethacrylates as vectors for gene delivery.

We report here the physicochemical and biological evaluation of a series of polymethacrylates with side groups of different pK(a) values, such as tertiary amines, pyridine groups, acid functions and imidazole groups as synthetic vectors for gene delivery. The ability of the different polymers to condense DNA was studied by ethidium bromide exclusion tests and agarose gel electrophoresis. The results show that all polymers are able to condense DNA. Both the molecular weight and the chemical composition of the polymers have an influence on the DNA condensation process. Furthermore, the biological properties of the polymer-DNA complexes were investigated, including their haemolytic activity, cytotoxicity and in vitro transfection efficiency. Complexes based on polymers containing only tertiary amines, have a transfection efficiency similar to that of poly(ethyleneimine) (PEI). Polymers containing pyridine groups have a reduced transfection efficiency compared to polymers containing tertiary amines. Introduction of imidazole groups or acid functions results in a loss of the transfection efficiency of the corresponding complexes with DNA. In general, the viability of cells incubated with complexes based on the polymethacrylates is higher than with PEI. Polymers with high transfection efficiency induce erythrocyte lysis.     

Design,synthesis and biological evaluation of peptide‐NSAID conjugates for targeted cancer therapy

Linear arginine‐glycine‐aspartic acid (RGD) and asparagine‐glycine‐arginine (NGR) peptide‐nonsteroidal anti‐inflammatory drug conjugates were synthesized to evaluate their anticancer effect. Two well‐known targeting peptide sequences, RGD and NGR, were conjugated with naproxen and ibuprofen. It is expected that the RGD peptide selectively binds to α_v‐integrin receptors, which are highly expressed in cancer cells, and that the NGR peptide selectively targets aminopeptidase N (APN/CD13, EC 3.4.11.2), which is overexpressed in blood vessels of tumors. To investigate the impact of possible steric hindrance due to the attachment of the drug to the peptide, a linear six‐carbon linker (hexanoic acid) was also used as a spacer. Cytotoxic effects of the synthesized compounds were evaluated against several cancer cell lines, including MCF‐7, A2780 (α_vβ₃ positive), OVCAR3 (high α_vβ₃), HT‐1‐80, and SKOV‐3 cells (CD13 positive). The NGR conjugate forms of both ibuprofen and naproxen showed better activity against the SKOV‐3 tumor cell line. The improved binding of these conjugates to their receptors was confirmed by docking studies.     

Recent progress in the syntheses and biological evaluation of boronated porphyrins for boron neutron-capture therapy

Boronated porphyrins are an important class of tumor-localizing agents in two bimodal therapies for cancer currently under study experimentally and clinically; boron neutron-capture therapy (BNCT) and photodynamic therapy (PDT). The desirable properties for the boronated porphyrins are that they are easily synthesized, pure and well-characterized drugs, and that in vivo, they are stable, tumor-specific, with high tumor:blood and tumor:normal tissue boron concentration ratios, and cause minimal toxicity. A large number of new porphyrins and their syntheses are presented herein. The focus is primarily on porphyrins published within the past 5 years, but the implications and trends from porphyrins studied in vivo over the past 15 years are also reviewed. Many possess quite unusual, novel structures and others have appended cell-targeting moieties for greater tumor specificity. Besides the commonly used closo- and nido-o-carboranes other boron cages and modes of attachment are presented. These boron cages can selectively alter the lipophilic, hydrophilic and amphiphilic properties of the porphyrins as well as their boron content. New delivery modalities have also greatly improved the targeting potential of compounds previously deemed unsuitable for applications in BNCT.     

Synthesis and biological evaluation of neutral and zwitterionic 3-carboranyl thymidine analogues for boron neutron capture therapy

Novel 3-carboranyl thymidine analogues (3CTAs) were synthesized as potential boron delivery agents for boron neutron capture therapy (BNCT). This library includes six zwitterionic NH(3)(+)-nido-m-carborane-substituted thymidine analogues (Thds) and the corresponding neutral NH(2)-closo-m-carborane-substituted counterparts. All compounds of this library were good substrates for recombinant human thymidine kinase 1 (TK1) with phosphorylation rates up to 89% relative to that of Thd. One compound out of this library, 3-[3-(7-NH(3)(+)-nido-m-carboran-1-yl)propan-1-yl]thymidine (19b), showed selective retention in TK1-expressing murine L929 wild-type tumors versus L929 TK1 (-) tumors in biodistribution studies. The biological evaluation of the zwitterionic NH(3)(+)-nido-m-carborane-substituted Thds indicated improved aqueous solubility and similar or even superior potential as BNCT agents compared with different classes of 3CTAs (Cancer Res. 2004, 64, 6280-6286 and 6287-6295). To complete previous structure-activity relationship (SAR) studies, 3-[(closo-o-carboranyl)methyl]thymidine (4) was also synthesized and evaluated.     

Polybutylcyanoacrylate nanoparticles as novel vectors in cancer gene therapy

To make progress toward an efficient gene vector for cancer gene therapy, a novel nonviral vector of polybutylcyanoacrylate nanoparticles (PBCA NPs) was developed. Cetyltrimethyl ammonium bromide (CTAB) was used to modify the surface of PBCA NPs, and then the plasmid DNA (pDNA) of pAFP-TK was wrapped into PBCA-CTAB NPs. Atomic force microscopy and zeta potential demonstrated that PBCA-CTAB NPs were 80-200 nm in diameter and had +15.6 mV positive surface charges. Assay using 3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyl-2H-tetrazolium bromide showed that PBCA-CTAB NPs had less cytotoxicity to 3T3 cells than HepG2 cells. The analysis of PBCA-CTAB-DNA complexes could not only protect DNA from degradation by DNase I, it could also transfer pDNA into targeted cells with high transfection efficiency. Furthermore, when PBCA-CTAB NPs combined with suicide gene pAFP-TK, alpha-fetoprotein-positive cells transfected by it were highly sensitive to ganciclovir treatment, and cell survival declined precipitously. Therefore, this target strategy using a pAFP-TK/GCV suicide gene therapy system in which PBCA-CTAB NPs serve as gene delivery vectors explores a promising area for alpha-fetoprotein-positive hepatocellular carcinoma and associated carcinoma therapy.     

Aminoacyl-anthraquinone conjugates as telomerase inhibitors: synthesis, biophysical and biological evaluation

The telomerase-telomere complex is a prospective anticancer target. To inhibit enzyme activity by induction of G-quadruplex in human telomeres, we have synthesized a small library of 2,6- and 2,7-amino-acyl/ peptidyl anthraquinones with diverse connecting linkers, charge, lipophilicity and bulk. The test compounds modulated G-quadruplex stability to different extents and showed clear preference for quadruplex over duplex DNA. Telomerase inhibition correlated with G-quadruplex stabilization. A SAR analysis showed that type of linkage between the linker and the anthraquinone, together with the position of the side chains and the nature of the amino acid components play a major role both in stabilizing G-quadruplex and producing telomerase inhibition. Short-term cytotoxic activity was poor. However, after prolonged exposure to effective G-quadruplex binders, cells became senescent. These results are of help in the rational design of more efficient G-quadruplex stabilizers, possibly endowed with cancer cell-selective antiproliferative effects.     

Hydroxylated decahydroquinolines as ligands for the vesicular acetylcholine transporter: synthesis and biological evaluation.

Analogues of the potent anticholinergic 2-(4-phenylpiperidino)cyclohexanol (vesamicol, 1) in which the cyclohexyl fragment was replaced with an N-acyl or N-alkyl trans-decahydroquinolyl moiety were synthesized and evaluated as potential ligands for the vesicular acetylcholine transporter (VAChT). The binding of compounds, such as 18, 20, and 21, was both stereospecific and of comparable magnitude to that of the closely related vesamicol analogue 2,3-trans-4a, 8a-trans-3-hydroxy-2-(4-phenylpiperidino)-1,2,3,4,5,6,7, 8-decahydronaphthalene (6) which displays subnanomolar affinity for this transporter. However, these compounds also demonstrated high affinities for sigma(1) and sigma(2) receptors and thus failed to show significantly improved selectivity over previously reported vesamicol analogues.     

Carboranylporphyrins for boron neutron capture therapy of cancer

A major challenge for cancer treatment is the preferential and irreversible killing of tumor cells and minimal damage of normal tissues, both in the site of the malignancy and in the body. The agents used in boron neutron capture therapy (BNCT) are supposed to have the following advantages over many conventional chemotherapeutics: 1) when irradiated with thermal neutrons, an unstable isotope (11)B is formed whose rapid decay yields local and a thermal effect; 2) because the free path of the released particles is close to the cell diameter, the tissues outside the tumor should gain less damage; 3) local radioactivity and heat should be harmful for cells that, in the course of their natural history, acquired the determinants of altered response to many toxic stimuli. However, a higher specificity of damage would be achieved if the drugs accumulate mostly in cancer cells rather than in non-malignant counterparts. Therefore, optimization of agents for BNCT presumes the design of chemicals with improved accumulation/ retention in cancer cells. In particular, carboranyl-substituted porphyrins, the stable conjugates of macrocyclic porphyrins with complex boron-containing polyhedra, are considered good candidates for BNCT due to their uptake by cancer cells and high boron content. Importantly, the proposed mechanisms of pharmacological effects of carboranylporphyrins make these compounds potentially appropriate for elimination of pleiotropically resistant tumor cells.     

Dual-targeting for brain-specific drug delivery: synthesis and biological evaluation

Ibuprofen is one of the most potent non-steroid anti-inflammatory drugs (NSAIDs) and plays an important role in the treatment of neurodegenerative diseases. However, its poor brain penetration and serious side effects at therapeutic doses, has hindered its further application. Thus, it is of great interest to develop a carrier-mediated transporter (CMT) system that is capable of more efficiently delivering ibuprofen into the brain at smaller doses to treat neurodegenerative diseases. In this study, a dual-mediated ibuprofen prodrug modified by glucose (Glu) and vitamin C (Vc) for central nervous system (CNS) drug delivery was designed and synthesized in order to effectively deliver ibuprofen to brain. Ibuprofen could be released from the prepared prodrugs when incubated with various buffers, mice plasma and brain homogenate. Also, the prodrug showed superior neuroprotective effect in vitro and in vivo than ibuprofen. Our results suggest that chemical modification of therapeutics with warheads of glucose and Vc represents a promising and efficient strategy for the development of brain-targeting prodrugs by utilizing the endogenous transportation mechanism of the warheads.     

Poxviruses as vectors for cancer immunotherapy

Despite advances in chemotherapy and surgical techniques, patients with cancer often develop local recurrence or metastatic spread. Recent advances in molecular biology, coupled with new insights in tumor immunology, have led to the design of novel antitumor vaccines. Poxviruses are a large family of DNA viruses that provide an effective and safe vector system for vaccine development. The poxvirus strategy has been successfully documented in animal models, and has been used to express both tumor-associated antigens and immune stimulatory molecules. In this review, we focus on recent advances in the use of poxvirus-based vaccines as cancer therapeutic agents.     

Design, synthesis and biological evaluation of new 2-benzoxazolinone derivatives as potential cholinesterase inhibitors for therapy of alzheimer's disease

Currently acetylcholinesterase inhibitor (AChEI) therapy is one of the most frequently used methods in the treatment of Alzheimer's disease; tacrine, donepezil, rivastygmine and galantamine are applied in different stages of AD. In the present study, we propose a new series of 2-benzoxazolinone derivatives as potential cholinesterase inhibitors. These compounds were synthesized by condensation of 6-chloro acetyl-2-benzoxa zolinone with the corresponding amine and evaluated as acetylcholinesterase inhibitors using the colorimetric Ellman's method. Selectivity and the IC50 values were determined for the received derivatives. All tested compounds exhibited the inhibitory activity towards acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). Compound 3e showed stronger activity than the standard tacrine, and compound 3a showed activity similar to that of tacrine for AChE. Compounds 3a, 3b, 3c, and 3e showed stronger activity than the standard donepezil towards the inhibition of BChE, and the compound 3e showed stronger activity than donepezil towards AChE.     

Hetero-annulated coumarins as new AChE/BuChE inhibitors: synthesis and biological evaluation

A series of chromene-fused coumarins known as 10,11-dihydrochromeno[4,3-b]chromene-6,8(7H,9H)-diones 4a–o were synthesized through one-pot reaction of appropriate benzaldehydes, dimedone, and 4-hydroxycoumarin in the presence of nano-silica sulfuric acid under solvent-free condition in good yields. The in vitro anticholinesterase assay revealed that the 3-hydroxyphenyl analog 4e showed the highest inhibitory activity against both acetylcholinesterase and butyrylcholinesterase, possessing IC₅₀ values of 3.28 and 2.19?µM, respectively. The structure-activity relationships study demonstrated that the selectivity for acetylcholinesterase over butyrylcholinesterase could be modulated by introducing second hydroxyl or methoxy substituent on the para-position of the 3-hydroxyphenyl pendent group. The docking study of compound 4e with acetylcholinesterase confirmed π–π stacking interaction between the coumarin moiety and Trp279 as well as the formation of hydrogen bonding between hydroxyl group and Asn85.     

N-deacetyl-N-aminoacylthiocolchicine derivatives: synthesis and biological evaluation on MDR-positive and MDR-negative human cancer cell lines

A new series of N-deacetyl-N-(N-trifluoroacetylaminoacyl)thiocolchicine derivatives 9-15 have been synthesized starting from the corresponding N-deacetylthiocolchicine (3) and the N-trifluoroacetylamino acids 5-8 which were used as a racemic mixture. The trifluoroacetyl protecting group has been removed easily, giving the corresponding N-deacetyl-N-aminoacylthiocolchicines 16-22. Optical pure compounds 9-22 were isolated from the diastereoisomeric mixture or were prepared starting from compound 3 and an optical pure amino acid derivative; the configuration of each compound was assigned unequivocally. The diastereoisomeric couples of amino acids synthesized were tested, and their antiproliferative activity on MDR-positive and MDR-negative human cancer cell lines was evaluated.     

Design,synthesis and biological evaluation of ambenonium derivatives as AChE inhibitors

Ambenonium (1), an old AChE inhibitor, is endowed with an outstanding affinity and a peculiar mechanism of action that, taken together, make it a very promising pharmacological tool for the treatment of Alzheimer's disease (AD). Unfortunately, the bisquaternary structure of 1 prevents its passage through the blood brain barrier. In a search of centrally active ambenonium derivatives, we planned to synthesize tertiary amines of 1, such as 2 and 3. In addition, to add new insights into the binding mechanism of the inhibitor, we designed constrained analogues of ambenonium by incorporating the diamine functions into cyclic moieties (4-12). The biological evaluation of the new compounds has been assessed in vitro against human AChE and BChE. All tertiary amine derivatives resulted more than 1000-fold less potent than 1 and, unlike prototype, did not show any selectivity between the two enzymes. This result, because of recent findings concerning the role of BChE in AD, makes our compounds, endowed with a well-balanced profile of AChE/BChE inhibition, valuable candidates for further development. To better clarify the interactions that account for the high affinity of 1, docking simulations and molecular dynamics studies on the AChE-1 complex were also carried out.     

Non-viral vectors in cancer gene therapy: principles and progress

This review focuses on the use of synthetic (non-viral) delivery systems for cancer gene therapy. Therapeutic strategies such as gene replacement/mutation correction, immune modulation and molecular therapy/'suicide' gene therapy type approaches potentially offer unique and novel ways of fighting cancer, some of which have already shown promise in early clinical trials. However, the specific and efficient delivery of the genetic material to remote tumors/metastases remains a challenge, which is being addressed using a variety of viral and non-viral systems. Each of these disparate systems has distinct advantages and disadvantages, which need to be taken into account when a specific therapeutic gene is being used. The review concentrates on particulate gene delivery systems, which are formed through non-covalent complexation of cationic carrier molecules (e.g. lipids or polymers) and the negatively charged plasmid DNA. Such systems tend to be comparatively less efficient than viral systems, but have the inherent advantage of flexibility and safety. The DNA-carrier complex acts as a protective package, and needs to be inert and stable while in circulation. Once the remote site has been reached the complex needs to efficiently transfect the targeted (tumor) cells. In order to improve overall transfection specificity and efficiency it is necessary to optimize intracellular trafficking of the DNA complex as well as the performance after systemic administration. Common principles and specific advantages or disadvantages of the individual synthetic gene delivery systems are discussed, and their interaction with tumor-specific and generic biological barriers are examined in order to identify potential strategies to overcome them.     

Substituted chloroacetamides as potential cancer stem cell inhibitors: Synthesis and biological evaluation

Cancer kills, irrespective of geographical and cultural origin. Novel modalities for treating cancer are desperately needed. Cancer stem cells (CSCs), main culprits behind chemoresistance and tumor relapse, are one of the few logical choices. Herein, we report the synthesis and biological evaluation of small molecules with chloroacetamide war-head. These molecules were screened for viability against various breast, prostate, and oral cancer cell lines using MTT and soft-agar assays. Further, promising hits were screened in sphere-forming assay with the aim of discovering potential anti-CSC agents. Our optimism yielded four hits inhibiting self-renewal of cancer cells with stem-like characters in vitro. Finally, the hits were evaluated for in vitro toxicity against human peripheral blood mononuclear cells and mouse embryonic fibroblast cell line. Overall, these preliminary investigations yielded three hits exhibiting promising anti-CSC potential with little or no toxicity against normal cells.