Bacterially-Derived Nanocells for Tumor-Targeted Delivery of Chemotherapeutics and Cell Cycle Inhibitors

MacDiarmid, Jennifer; Madrid-Weiss, Jocelyn; Amaro-Mugridge, Nancy B.; Phillips, Leo; Brahmbhatt, Himanshu

doi:10.4161/cc.6.17.4648

Cited by 31 publications

(32 citation statements)

References 90 publications

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“…Nevertheless, active targeting might significantly decrease the effective dosing required for antitumor efficacy. For example, MacDiarmid et al (44, 45) reported that they were able to reduce i.v. doxorubicin doses required to achieve significant growth inhibition of murine breast cancer xenografts by more than 3 log scales when the drug was encapsulated in so-called “nanocells” coated with anti–epidermal growth factor receptor antibodies.…”

Section: Discussionmentioning

confidence: 99%

In vivo characterization of a polymeric nanoparticle platform with potential oral drug delivery capabilities

Bisht¹,

Feldmann²,

Koorstra

et al. 2008

Molecular Cancer Therapeutics

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Nanotechnology has enabled significant advances in the areas of cancer diagnosis and therapy. The field of drug delivery is a sterling example, with nanoparticles being increasingly used for generating therapeutic formulations of poorly water-soluble, yet potent anticancer drugs. Whereas a number of nanoparticle-drug combinations are at various stages of preclinical or clinical assessment, the overwhelming majorities of such systems are injectable formulations and are incapable of being partaken orally. The development of an oral nano-delivery system would have distinct advantages for cancer chemotherapy. We report the synthesis and physicochemical characterization of orally bioavailable polymeric nanoparticles composed of N-isopropylacrylamide, methylmethacrylate, and acrylic acid in the molar ratios of 60:20:20 (designated NMA622). Amphiphilic NMA622 nanoparticles show a size distribution of <100 nm (mean diameter of 80 ± 34 nm) with low polydispersity and can readily encapsulate a number of poorly water-soluble drugs such as rapamycin within the hydrophobic core. No apparent systemic toxicities are observed in mice receiving as much as 500 mg/kg of the orally administered void NMA622 for 4 weeks. Using NMA622-encapsulated rapamycin (“nanorapamycin”) as a prototype for oral nano-drug delivery, we show favorable in vivo pharmacokinetics and therapeutic efficacy in a xenograft model of human pancreatic cancer. Oral nanorapamycin leads to robust inhibition of the mammalian target of rapamycin pathway in pancreatic cancer xenografts, which is accompanied by significant growth inhibition (P < 0.01) compared with control tumors. These data indicate that NMA622 nanoparticles provide a suitable platform for oral delivery of water-insoluble drugs like rapamycin for cancer therapy.

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Section: Discussionmentioning

confidence: 99%

In vivo characterization of a polymeric nanoparticle platform with potential oral drug delivery capabilities

Bisht¹,

Feldmann²,

Koorstra

et al. 2008

Molecular Cancer Therapeutics

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“…Benoit et al reported that the magnetotactic bacteria Magnetospirillum magneticum AMB-1 could produce positive MRI contrast and colonize mouse tumor xenografts, providing a potential tool for MRI visualization of bacteria in preclinical and translational studies to track cancer despite its lower sensitivity. Following IV injection of 64 Cu-labeled AMB-1, PET imaging also revealed increased bacterial colonization of tumors, but decreased colonization of other organs, such as liver and spleen, after 4 h [57].…”

Section: Bacteriamentioning

confidence: 98%

“…These minicells can be packaged with therapeutically relevant concentrations of a range of therapeutics and selectively targeted to cancer cells via bispecific antibodies (BsAbs) (Fig. 1d) [64,65]. A two-wave cancer treatment has been explored in which minicells are specifically and sequentially delivered to tumor xenografts.…”

Section: Bacteria-like Particlesmentioning

confidence: 99%

Molecular Imaging of Biological Gene Delivery Vehicles for Targeted Cancer Therapy: Beyond Viral Vectors

Min

Nguyen

Gambhir

2010

Nucl Med Mol Imaging

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Cancer persists as one of the most devastating diseases in the world. Problems including metastasis and tumor resistance to chemotherapy and radiotherapy have seriously limited the therapeutic effects of present clinical treatments. To overcome these limitations, cancer gene therapy has been developed over the last two decades for a broad spectrum of applications, from gene replacement and knockdown to vaccination, each with different requirements for gene delivery. So far, a number of genes and delivery vectors have been investigated, and significant progress has been made with several gene therapy modalities in clinical trials. Viral vectors and synthetic liposomes have emerged as the vehicles of choice for many applications. However, both have limitations and risks that restrict gene therapy applications, including the complexity of production, limited packaging capacity, and unfavorable immunological features. While continuing to improve these vectors, it is important to investigate other options, particularly nonviral biological agents such as bacteria, bacteriophages, and bacteria-like particles. Recently, many molecular imaging techniques for safe, repeated, and high-resolution in vivo imaging of gene expression have been employed to assess vector-mediated gene expression in living subjects. In this review, molecular imaging techniques for monitoring biological gene delivery vehicles are described, and the specific use of these methods at different steps is illustrated. Linking molecular imaging to gene therapy will eventually help to develop novel gene delivery vehicles for preclinical study and support the development of future human applications.

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“…In parallel to developing novel targeting ligands, novel nanocarrier compositions have also been extensively investigated in the past decade, e.g., minicells (MacDiarmid et al 2007a, 2007b), apotransferrin (Krishna et al 2009) and synthetic HDL or LDL lipid nanoparticles (Nikanjam et al 2007, Thaxton et al 2009). Moreover, inorganic drug delivery systems such as nanodiamond and single wall carbon nanotube also demonstrated some potential (Bhirde et al 2009, Lam and Ho 2009).…”

Section: Novel Delivery Strategies For Targeted Nanocarriersmentioning

confidence: 99%

“…MacDiarmid et al (2007a, 2007b, 2009) described a new type of nanocarrier known as minicells. These are ~400 nm in diameter and are derived from achromosomal bacterial cells.…”

Section: Novel Delivery Strategies For Targeted Nanocarriersmentioning

confidence: 99%

Receptor-targeted nanocarriers for therapeutic delivery to cancer

Yu¹,

Tai²,

Wang³

et al. 2010

Molecular Membrane Biology

308

165

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Efficient and site-specific delivery of therapeutic drugs is a critical challenge in clinical treatment of cancer. Nano-sized carriers such as liposomes, micelles, and polymeric nanoparticles have been investigated for improving bioavailability and pharmacokinetic properties of therapeutics via various mechanisms, for example, the enhanced permeability and retention (EPR) effect. Further improvement can potentially be achieved by conjugation of targeting ligands onto nanocarriers to achieve selective delivery to the tumour cell or the tumour vasculature. Indeed, receptor-targeted nanocarrier delivery has been shown to improve therapeutic responses both in vitro and in vivo. A variety of ligands have been investigated including folate, transferrin, antibodies, peptides and aptamers. Multiple functionalities can be incorporated into the design of nanoparticles, e.g., to enable imaging and triggered intracellular drug release. In this review, we mainly focus on recent advances on the development of targeted nanocarriers and will introduce novel concepts such as multi-targeting and multi-functional nanoparticles.

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Bacterially-Derived Nanocells for Tumor-Targeted Delivery of Chemotherapeutics and Cell Cycle Inhibitors

Cited by 31 publications

References 90 publications

In vivo characterization of a polymeric nanoparticle platform with potential oral drug delivery capabilities

In vivo characterization of a polymeric nanoparticle platform with potential oral drug delivery capabilities

Molecular Imaging of Biological Gene Delivery Vehicles for Targeted Cancer Therapy: Beyond Viral Vectors

Receptor-targeted nanocarriers for therapeutic delivery to cancer

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