Specific Targets in Tumor Tissue for the Delivery of Therapeutic Genes

Günther, Michael; Wagner, Ernst; Ogris, Manfred

doi:10.2174/1568011053174855

Cited by 38 publications

(20 citation statements)

References 164 publications

(175 reference statements)

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“…New delivery technologies that could overcome the internalization barrier, including the use of dendrimers, are therefore being investigated (19). Improved targeting to solid tumors can also be achieved on conjugation of anticancer drugs to polymers (26), which is believed to arise from the increased permeability of tumor vasculature to macromolecules and limited lymphatic drainage (27 -29).…”

Section: Discussionmentioning

confidence: 99%

Macromolecular delivery of 5-aminolaevulinic acid for photodynamic therapy using dendrimer conjugates

Battah

Balaratnam

Casas

et al. 2007

Molecular Cancer Therapeutics

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Intracellular porphyrin generation following administration of 5-aminolaevulinic acid (5-ALA) has been widely used in photodynamic therapy. However, cellular uptake of 5-ALA is limited by its hydrophilicity, and improved means of delivery are therefore being sought. Highly branched polymeric drug carriers known as dendrimers present a promising new approach to drug delivery because they have a well-defined structure capable of incorporating a high drug payload. In this work, a dendrimer conjugate was investigated, which incorporated 18 aminolaevulinic acid residues attached via ester linkages to a multipodent aromatic core. The ability of the dendrimer to deliver and release 5-ALA intracellularly for metabolism to the photosensitizer, protoporphyrin IX, was studied in the transformed PAM 212 murine keratinocyte and A431 human epidermoid carcinoma cell lines. Up to an optimum concentration of 0

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Section: Discussionmentioning

confidence: 99%

Macromolecular delivery of 5-aminolaevulinic acid for photodynamic therapy using dendrimer conjugates

Battah

Balaratnam

Casas

et al. 2007

Molecular Cancer Therapeutics

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“…Targeted gene therapy is considered as a novel strategy for treating metastasized cancer or therapy refractory tumors owing to the benefit of tumor-specific expression of therapeutic genes including an apoptosis-inducing gene to kill the tumor cells by a cancer-specific promoter (2). The success of this strategy also depends on suitable vectors that can efficiently deliver a therapeutic gene into target cells with minimal toxicity.…”

Section: Introductionmentioning

confidence: 99%

Cancer-Targeted BikDD Gene Therapy Elicits Protective Antitumor Immunity against Lung Cancer

Sher

Liu

Chang

et al. 2011

Molecular Cancer Therapeutics

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Targeted cancer-specific gene therapy is a promising strategy for treating metastatic lung cancer, which is a leading cause of lung cancer-related deaths. Previously, we developed a cancer-targeted gene therapy expression system with high tumor specificity and strong activity that selectively induced lung cancer cell killing without affecting normal cells in immunocompromised mice. Here, we found this cancer-targeted gene therapy, SV-BikDD, composed of the survivin promoter in the VP16-GAL4-WPRE integrated systemic amplifier system to drive the apoptotic gene BikDD, not only caused cytotoxic effects in cancer cells but also elicited a cancer-specific cytotoxic T lymphocyte response to synergistically increase the therapeutic effect and further develop an effective systemic antitumoral immunity against rechallenges of

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“…To overcome this problem, several delivery systems have been studied. Recent efforts toward developing tissue-targeted nucleic acid delivery systems based on synthetic reagents have yielded promising results (26,30,34,47,78,83,87,102). To improve the efficiency of siRNA-loaded polymer NPs, more and more "targeted NPs" are imagined with a surface recovered with a peptide, a chemoattractant agent, or an antibody (Fig.…”

Section: Nanoparticles Used To Deliver Gene Therapymentioning

confidence: 99%

Nanomedicine in GI

Laroui

Wilson

Dalmasso

et al. 2011

American Journal of Physiology-Gastrointestinal and Liver Physi

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Recent advances in nanotechnology offer new hope for disease detection, prevention, and treatment. Nanomedicine is a rapidly evolving field wherein targeted therapeutic approaches using nanotechnology based on the pathophysiology of gastrointestinal diseases are being developed. Nanoparticle vectors capable of delivering drugs specifically and exclusively to regions of the gastrointestinal tract affected by disease for a prolonged period of time are likely to significantly reduce the side effects of existing otherwise effective treatments. This review aims at integrating various applications of the most recently developed nanomaterials that have tremendous potential for the detection and treatment of gastrointestinal diseases.nanoparticles; intestinal tract; diagnosis; therapeutics; nanomaterial; siRNA; gastrointestinal ALTHOUGH NANOMATERIALS (NMs) are widely considered to be an invention of modern science, they actually have a very long history. Nanoparticles (NPs) were empirically used by artisans as far back as the 9th century in Mesopotamia to generate a glittering effect on the surfaces of pots. The first scientific description of nanometer-scale metals was provided by Michael Faraday in his classic paper (25a), but the development of NMs depended mainly on their visualization and the characterization of their physical and chemical properties. Modern instrumental techniques have drastically increased our ability to precisely measure particle size distributions and many other parameters that are correlated with nanoscale objects. For example, techniques such as transmission and scanning electron microscopy and scanning tunneling microscopy have facilitated the direct visualization of individual NPs with atomic accuracy (35,46). As a result of these advances, scientists have developed exquisite and highly sophisticated methods to generate nanoscale materials with different sizes, compositions, and geometries. These nanoscale materials possess unique and unusual properties and are currently used by multidisciplinary teams of scientists in scientific areas that range from physics and engineering to biochemistry. Consequently, the field of nanomedicine has emerged alongside the development of these materials to harness some of their novel properties. Tremendous progress has been made with respect to the synthesis of a variety of materials that can be used as nanovehicles (carbons, synthetic polymers, polysaccharides, and iron, to name a few) (51, 65) and the techniques used to control the shapes and length scales of NMs. The discovery of quantum effects (size-dependent properties) that produce nanomaterials with specific emissive, absorptive, or scattering spectra has broadened the range of their potential applications in areas such as imaging and diagnostics (10,11,33). One of the most attractive applications of NM is as a drug delivery system, in which NMs are used as drug carriers. The potential to target a single cell represents a revolutionary tool for medicine. There are several advantages using NMs: NMs a...

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Specific Targets in Tumor Tissue for the Delivery of Therapeutic Genes

Cited by 38 publications

References 164 publications

Macromolecular delivery of 5-aminolaevulinic acid for photodynamic therapy using dendrimer conjugates

Macromolecular delivery of 5-aminolaevulinic acid for photodynamic therapy using dendrimer conjugates

Cancer-Targeted BikDD Gene Therapy Elicits Protective Antitumor Immunity against Lung Cancer

Nanomedicine in GI

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