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Nanoparticles and brain tumor treatment / Gerardo Caruso [and others].

Contributor(s):

Caruso, Gerardo

Material type: Text

TextPublisher number: 860038 | asmeSeries: Biomedical & nanomedical technologiesPublication details: New York, N.Y. : ASME ; [New York, N.Y.] (222 East 46th Street, New York, NY 10017) : Momentum Press, 2012.Description: 1 online resource (viii, 99 pages) : illustrationsContent type:

text

Media type:

computer

Carrier type:

online resource

ISBN:

9781606504086
1606504088
9781606504222
1606504223
1283896060
9781283896061

Other title:

Available from some providers with title: Application of nanoparticles in brain tumor treatment

Subject(s): Genre/Form:

Additional physical formats: Print version:: Nanoparticles and brain tumor treatment.DDC classification:

610.284 23

LOC classification:

R857.N34 N253 2012

NLM classification:

2013 A-196
WL 358

Online resources:

Click here to access online

Contents:

1. Introduction.

2. Glioma biology -- 2.1 Invasion and angiogenesis.

3. Blood-brain barrier -- 3.1 Blood-brain barrier physiology -- 3.2 Blood-brain barrier transport systems.

4. Nanomedicine and nanotechnology -- 4.1 Nanoparticle drug delivery -- 4.1.1 Nanoparticle distribution -- 4.1.2 Nanoparticle functionalization -- 4.1.3 Nanoparticle targeting -- 4.2 Nanomedicine and cancer -- 4.3 Nanomedicine and toxicity.

5. Nanoparticle technologies -- 5.1 Polymeric and polymer-drug conjugate nanoparticles -- 5.2 Micelle nanoparticles -- 5.3 Liposomes -- 5.4 Gold and silver nanoparticles -- 5.5 Metal oxide -- 5.6 Magnetic nanoparticles -- 5.7 Carbon nanotubes -- 5.8 Fullerenes -- 5.9 Peptides nanoparticles -- 5.10 Silica nanoparticles -- 5.11 Quantum dots -- 5.12 Dendrimers.

6. Nanomedicine applications in brain tumors -- 6.1 Brain tumor drug targeting -- 6.1.1 Systemic approaches -- 6.1.2 Physiological approaches -- 6.1.2.1 Receptor-mediated transcytosis -- 6.1.2.2 Adsorptive-mediated transcytosis -- 6.1.2.3 Efflux pump inhibition -- 6.1.2.4 Cell-mediated drug transport -- 6.1.3 Direct CNS approaches -- 6.1.3.1 Intracerebral routes -- 6.1.4 Drug modifications and prodrugs.

7. Experimental studies.

8. Conclusions -- References.

Abstract: Despite progresses in surgery, radiotherapy, and in chemotherapy, an effective curative treatment of gliomas does not yet exist. Mortality is still close to 100% and the average survival of patients with GBM is less than 1 year. The efficacy of current anti-cancer strategies in brain tumors is limited by the lack of specific therapies against malignant cells. Besides, the delivery of the drugs to brain tumors is limited by the presence of the blood brain barrier. The oncogenesis of gliomas is characterized by several biological processes and genetic alterations, involved in the neoplastic transformation. The modulation of gene expression to more levels, such as DNA, mRNA, proteins and transduction signal pathways, may be the most effective modality to down-regulate or silence some specific gene functions. Gliomas are characterized by extensive microvascular proliferation and a higher degree of vasculature. In malignant gliomas targeted therapies efficacy is low. In this complex field, it seems to be very important to improve specific selective drugs delivery systems. Drugs, antisense oligonucleotides, small interference RNAs, engineered monoclonal antibodies and other therapeutic molecules may diffuse into CNS overcoming the BBB. Nanotechnology could be used both to improve the treatment efficacy and to reduce the adverse side effects.

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Item type	Home library	Collection	Call number	Materials specified	Status	Date due	Barcode
Electronic-Books	OPJGU Sonepat- Campus	E-Books EBSCO			Available

Online resource; title from PDF title page (Momentum Press, viewed April 12, 2013).

Includes bibliographical references (pages 81-99).

1. Introduction.

2. Glioma biology -- 2.1 Invasion and angiogenesis.

3. Blood-brain barrier -- 3.1 Blood-brain barrier physiology -- 3.2 Blood-brain barrier transport systems.

7. Experimental studies.

8. Conclusions -- References.

Despite progresses in surgery, radiotherapy, and in chemotherapy, an effective curative treatment of gliomas does not yet exist. Mortality is still close to 100% and the average survival of patients with GBM is less than 1 year. The efficacy of current anti-cancer strategies in brain tumors is limited by the lack of specific therapies against malignant cells. Besides, the delivery of the drugs to brain tumors is limited by the presence of the blood brain barrier. The oncogenesis of gliomas is characterized by several biological processes and genetic alterations, involved in the neoplastic transformation. The modulation of gene expression to more levels, such as DNA, mRNA, proteins and transduction signal pathways, may be the most effective modality to down-regulate or silence some specific gene functions. Gliomas are characterized by extensive microvascular proliferation and a higher degree of vasculature. In malignant gliomas targeted therapies efficacy is low. In this complex field, it seems to be very important to improve specific selective drugs delivery systems. Drugs, antisense oligonucleotides, small interference RNAs, engineered monoclonal antibodies and other therapeutic molecules may diffuse into CNS overcoming the BBB. Nanotechnology could be used both to improve the treatment efficacy and to reduce the adverse side effects.

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