Team:SupBiotech-Paris/Bibliographie

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Revision as of 17:41, 20 October 2009

Accueil	Équipe	Gestion de projet	Galerie	Remerciements

Chapitre	Ref.	Auteurs	Titre	Année
Thérapie actuelle	[1]	Lechat P.	Pharmacology	2006
Thérapie actuelle	[2]	Bruguerolle B.	Biological rhythms and medications: a source of variability often neglected in pharmacology	2008
Thérapie genique	[1]	Kevin J. Scanlon and al.	Cancer Gene Therapy: Challenges and Opportunities	2004
Thérapie genique	[2]	Gouze JN and al.	A comparative study of the inhibitory effects of interleukin-1 receptor antagonist following administration as a recombinant protein or by gene transfer	2003
Thérapie génique	[3]	Centre for Genetics Education	http://www.genetics.com.au/index.asp	XXXX
Vectorisation	[1]	Couvreur P.	L'encapsulation de médicament	2003
Vectorisation	[2]	Andrieux K. and al.	Nanotechnology and new drug	2003
Vectorisation	[3]	Torchilin V.P.	Recent Approaches to Intracellular Delivery of Drugs and DNA and Organelle Targeting	2006
Vectorisation	[4]	Davis M.E. and al.	Nanoparticle therapeutics: an emerging treatment modality for cancer	2008
Vectorisation	[5]	Seow Y. and al.	Biological Gene Delivery Vehicles: Beyond Viral Vectors	2009
Vectorisation	[6]	Decroly E.	Vectorology	2005
Vectorisation	[7]	Robbins P.D. and al.	Viral Vectors for Gene Therapy	1998
Vectorisation	[8]	Wei M.Q. and al.	Bacterial targeted tumour therapy-dawn of a new era	2008
Vectorisation	[9]	Ryan R.M. and al.	Use of bacteria in anti-cancer therapies	2005
Vectorisation	[10]	Mehnert	Solid lipid nanoparticles: Production, characterization and applications	2001
Vectorisation	[11]	Lasic D.D.	Liposomes in gene therapy	1996
Vectorisation	[12]	Lutten J. and al.	Biodegradable polymers as non-viral carriers for plasmid DNA delivery	2008
Vectorisation	[13]	Jiskoot W. and al.	Immunological Risk of Injectable Drug Delivery Systems	2009
Vectorisation	[14]	Head M. and al.	Mechanism and computer simulation of immune complex formation, opsonization, and clearance	1996
Vectorisation	[15]	Koide H. and al.	Particle size-dependent triggering of accelerated blood clearance phenomenon	2008
Vectorisation	[16]	Ishida T. and al.	Accelerated blood clearance of PEGylated liposomes following preceding liposome injection: Effects of lipid dose and PEG surface-density and chain length of the first-dose liposomes	2005
Vectorisation	[17]	Wang XY and al.	Anti-PEG IgM elicited by injection of liposomes is involved in the enhanced blood clearance of a subsequent dose of PEGylated liposomes	2007
Vectorisation	[18]	Tosi M.F. and al.	Innate immune responses to infection	2005
Vectorisation	[19]	Linkov I and al.	Nanotoxicology and nanomedicine: making hard decisions	2008
Vecteur Tissulaire	[1]	Ronald S. and al.	Antimicrobial mechanisms of phagocytes and bacterial evasion strategies	2009
Vecteur Tissulaire	[2]	Clark B. Inderlied and al.	The Mycobacterium avium Complex	1993
Vecteur Tissulaire	[3]	Nisheeth Agarwal and al.	Cyclic AMP intoxication of macrophages by a Mycobacterium tuberculosis adenylate cyclase	2009
Vecteur Tissulaire	[4]	Hunter R.L. and al.	Pathology of postprimary tuberculosis in humans and mice: contradiction of long-held beliefs	2007
Vecteur Tissulaire	[5]	Axelrod S and al.	Delay of phagosome maturation by a mycobacterial lipid is reversed by nitric oxide	2008
Vecteur Tissulaire	[6]	Nicole N van der Wel and al.	Subcellular localization of mycobacteria in tissues and detection of lipid antigens in organelles using cryo-techniques for light and electron microscopy	2005
Vecteur Tissulaire	[7]	Claudia Nobrega and al.	The thymus as a target for mycobacterial infections	2007
Vecteur Cellulaire	[1]	Harrison Echols and al.	Genetic Map of Bacteriophage Lambda	1978
Vecteur Cellulaire	[2]	Joseph Sambrook and al.	Molecular Cloning: A Laboratory Manual (Third Edition)	2001
Vecteur Cellulaire	[3]	Court DL and al.	A New Look at Bacteriophage lambda Genetic Networks	2007
Vecteur Cellulaire	[4]	Ortega ME and al.	Bacteriophage Lambda gpNu1 and Escherichia coli IHF Proteins Cooperatively Bind and Bend Viral DNA: Implications for the Assembly of a Genome-Packaging Motor	2006
Vecteur Cellulaire	[5]	Feiss M. and al.	Bactériophage Lambda Terminase and the Mechanism of Viral DNA Packaging	2005
Vecteur Cellulaire	[6]	Hang JQ and al.	The Functional Asymmetry of cosN, the Nicking Site for Bacteriophage λ DNA Packaging, Is Dependent on the Terminase Binding Site, cosB	2001
Vecteur Cellulaire	[7]	Becker A and al.	Bacteriophage lambda DNA : The begginning of the End	1990
Vecteur Cellulaire	[8]	Hochschild A and al.	The bactériophage lambda cI protein finds an asymmetric solution	2009
Vecteur Cellulaire	[9]	Phoebe L.Stewart1 and al.	Cryo-EM visualization of an exposed RGD epitope on adenovirus that escapes antibody neutralization	1997
Plasmide thérapeutique	[1]	Ortega ME et al.	Bacteriophage lambda gpNu1 and Escherichia coli IHF proteins cooperatively bind and bend viral DNA: implications for the assembly of a genome-packaging motor	2006
Plasmide thérapeutique	[2]	Joseph Sambrook and al.	Molecular Cloning: A Laboratory Manual (Third Edition)	2001
Plasmide thérapeutique	[3]	Court DL and al.	A New Look at Bacteriophage lambda Genetic Networks	2007
Plasmide thérapeutique	[4]	Feiss M. and al.	Viral Genome Packaging Machines: Genetics, Structure and Mechanism	2005
Plasmide thérapeutique	[5]	Hang JQ and al.	The Functional Asymmetry of cosN, the Nicking Site for Bacteriophage λ DNA Packaging, Is Dependent on the Terminase Binding Site, cosB	2001
Plasmide thérapeutique	[6]	Becker A and al.	Bacteriophage lambda DNA : The begginning of the End	1990
Plasmide thérapeutique	[7]	Young et al.	Effect of a DNA nuclear targeting sequence on gene transfer and expression of plasmids in the intact vasculature	2003
	[]

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@@ Line 48: / Line 48: @@
 |height=40px|Vectorisation
 |[1]
-|
+|Couvreur P.
-|
+|L'encapsulation de médicament
-|
+|2003
 |- style="background: white; text-align: center;"
 |height=40px|Vectorisation
 |[2]
-|
+|Andrieux K. and al.
-|
+|Nanotechnology and new drug
-|
+|2003
 |- style="background: #C0C0C0; text-align: center;"
 |height=40px|Vectorisation
 |[3]
-|
+|Torchilin V.P.
-|
+|Recent Approaches to Intracellular Delivery of Drugs and DNA and Organelle Targeting
-|
+|2006
 |- style="background: white; text-align: center;"
 |height=40px|Vectorisation
 |[4]
-|
+|Davis M.E. and al.
-|
+|Nanoparticle therapeutics: an emerging treatment modality for cancer
-|
+|2008
 |- style="background: #C0C0C0; text-align: center;"
 |height=40px|Vectorisation
 |[5]
-|
+|Seow Y. and al.
-|
+|Biological Gene Delivery Vehicles: Beyond Viral Vectors
-|
+|2009
 |- style="background: white; text-align: center;"
 |height=40px|Vectorisation
 |[6]
-|
+|Decroly E.
-|
+|Vectorology
-|
+|2005
 |- style="background: #C0C0C0; text-align: center;"
 |height=40px|Vectorisation
 |[7]
-|
+|Robbins P.D. and al.
-|
+|Viral Vectors for Gene Therapy
-|
+|1998
 |- style="background: white; text-align: center;"
 |height=40px|Vectorisation
 |[8]
-|
+|Wei M.Q. and al.
-|
+|Bacterial targeted tumour therapy-dawn of a new era
-|
+|2008
 |- style="background: #C0C0C0; text-align: center;"
 |height=40px|Vectorisation
 |[9]
-|
+|Ryan R.M. and al.
-|
+|Use of bacteria in anti-cancer therapies
-|
+|2005
 |- style="background: white; text-align: center;"
 |height=40px|Vectorisation
 |[10]
-|
+|Mehnert
-|
+|Solid lipid nanoparticles: Production, characterization and applications
-|
+|2001
 |- style="background: #C0C0C0; text-align: center;"
 |height=40px|Vectorisation
 |[11]
-|
+|Lasic D.D.
-|
+|Liposomes in gene therapy
-|
+|1996
 |- style="background: white; text-align: center;"
 |height=40px|Vectorisation
 |[12]
-|
+|Lutten J. and al.
-|
+|Biodegradable polymers as non-viral carriers for plasmid DNA delivery
-|
+|2008
 |- style="background: #C0C0C0; text-align: center;"
 |height=40px|Vectorisation
 |[13]
-|
+|Jiskoot W. and al.
-|
+|Immunological Risk of Injectable Drug Delivery Systems
-|
+|2009
 |- style="background: white; text-align: center;"
 |height=40px|Vectorisation
 |[14]
-|
+|Head M. and al.
-|
+|Mechanism and computer simulation of immune complex formation, opsonization, and clearance
-|
+|1996
 |- style="background: #C0C0C0; text-align: center;"
 |height=40px|Vectorisation
 |[15]
-|
+|Koide H. and al.
-|
+|Particle size-dependent triggering of accelerated blood clearance phenomenon
-|
+|2008
+|- style="background: white; text-align: center;"
+|height=40px|Vectorisation
+|[16]
+|Ishida T. and al.
+|Accelerated blood clearance of PEGylated liposomes following preceding liposome injection: Effects of lipid dose and PEG surface-density and chain length of the first-dose liposomes
+|2005
+|- style="background: #C0C0C0; text-align: center;"
+|height=40px|Vectorisation
+|[17]
+|Wang XY and al.
+|Anti-PEG IgM elicited by injection of liposomes is involved in the enhanced blood clearance of a subsequent dose of PEGylated liposomes
+|2007
+|- style="background: white; text-align: center;"
+|height=40px|Vectorisation
+|[18]
+|Tosi M.F. and al.
+|Innate immune responses to infection
+|2005
+|- style="background: #C0C0C0; text-align: center;"
+|height=40px|Vectorisation
+|[19]
+|Linkov I and al.
+|Nanotoxicology and nanomedicine: making hard decisions
+|2008
 |- style="background: white; text-align: center;"