Biomedical Engineering Reference
In-Depth Information
[14] Z Ding, RB Fong, CJ Long, PS Stayton, et al., Size-dependent control of the binding of
biotinylated proteins to streptavidin using a polymer shield, Nature 411(6833) (2001) 59-62.
[15] H Maeda, SMANCS and polymer-conjugated macromolecular drugs: Advantages in cancer
chemotherapy, Advanced Drug Delivery Reviews 6(2) (1991) 181-202.
[16] R Duncan, J Kopecek, Soluble synthetic polymers as potential drug carriers, Advances in
Polymer Science 57 (1984) 51-101.
[17] AS Hoffman, PS Stayton, O Press, N Murthy, et al., Design of "Smart" Polymers that can
direct intracellular drug delivery, Polymers for Advanced Technologies 13 (2002) 992-999.
[18] AS Hoffman, PS Stayton, O Press, N Murthy, et al., Bioinspired polymers that control
intracellular drug delivery, Biotechnology and Bioprocess Engineering 6 (2001) 205-212.
[19] N Murthy, JR Robichaud, DA Tirrell, PS Stayton, et al., The design and synthesis of
polymers for eukaryotic membrane disruption, Journal of Controlled Release 61 (1999) 137-
143.
[20] R Duncan, P Ferruti, D Sgouras, A Tuboku-Metzger, et al., A polymer-Triton X-100
conjugate capable of pH-dependent red blood cell lysis: A model system illustrating the
possibility of drug delivery within acidic intracellular compartments, Journal of Drug
Targeting 2 (1994) 341-347.
[21] A Licea-Claverie, E Rogel-Hernandez, R Salgado-Rodriguez, JA Lopez-Sanchez, et al., The
use of hydrophobic spacers in the development of new temperature- and pH-sensitive
polymers, Macromolecular Symposia 207(Fundamentals and Applications of Polymer Gels)
(2004) 193-215.
[22] X Guan, Z Liu, Z Su, Synthesis and photophysical behaviors of temperature/pH-sensitive
polymeric materials, European Polymer Journal 43(7) (2007) 3094-3105.
[23] MG Neumann, IA Pastre, AM Chinelatto, OA El Seoud, Effects of the structure of anionic
polyelectrolytes on surface potentials of their aggregates in water, Colloid and Polymer
Science 274(5) (1996) 475-481.
[24] MS Donovan, BS Sumerlin, AB Lowe, CL McCormick, Controlled/living polymerization of
sulfobetaine monomers directly in aqueous media via raft, Macromolecules 35 (2002) 8663-
8666.
[25] SI Kang, YH Bae, pH-Induced volume-phase transition by reversible crystal formation,
Macromolecules 34 (2001) 8173-8178.
[26] T Traitel, R Goldbart, J Kost, Smart polymers for responsive drug-delivery systems, Journal
of Biomaterial Sciences, Polymer Edition 19(6) (2008) 755-767.
[27] O Korostynska, K Arshak, E Gill, A Arshak, Review on state-of-the-art in polymer based pH
sensors, Sensors 7 (2007) 3027-3042.
[28] A Benrebouh, D Avoce, XX Zhu, Thermo- and pH-sensitive polymers containing cholic acid
derivatives, Polymer 42 (2001) 4031-4038.
[29] HC Chiu, AT Wu, YF Lin, Synthesis and characterization of acrylic acid-containing dextran
hydrogels, Polymer 42 (2001) 1471-1479.
[30] EEL Kathmann, LA White, CA McCormick, Water-soluble polymers 73. Electrolyte- and
pH-responsive zwitter ionic copolymers of 4-[2-acrylamido-2-methylpropyl)-di-
methylammonio]butanoate with 3-[(acrylamio-2-methyl-
propyl)dimethylammonio]propanesulfonate, Macromolecules 30 (1997) 5297-5304.
[31] SI Kang, YH Bae, pH-Induced solubility transition of sulfonamide-based polymers, Journal
of Controlled Release 80 (2002) 145-155.
[32] M Sakata, M Todokoro, T Kai, M Kunitake, et al., Effect of cationic polymer adsorbent pKa
on the selective removal of endotoxin from an albumin solution, Chromatographia 53 (2001)
619-623.
[33] SH Yuk, SH Cho, SH Lee, pH/Temperature-responsive polymer composed of poly(
N,N
-
dimethylamino)ethyl methacrylate-co-ethylacrylamide, Macromolecules 30 (1997) 6856-
6859.
Search WWH ::
Custom Search