SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2316172290> ?p ?o ?g. }

Showing items 1 to 100 of ±164 with 100 items per page.

W2316172290 endingPage "6047" @default.
W2316172290 startingPage "6038" @default.
W2316172290 abstract "Superparamagnetic iron oxide nanoparticles (IONPs) have been studied extensively as negative contrast agents to enhance MRI efficacy. For optimal effective clinical use in T2/T2* weighted MRI imaging, the aim is to maximize relaxivity (r2) of IONPs, and minimize r1 relaxivity. A prerequisite for successful clinical use of magnetic nanoparticles is colloidal stability in biologically relevant media; biocompatible polymers with antifouling properties such as poly(ethylene glycol) (PEG) can be coated on the surface of IONPs, to improve stability and to impart longer blood circulation times. Our research aim was to optimize IONPs for use as contrast agents by achieving high grafting density and therefore colloidal stability, while retaining the magnetic properties of the IONP core. To attain the optimal material design the chemical functionalities and chain length of the polymeric layer must be precisely controlled. In this paper we describe the synthesis of poly(oligoethylene glycol acrylate) (P(OEGA)) functionalized magnetic iron oxide nanoparticles (IONP) made using a grafting “from” approach. Cu(0)-mediated living radical polymerization (LRP) was used to grow polymer chains of predetermined length from the surface of prefunctionalized IONPs. The polymers chain were further extended via an iterative addition of the same (or another) monomer with high efficiency demonstrating the retention of polymer chain end functionality. IONPs with different lengths of the P(OEGA) layer were also synthesized using a grafting “to” approach as a comparison study. Colloidal stabilities and MRI relaxivites of functionalized IONPs were investigated in both water and fetal calf serum (FCS). The grafting “from” approach proved to be superior to the grafting “to” approach as we were able to produce polymer coated IONPs with much higher r2 / r1 relaxivity ratios in water. At 9.4 T, the r2/r1 relaxivity values that we attained were about 6-fold higher than the commercial, clinically used, MRI contrast agent Resovist." @default.
W2316172290 created "2016-06-24" @default.
W2316172290 creator A5001395511 @default.
W2316172290 creator A5003954971 @default.
W2316172290 creator A5017902199 @default.
W2316172290 creator A5017973525 @default.
W2316172290 creator A5022973829 @default.
W2316172290 creator A5031327274 @default.
W2316172290 date "2013-08-02" @default.
W2316172290 modified "2023-10-13" @default.
W2316172290 title "Grafting of P(OEGA) Onto Magnetic Nanoparticles Using Cu(0) Mediated Polymerization: Comparing Grafting “from” and “to” Approaches in the Search for the Optimal Material Design of Nanoparticle MRI Contrast Agents" @default.
W2316172290 cites W1560609297 @default.
W2316172290 cites W1964958595 @default.
W2316172290 cites W1967491683 @default.
W2316172290 cites W1967732157 @default.
W2316172290 cites W1970954421 @default.
W2316172290 cites W1973762887 @default.
W2316172290 cites W1975746685 @default.
W2316172290 cites W1975861706 @default.
W2316172290 cites W1980122435 @default.
W2316172290 cites W1984364596 @default.
W2316172290 cites W1984906180 @default.
W2316172290 cites W19859413 @default.
W2316172290 cites W1987615670 @default.
W2316172290 cites W1990796256 @default.
W2316172290 cites W1993177238 @default.
W2316172290 cites W1993475836 @default.
W2316172290 cites W1994637691 @default.
W2316172290 cites W1997617616 @default.
W2316172290 cites W1999890986 @default.
W2316172290 cites W2000068330 @default.
W2316172290 cites W2002063000 @default.
W2316172290 cites W2004016712 @default.
W2316172290 cites W2008216183 @default.
W2316172290 cites W2010939247 @default.
W2316172290 cites W2012591139 @default.
W2316172290 cites W2012719370 @default.
W2316172290 cites W2012789401 @default.
W2316172290 cites W2013440195 @default.
W2316172290 cites W2014721045 @default.
W2316172290 cites W2023562421 @default.
W2316172290 cites W2029129350 @default.
W2316172290 cites W2031147516 @default.
W2316172290 cites W2033007989 @default.
W2316172290 cites W2040540163 @default.
W2316172290 cites W2048192248 @default.
W2316172290 cites W2052883298 @default.
W2316172290 cites W2054949603 @default.
W2316172290 cites W2055134818 @default.
W2316172290 cites W2059815554 @default.
W2316172290 cites W2061166520 @default.
W2316172290 cites W2061690699 @default.
W2316172290 cites W2065507993 @default.
W2316172290 cites W2067486445 @default.
W2316172290 cites W2068809896 @default.
W2316172290 cites W2069247663 @default.
W2316172290 cites W2069943212 @default.
W2316172290 cites W2069946601 @default.
W2316172290 cites W2071436231 @default.
W2316172290 cites W2075337839 @default.
W2316172290 cites W2075741216 @default.
W2316172290 cites W2076338426 @default.
W2316172290 cites W2078544750 @default.
W2316172290 cites W2079011492 @default.
W2316172290 cites W2082769422 @default.
W2316172290 cites W2083113159 @default.
W2316172290 cites W2083844537 @default.
W2316172290 cites W2084871302 @default.
W2316172290 cites W2085056001 @default.
W2316172290 cites W2087803454 @default.
W2316172290 cites W2096768424 @default.
W2316172290 cites W2099914775 @default.
W2316172290 cites W2101782398 @default.
W2316172290 cites W2104687956 @default.
W2316172290 cites W2107525560 @default.
W2316172290 cites W2117412515 @default.
W2316172290 cites W2125234021 @default.
W2316172290 cites W2131838288 @default.
W2316172290 cites W2132005699 @default.
W2316172290 cites W2143896522 @default.
W2316172290 cites W2146002957 @default.
W2316172290 cites W2154964751 @default.
W2316172290 cites W2166222229 @default.
W2316172290 cites W2169892080 @default.
W2316172290 cites W2316585167 @default.
W2316172290 cites W2333891198 @default.
W2316172290 doi "https://doi.org/10.1021/ma401250f" @default.
W2316172290 hasPublicationYear "2013" @default.
W2316172290 type Work @default.
W2316172290 sameAs 2316172290 @default.
W2316172290 citedByCount "63" @default.
W2316172290 countsByYear W23161722902013 @default.
W2316172290 countsByYear W23161722902014 @default.
W2316172290 countsByYear W23161722902015 @default.
W2316172290 countsByYear W23161722902016 @default.
W2316172290 countsByYear W23161722902017 @default.
W2316172290 countsByYear W23161722902018 @default.
W2316172290 countsByYear W23161722902019 @default.