OR WAIT 15 SECS
Wyatt Application Note
The objective of this experiment was to develop a greener synthesis of disulfi de polymers which are reducible under specifi c biological conditions.
The monomer, 3,6-dioxa-1,8-octanedithiol, and triethylamine (1:1.25 equivalent ratio) were reacted under bulk conditions or 10 minutes. To the bulk mixture, 2.0 equivalents of hydrogen peroxide (3% aqueous solution by weight) were added. The polymer was allowed to react with oxidative solution for a given amount of time. It was then removed from the solution, purifi ed in acetone and dried.
Molecular weights of soluble products were determined by Size Exclusion Chromatography (SEC) on a system equipped with six Waters Styragel columns, a Waters 2487 dual absorbance UV detector, an Optilab DSP interferomatic refractometer (Wyatt Technology), a DAWN EOS multi-angle laser light scattering detector (Wyatt Technology) and a ViscoStar viscometer (Wyatt Technology). The data from the SEC was processed using Wyatt's ASTRA software.
Figure 1: Light scattering and rms radius plots for sample EQR-3-7B.
The dn/dc value for the polymer was calculated by two methods: 100% mass recovery (0.116 mL/g) and by RI analysis of a series of polymer dilutions (0.132 mL/g). It was found that the molecular weight of the polymer depends heavily on the reaction time of the oxidative step and on the reaction temperature. Data from two example polymerizations demonstrates the time dependence. Only 9 minutes after the addition of hydrogen peroxide, the reaction reached 73% conversion, and Mn = 14000 g/mol (sample EQR-3-7B). Additional reaction time in the oxidative solution increased the conversion to 90% and Mn to 230000 g/mol (EQR-2-13-062910D).
Figure 2: All detector traces for sample EQR-2-13-062910D.
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