] [37] [26] [37] [37] [26] [26] [26] [26] [26] [26]22,67 [26] [26] [38] 38

] [37] [26] [37] [37] [26] [26] [26] [26] [26] [26]22,67 [26] [26] [38] 38 67 [26] 67 [26] 38 [38] 38 [38] 38 [38] 38 [38] 38 [38] 38 [38] [38] 38 [38] 38 [38]All polymerizations had been performed beneath Caspase-11 Proteins medchemexpress reverse addition situations (monomer added to
] [37] [26] [37] [37] [26] [26] [26] [26] [26] [26]22,67 [26] [26] [38] 38 67 [26] 67 [26] 38 [38] 38 [38] 38 [38] 38 [38] 38 [38] 38 [38] [38] 38 [38] 38 [38]All polymerizations were performed under reverse addition conditions (monomer added to oxidant). two Weight-average 3 9All polymerizations had been performed beneath reverse addition conditions (monomer added to oxidant). 2 Weight-average four 11,528 38 molecular weight (Mw) in the neutral underPBOOT addition circumstances (monomer added to oxidant). two Weight-average = All polymerizations had been performed (undoped) polymers in g/mol. Weight-average degree of polymerization (Xw [38] reverse molecular weight could be the molecular weight in the repeat unit).in g/mol. 3 Weight-average degree of polymerization (Xw = Mw/M0, where M0 (Mw) of your neutral (undoped) polymers in g/mol. 3 Weight-average degree 11,528 9 PBOOT 4 38 [38] molecular weight (Mw) on the neutral (undoped) polymers of polymerization (Xw = of PBOOT unit). the repeat Mw/M0, exactly where M0 would be the molecular weightPBOOT 4 11,528 38 9 four 11,528 38 [38] [38] Mw/M0, where M0 is the molecular weight of reverse addition 1 All polymerizations have been performed below the repeat unit). circumstances (monomer added to oxidant). two Weight-average Numerous research have already been conducted to examine the effects of varying MMP-19 Proteins medchemexpress distinct reac3 Weight-average degree of polymerization (Xw molecular weight (Mw) on the neutral (undoped) have beenin circumstances to examine the effects of varying different=reac1 All polymerizations were performed beneath reverse addition g/mol. (monomer Weight-average Several studies polymers reaction temperature, added to oxidant). 22 concentration, 1 All polymerizations had been tion parameters. reverse addition conditions (monomer solvent, monomer Weight-average and Varying been performed performed added to oxidant). Numerous of addition circumstances carried out to to oxidant). 2 degree of polymerization (X 1 All w/M0, exactly where M0 would be the molecular weightstudies haveunit). (monomer addedexamine the effects of varying distinctive reacM polymerizations have been performed neutral underthe repeat the in g/mol. 3 Weight-average Weight-average molecular weightw = molecular weight (Mw) of tion beneath reverse Varying the reaction temperature, solvent, monomer concentration, and the parameters. (undoped) polymers three the neutral (undoped) polymers in g/mol. three Weight-average degree of polymerization (Xw = tion parameters. Varying unit). (Mmolecular weight (Mw) of monomer/oxidant ratio can affect of polymerization (Xwsolvent, 0polymer0 regioregularity and degree reaction yields also as , exactly where M concentration, w ) w/M0, neutral (undoped) molecular weight of the repeat the reaction temperature, = Mw /M monomeris the molecular M of your where M0 would be the polymers in g/mol. Weight-average impact reaction yields as well as polymer regioregularity and monomer/oxidant (summarized in Table 2) [169,392]. Reduced reaction temperatures Mw of the repeat unit). weight/M0, where M0 may be the molecular weight of the ratio can have an effect on reaction yields at the same time effects of varying distinctive reacmolecular weight ratio can monomer/oxidant repeat unit). carried out to examine the as polymer regioregularity and Quite a few studies have beenmolecular weight (summarized in of a slight reduction in yield [40]. Polymers ready Table two) [169,392]. enhance polydispersity atthe reaction temperature, solvent,Reduced reaction temperatures the molecular weight (summarized in Table to examine the effects of varying temperatures ti.