“…We recently reconsidered the structure and conformation of several water-soluble, chemically modified cellulose ether samples in aqueous solution. − It has been widely believed that most water-soluble, chemically modified cellulose derivatives behave as semiflexible polymer chains with finite persistence lengths, e.g., 5–20 nm, in aqueous solution. − However, we found that methyl cellulose (MC) samples with a degree of substitution (DS) = 1.8, hydroxyethyl cellulose (HeC) samples with a molar substitution number, MS, ∼2.4, and hydroxypropylmethyl cellulose (HpMC) samples with a DS = 1.9 and MS ∼ 0.25 possess formation factors that can be reasonably described with rod particles in aqueous solution, as in the case of the HpC samples in this study. − These systems maintained the relationship L / R g ∼ 3.5 characteristic of the rod particles over the M w range examined and demonstrated an increasing change in l c / L data from 2 in the lower M w range to 4 (or more) in the range of M w > 300 kg mol –1 with increasing M w . − Reformation of intramolecular hydrogen bonds between hydroxyl groups on chemically modified cellulose samples is essential for rod-like particle formation. The reason why the dependence of l c / L on M w in the HpC samples found in this study is substantially distinct from that observed in aqueous systems of MC, HeC, and HpMC should be that the molar substitution number, MS, is ∼3.8, which is markedly greater than those of the MC, HeC, and HpMC samples.…”