Single-molecule kinetics of growth and degradation of cell-penetrating poly(disulfide)s

The delivery of therapeutic agents into target cells is a challenging task. Cell penetration and intracellular targeting were recently addressed with biodegradable cell-penetrating poly(disulfide)s (CPDs). Cellular localization is determined by the length of these polymers, emphasizing the significance of initial chain length and the kinetics of intracellular depolymerization for targeted delivery. In the present study, the kinetics of CPD polymer growth and degradation were monitored in a single-molecule nanoreactor. The chain lengths achievable under synthetic conditions with high concentrations of dithiolanes were then predicted by using the rate constants. For example, CPDs comprising 40 units are generated in 1 s at pH 7.4 and 0.3 s at pH 8.4 at dithiolane concentrations of 200 mM. The rate constants for degradation suggest that the main depolymerization pathway in the cell is by monomer removal by self-cyclization, rather than by intrachain cleavage by endogenous thiols

Relation between the Co-O bond lengths and the spin state of Co in layered Cobaltates: a high-pressure study

The pressure-response of the Co-O bond lengths and the spin state of Co ions in a hybrid 3d-5d solid-state oxide Sr2Co0.5Ir0.5O4 with a layered K2NiF4-type structure was studied by using hard X-ray absorption and emission spectroscopies. The Co-K and the Ir-L-3 X-ray absorption spectra demonstrate that the Ir5+ and the Co3+ valence states at ambient conditions are not affected by pressure. The Co Ka emission spectra, on the other hand, revealed a gradual spin state transition of Co3+ ions from a highspin (S = 2) state at ambient pressure to a complete low-spin state (S = 0) at 40 GPa without crossing the intermediate spin state (S = 1). This can be well understood from our calculated phase diagram in which we consider the energies of the low spin, intermediate spin and high spin states of Co3+ ions as a function of the anisotropic distortion of the octahedral local coordination in the layered oxide. We infer that a short in-plane Co-O bond length (<1.90 angstrom) as well as a very large ratio of Co-O-apex/Co-Oin-plane is needed to stabilize the IS Co3+, a situation which is rarely met in reality