The Induction Period in Chain Reactions

Versatile synthesis of metal-compound based mesoporous Janus nanoparticles

The construction of mesoporous Janus nanoparticles (mJNPs) with controllable components is of great significance for the development of sophisticated nanomaterials with synergistically enhanced functionalities and applications. However, the compositions of reported mJNPs are mainly the functionally inert SiO₂ and polymers. The universal synthesis of metal-compound based mJNPs with abundant functionalities is urgently desired, but remains a substantial challenge. Herein, we present a hydrophilicity mediated interfacial selective assembly strategy for the versatile synthesis of metal-compound based mJNPs. Starting from the developed silica-based mJNPs with anisotropic dual-surface of hydrophilic SiO₂ and hydrophobic organosilica, metal precursor can selectively deposit onto the hydrophilic SiO₂ subunit to form the metal-compound based mJNPs. This method shows good universality and can be used for the synthesis of more than 20 kinds of metal-compound based mJNPs, including alkali-earth metal compounds, transition metal compounds, rare-earth metal compounds etc. Besides, the composition of the metal-compound subunit can be well tuned from single to multiple metal elements, even high-entropy complexes. We believe that the synthesis method and obtained new members of mJNPs provide a very broad platform for the construction and application of mJNPs with rational designed functions and structures.

A sensitive assay for the pharmacokinetic investigation of a rapidly hydrolyzing alkylating agent Lycurim (ritrosulfan; R-74; NSC-122 402)

Lycurim [1,4-di(2'-methanesulfonyloxyethylamino)-1,4-dideoxymesoerythri tol dimethane sulfonate] is rapidly hydrolyzed in aqueous media to inactive products according to a second-order reaction. The respective rate constants are: k1 = 9.82 X 10(-2) and k2 = 1.76 X 10(-2) mumol/ml/min. The concentrations of the parent compound and alkylating intermediate(s) were measured by chemical trapping with N,N-diethyldithiocarbamic acid (DDTC). The rate of this reaction is substantially higher: k1 = 2.61 X 10(-1) and K2 = 4.76 X 10(-2) mumol/ml/min. By using 35S-labeled DDTC, alkylating compounds in concentrations as low as 0.04 microgram/ml could be detected in spiked plasma samples. After intracavitary application of 60 mg Lycurim no alkylating activity could be demonstrated in the plasma of patients at any time point.

'Steady/equilibrium approximation' in relaxation and fluctuation. I. Procedure to simplify first-order reaction

A general procedure to simplify a complex first-order reaction by two approximations, the principle of fast equilibration and the steady-state approximation, is presented. Rate constants are classified into two groups: those of the order of unity and those of the order of epsilon (much less than 1) or less, and are represented in the schemes by thick and thin arrows, respectively. The fast and the slow components are defined: from the fast component at least one thick arrow originates and from the slow component no thick arrow originates. Fast components are divided into several groups. In a group, the fast components are connected by thick arrows in both directions in each reaction step. When at least one thick arrow originates from the components in a group G and terminates on a component not belonging to group G (group G is open), then the steady-state approximation or principle of fast equilibration holds on each component in group G after an induction period To. When no thick arrow originating from group G is directed to components not belonging to group G (group G is closed), the principle of fast equilibration holds on the fast components in group G after To. The induction period To is less than the order of 1/epsilon.