As a trust machine, blockchain was recently introduced to the public to provide an immutable, consensus based and transparent system in the Fintech field. However, there are ongoing efforts to apply blockchain to other fields where trust and value are essential. In this paper, we suggest Gcoin blockchain as the base of the data flow of drugs to create transparent drug transaction data. Additionally, the regulation model of the drug supply chain could be altered from the inspection and examination only model to the surveillance net model, and every unit that is involved in the drug supply chain would be able to participate simultaneously to prevent counterfeit drugs and to protect public health, including patients.
Anodic TiO2 nanotubes have been studied extensively for many years. However, the growth kinetics still remains unclear. The systematic study of the current transient under constant anodizing voltage has not been mentioned in the original literature. Here, a derivation and its corresponding theoretical formula are proposed to overcome this challenge. In this paper, the theoretical expressions for the time dependent ionic current and electronic current are derived to explore the anodizing process of Ti. The anodizing current-time curves under different anodizing voltages and different temperatures are experimentally investigated in the anodization of Ti. Furthermore, the quantitative relationship between the thickness of the barrier layer and anodizing time, and the relationships between the ionic/electronic current and temperatures are proposed in this paper. All of the current-transient plots can be fitted consistently by the proposed theoretical expressions. Additionally, it is the first time that the coefficient A of the exponential relationship (ionic current j(ion) = A exp(BE)) has been determined under various temperatures and voltages. And the results indicate that as temperature and voltage increase, ionic current and electronic current both increase. The temperature has a larger effect on electronic current than ionic current. These results can promote the research of kinetics from a qualitative to quantitative level.
Anodic TiO 2 nanotubes (ATNTs) have been studied extensively for many years. However, their mysterious formation mechanism still remains unclear. The formation of gaps and ribs around the nanotubes has not been elucidated. Here, various surface and cross-section morphologies of ATNTs obtained under different anodizing conditions and their evolution process have been investigated in detail. Based on many experimental facts, new explanations for the gaps and ribs are presented. An entire surface layer covered on the nanotubes plays a primary role on the formation of gaps and ribs. The gaps result from the radial distribution of the electric field at the pore bottom. No newly-formed oxide will exist along the gap direction, because the electric filed along the gap is the minimum. The ribs result from the electrolyte entering into the wider gaps among the ATNTs due to the rupture of the entire surface layer. The rings or ribs on the outer wall of ATNTs are formed at the electrolyte/Ti interface due to the discontinuous existence of a small amount of electrolyte within the gap base. The present viewpoint was demonstrated by an original micro-dam, which can block the electrolyte entering into the gaps and avoid the formation of ribs.
Intrinsically disordered
proteins (IDPs) exist in highly dynamic
conformational ensembles, which pose a major obstacle for drug development
targeting IDPs because traditional rational drug design relies on
unique three-dimensional structures. Here, we analyzed the conservation
(especially structural conservation) of potentially druggable cavities
in 22 ensembles of IDPs. It was found that there is considerable conservation
for potentially druggable cavities within each ensemble. The average
common atom percentage of potentially druggable cavities is as high
as 54%. The average root-mean-squared deviation of common atoms ranges
between 1 and 8 Å for multichain IDPs, and a common pocket is
kept after direct alignment of cavities. In addition, the conservation
of potentially druggable cavities varies among different proteins.
In the comparison of multi- and single-chain IDPs, some multichain
IDPs have an extremely high conservation, whereas another multichain
IDPs’ conservation appears worse, and the single-chain IDPs
have relatively moderate conservations. This study is a new attempt
to generally assess the potentially druggable cavities in IDPs for
taking IDPs as druggable targets, and this work also lends support
to the opinion of IDPs tending to bind to “multiconformational
affinity” compounds.
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