Highly stable Ni-MOF comprising triphenylamine moieties as a high-performance redox indicator for sensitive aptasensor construction

Electroactive metal-organic frameworks (MOFs) with large surface area and manipulatable structural properties show promise as a new type of signal probe for electrochemical biosensing application. In this work, an electroactive Ni-MOF, assembled by the redox-active ligands 4,4',4″-Tricarboxytriphenylamine (H₃TCA), a triphenylamine derivatives, as the electroactive source and magnetic ordered Ni₄O₄ clusters as electronic transport nodes, is first designed and applied for electrochemical aptasensing of thrombin (Tb). The designed Ni-MOF probe realizes a stable and sensitive electrochemical signal output based on simple sandwich-type aptasensing because the high-content TCA active sites and good magnetic ordered intermediate of Ni₄O₄ clusters are periodically arranged in well-defined porous structure of the MOF. The Ni-MOF probe assembled by redox-active ligand presents the high stability and can be directly applied in electrochemical aptasensor, avoiding any post-modification and the addition of redox mediators. As a result, the constructed electrochemical aptasensor shows a wide linear relationship for Tb from 0.05 pM to 50 nM and a detection limit of 0.016 pM (S/N = 3). Furthermore, the proposed aptasensor is successfully applied to analysis of target Tb in real serum sample with satisfactory results. The present work indicates that fabricating a redox-active organic molecule in functionalized MOFs offer a feasible strategy to design high-stable electroactive MOFs for construction of electrochemical biosensors with simplicity, high selectivity and sensitivity.

Quantum Monte Carlo simulations of a giant {Ni21Gd20} cage with a S = 91 spin ground state

The detailed analysis of magnetic interactions in a giant molecule is difficult both because the synthesis of such compounds is challenging and the number of energy levels increases exponentially with the magnitude and number of spins. Here, we isolated a {Ni₂₁Gd₂₀} nanocage with a large number of energy levels (≈5 × 10³⁰) and used quantum Monte Carlo (QMC) simulations to perform a detailed analysis of magnetic interactions. Based on magnetization measurements above 2 K, the QMC simulations predicted very weak ferromagnetic interactions that would give a record S = 91 spin ground state. Low-temperature measurements confirm the spin ground state but suggest a more complex picture due to the single ion anisotropy; this has also been modeled using the QMC approach. The high spin and large number of low-lying states lead to a large low-field magnetic entropy (14.1 J kg^-1 K^-1 for ΔH = 1 T at 1.1 K) for this material.

A linear trinuclear ferrous single molecule magnet

A linear trinuclear ferrous [FeII3] SMM exhibited clear magnetic hysteresis loops and a significant higher effective energy barrier in comparison with its cobalt(ii) analogue.