Dioxygen Activation by Iron Complexes: The Catalytic Role of Intersystem Crossing Dynamics for a Heme-Related Model

Du, Likai; Liu, Fang; Li, Yanwei; Yang, Zhongyue; Zhang, Qingzhu; Zhu, Chaoyuan; Gao, Jun

doi:10.1021/acs.jpcc.7b11462

Cited by 9 publications

(16 citation statements)

References 123 publications

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“…Many theoretical studies have investigated atomic‐level spin‐inversion mechanisms in O 2 binding with a simplified model heme, namely, a Fe(II)‐porphyrin complex with a proximal imidazole or a related ligand . These theoretical studies have shown that the electronic ground state of the Fe(II)‐porphyrin complex with a d 6 configuration is a quintet spin state and that the second lowest spin state is a triplet state, although the energy difference between these spin states is very small .…”

Section: Introductionmentioning

confidence: 99%

Spin‐inversion mechanisms in O₂ binding to a model heme complex revisited by density function theory calculations

et al. 2020

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Spin‐inversion mechanisms in O2 binding to a model heme complex, consisting of Fe(II)‐porphyrin and imidazole, were investigated using density‐functional theory calculations. First, we applied the recently proposed mixed‐spin Hamiltonian method to locate spin‐inversion structures between different total spin multiplicities. Nine spin‐inversion structures were successfully optimized for the singlet–triplet, singlet–quintet, triplet–quintet, and quintet–septet spin‐inversion processes. We found that the singlet–triplet spin‐inversion points are located around the potential energy surface region at short Fe–O distances, whereas the singlet–quintet and quintet–septet spin‐inversion points are located at longer Fe–O distances. This suggests that both narrow and broad crossing models play roles in O2 binding to the Fe‐porphyrin complex. To further understand spin‐inversion mechanisms, we performed on‐the‐fly Born‐Oppenheimer molecular dynamics calculations. The reaction coordinates, which are correlated to the spin‐inversion dynamics between different spin multiplicities, are also discussed.

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Section: Introductionmentioning

confidence: 99%

Spin‐inversion mechanisms in O₂ binding to a model heme complex revisited by density function theory calculations

et al. 2020

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“…In addition to the surface area, other factors related to the surface of the iron oxide are important to determine the peroxidaselike activity of the iron oxides. The ability to the binding and the dissociation of the oxygen molecules to the surface of the particles is critical factors with a complexity; for stance, in molecules with an active Fe ion in the core, the dioxygen binding and dissociation dynamics of the resulting iron peroxide species are key points for the catalytic activity of molecule 52 . Besides the surface, the structure and superficial plane are also important in the peroxidase-like of oxides with spinel structure, including the maghemite and the magnetite 53 , among others 3d transition metal oxides with similar structure 54 .…”

Section: Discussionmentioning

confidence: 99%

Free-Radical Formation by the Peroxidase-Like Catalytic Activity of MFe₂O₄ (M = Fe, Ni, and Mn) Nanoparticles

et al. 2019

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Ferrite Magnetic Nanoparticles (MNPs) have peroxidase-like activity and thus catalyze the decomposition of H 2 O 2 producing reactive oxygen species (ROS). Increasingly important applications of these Ferrite MNPs in biology and medicine require that their morphological, physicochemical and magnetic properties need to be strictly controlled. Usually, the tuning of their magnetic properties is achieved by the replacement of the Fe by other 3d metals, such as Mn or Ni. Here, we studied the catalytic activity for ferrite MNPs (MFe 2 O 4 , M = Fe 2+ /Fe 3+ , Ni, Mn) with mean diameter ranging from 10 to 12 nm. Peroxidase-like activity was studied by Electron Paramagnetic Resonance (EPR) using the spin-trap DMPO at different pHs (4.8, 7.4) and temperatures (25°C, 40°C). We identified an enhanced amount of the hydroxyl (•OH) and perhydroxyl (•OOH) radicals for all samples, compared to a blank solution. Quantitative studies show that [•OH] is the dominant radical formed for Fe 3 O 4 , which is strongly reduced with the concomitant oxidation of Fe 2+ or its substitution (Ni or Mn). A comparative analysis of the EPR data against in vitro production of ROS in microglial BV2 cell culture provided additional insight regarding the catalytic activity of ferrite MNPs, which should be considered if biomedical uses are intended. Our results contribute to a better understanding of the role played by different divalent ions in the catalytic activity of Ferrite nanoparticles, which is very important concerning their use in biomedical applications.

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“…The key steps of the workflow are shown in Figure 2. The samples sufficient molecular conformations were obtained from ab initio dynamic trajectories of previous work (Du et al, 2018), which covered a wide range of conformations related to the spin crossover. Different descriptors were then extracted, FIGURE 1 | The molecular model of this work.…”

Section: Methodsmentioning

confidence: 99%

“…In our previous work (Liu et al, 2017;Du et al, 2018), the spin-forbidden dioxygen binding dynamics in a simplified heme model were investigated by the non-adiabatic trajectory surface-hopping dynamics, and this involved the coupled singlet, triplet, and quintuplet states. The results revealed that there existed dominant long-lived, kinetically meta-stable states during the dynamics trajectories, and each meta-stable pattern showed a distinct partial charge population.…”

Section: Introductionmentioning

confidence: 99%

Toward the Prediction of Multi-Spin State Charges of a Heme Model by Random Forest Regression

Zhao

Huang

et al. 2020

Front. Chem.

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The random forest regression (RFR) model was introduced to predict the multiple spin state charges of a heme model, which is important for the molecular dynamic simulation of the spin crossover phenomenon. In this work, a multiple spin state structure data set with 39,368 structures of the simplified heme-oxygen binding model was built from the non-adiabatic dynamic simulation trajectories. The ESP charges of each atom were calculated and used as the real-valued response. The conformational adapted charge model (CAC) of three spin states was constructed by an RFR model using symmetry functions. The results show that our RFR model can effectively predict the on the fly atomic charges with the varying conformations as well as the atomic charge of different spin states in the same conformation, thus achieving the balance of accuracy and efficiency. The average mean absolute error of the predicted charges of each spin state is <0.02 e. The comparison studies on descriptors showed a maximum 0.06 e improvement in prediction of the charge of Fe 2+ by using 11 manually selected structural parameters. We hope that this model can not only provide variable parameters for developing the force field of the multi-spin state but also facilitate automation, thus enabling large-scale simulations of atomistic systems.

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Dioxygen Activation by Iron Complexes: The Catalytic Role of Intersystem Crossing Dynamics for a Heme-Related Model

Cited by 9 publications

References 123 publications

Spin‐inversion mechanisms in O₂ binding to a model heme complex revisited by density function theory calculations

Spin‐inversion mechanisms in O₂ binding to a model heme complex revisited by density function theory calculations

Free-Radical Formation by the Peroxidase-Like Catalytic Activity of MFe₂O₄ (M = Fe, Ni, and Mn) Nanoparticles

Toward the Prediction of Multi-Spin State Charges of a Heme Model by Random Forest Regression

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Dioxygen Activation by Iron Complexes: The Catalytic Role of Intersystem Crossing Dynamics for a Heme-Related Model

Cited by 9 publications

References 123 publications

Spin‐inversion mechanisms in O2 binding to a model heme complex revisited by density function theory calculations

Spin‐inversion mechanisms in O2 binding to a model heme complex revisited by density function theory calculations

Free-Radical Formation by the Peroxidase-Like Catalytic Activity of MFe2O4 (M = Fe, Ni, and Mn) Nanoparticles

Toward the Prediction of Multi-Spin State Charges of a Heme Model by Random Forest Regression

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Spin‐inversion mechanisms in O₂ binding to a model heme complex revisited by density function theory calculations

Spin‐inversion mechanisms in O₂ binding to a model heme complex revisited by density function theory calculations

Free-Radical Formation by the Peroxidase-Like Catalytic Activity of MFe₂O₄ (M = Fe, Ni, and Mn) Nanoparticles