Kaihao Gu scite author profile

Kaihao Gu

4Publications

49Citation Statements Received

115Citation Statements Given

How they've been cited

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138

114

Affiliations

University of Chinese Academy of Sciences, Fudan University, University of Shanghai for Science and Technology

Publications

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Computer simulation study on the effect of electrode–tissue contact force on thermal lesion size in cardiac radiofrequency ablation

Yan

Wang

et al. 2020

International Journal of Hyperthermia

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Purpose: In cardiac radiofrequency (RF) ablation, RF energy is often used to create a series of transmural lesions for blocking accessory conduction pathways. Electrode-tissue contact force (CF) is one of the key determinants of lesion formation during RF ablation. Low electrode-tissue CF is associated with ineffective RF lesion formation, whereas excessive CF may increase the risk of steam pop and perforation. By using finite element analysis, we studied lesion size and features at different values of electrode-tissue CF in cardiac RF ablation. Materials and methods: A computer-model-coupled electrode-tissue CF field, RF electric field, and thermal field were developed to study temperature distribution and lesion dimensions in cardiac tissue subjected to CF of 2, 5, 10, 20, 30, and 40 g with identical RF voltage and duration. Results: Increasing CF was associated with an increase in lesion depth, width, and cross-section area. The lesion cross-section area exhibited a linear increase, and the lesion width was significantly greater than lesion depth under the identical ablation condition. The relationship between CF value and lesion size is a power function: Lesion Size ¼ a Â CF b (Lesion Depth ¼ 3.17 Â CF 0.14 and Lesion Width ¼ 5.17 Â CF 0.14). Conclusions: This study confirmed that CF is a major determinant of RF lesion size and that electrode-tissue CF affects the amount of power dissipated in tissue. At a constant RF voltage and application time, RF lesion size increases as CF increases.

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Regulation of Recombinase Polymerase Amplification by Vibrational Strong Coupling of Water

et al. 2023

ACS Photonics

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Vibrational strong coupling (VSC) between molecular transitions and photonic structures can be used to tune the reactivity of molecules, and hybrid polariton states have been employed to modify the energy landscape of molecular systems in an optical cavity. To investigate how to modulate life reactions with VSC, herein we selected an in vitro model bioreaction, DNA replication, i.e., recombinase polymerase amplification (RPA), to couple with the typical Fabry–Pérot (FP) cavity mode. Known as an isothermal enzymatic reaction, RPA well satisfies the VSC study within FP cavities. Through tuning the resonance coupling strength between water molecules and FP cavity modes, we can regulate the efficiency of RPA as the cavity modes change from 3100 to 3550 cm–1. The results showed that O–H-based VSC can significantly inhibit the efficiency of RPA by ∼58%. Due to the key role of water in life, O–H stretching vibrational coupling with photonic structures could be a novel tool to regulate life in turn.

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Effect of anisotropy in myocardial electrical conductivity on lesion characteristics during radiofrequency cardiac ablation: a numerical study

Yan

Wang

2022

International Journal of Hyperthermia

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Effect of Anisotropic Electrical Conductivity Induced by Fiber Orientation on Ablation Characteristics of Pulsed Field Ablation in Atrial Fibrillation Treatment: A Computational Study

Zang

et al. 2022

JCDD

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Pulsed field ablation (PFA) is a promising new ablation modality for the treatment of atrial fibrillation (AF); however, the effect of fiber orientation on the ablation characteristics of PFA in AF treatment is still unclear, which is likely an essential factor in influencing the ablation characteristics. This study constructed an anatomy-based left atrium (LA) model incorporating fiber orientation and selected various electrical conductivity and ablation targets to investigate the effect of anisotropic electrical conductivity (AC), compared with isotropic electrical conductivity (IC), on the ablation characteristics of PFA in AF treatment. The results show that the percentage differences in the size of the surface ablation area between AC and IC are greater than 73.71%; the maximum difference in the size of the ablation isosurface between AC and IC at different locations in the atrial wall is 3.65 mm (X-axis), 3.65 mm (Z-axis), and 4.03 mm (X-axis), respectively; and the percentage differences in the size of the ablation volume are greater than 6.9%. Under the condition of the pulse, the amplitude is 1000 V, the total PFA duration is 1 s, and the pulse train interval is 198.4 ms; the differences in the temperature increase between AC and IC in LA are less than 2.46 °C. Hence, this study suggests that in further exploration of the computational study of PFA in AF treatment using the same or similar conditions as those used here (myocardial electrical conductivity, pulse parameters, and electric field intensity damage threshold), to obtain more accurate computational results, it is necessary to adopt AC rather than IC to investigate the size of the surface ablation area, the size of the ablation isosurface, or the size of the ablation volume generated by PFA in LA. Moreover, if only investigating the temperature increase generated by PFA in LA, adopting IC instead of AC for simplifying the model construction process is reasonable.

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Kaihao Gu

Computer simulation study on the effect of electrode–tissue contact force on thermal lesion size in cardiac radiofrequency ablation

Regulation of Recombinase Polymerase Amplification by Vibrational Strong Coupling of Water

Effect of anisotropy in myocardial electrical conductivity on lesion characteristics during radiofrequency cardiac ablation: a numerical study

Effect of Anisotropic Electrical Conductivity Induced by Fiber Orientation on Ablation Characteristics of Pulsed Field Ablation in Atrial Fibrillation Treatment: A Computational Study

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