Beyond conventional models: integer and fractional order analysis of nonlinear Michaelis-Menten kinetics in immobilised enzyme reactors

IF 1.5 4区 工程技术 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
R. Rajaraman
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引用次数: 0

Abstract

Purpose

This study explores the immobilisation of enzymes within porous catalysts of various geometries, including spheres, cylinders and flat pellets. The objective is to understand the irreversible Michaelis-Menten kinetic process within immobilised enzymes through advanced mathematical modelling.

Design/methodology/approach

Mathematical models were developed based on reaction-diffusion equations incorporating nonlinear variables associated with Michaelis-Menten kinetics. This research introduces fractional derivatives to investigate enzyme reaction kinetics, addressing a significant gap in the existing literature. A novel approximation method, based on the independent polynomials of the complete bipartite graph, is employed to explore solutions for substrate concentration and effectiveness factor across a spectrum of parameter values. The analytical solutions generated through the bipartite polynomial approximation method (BPAM) are rigorously tested against established methods, including the Bernoulli wavelet method (BWM), Taylor series method (TSM), Adomian decomposition method (ADM) and fourth-order Runge-Kutta method (RKM).

Findings

The study identifies two main findings. Firstly, the behaviour of dimensionless substrate concentration with distance is analysed for planar, cylindrical and spherical catalysts using both integer and fractional order Michaelis-Menten modelling. Secondly, the research investigates the variability of the dimensionless effectiveness factor with the Thiele modulus.

Research limitations/implications

The study primarily focuses on mathematical modelling and theoretical analysis, with limited experimental validation. Future research should involve more extensive experimental verification to corroborate the findings. Additionally, the study assumes ideal conditions and uniform catalyst properties, which may not fully reflect real-world complexities. Incorporating factors such as mass transfer limitations, non-uniform catalyst structures and enzyme deactivation kinetics could enhance the model’s accuracy and broaden its applicability. Furthermore, extending the analysis to include multi-enzyme systems and complex reaction networks would provide a more comprehensive understanding of biocatalytic processes.

Practical implications

The validated bipartite polynomial approximation method presents a practical tool for optimizing enzyme reactor design and operation in industrial settings. By accurately predicting substrate concentration and effectiveness factor, this approach enables efficient utilization of immobilised enzymes within porous catalysts. Implementation of these findings can lead to enhanced process efficiency, reduced operating costs and improved product yields in various biocatalytic applications such as pharmaceuticals, food processing and biofuel production. Additionally, this research fosters innovation in enzyme immobilisation techniques, offering practical insights for engineers and researchers striving to develop sustainable and economically viable bioprocesses.

Social implications

The advancement of enzyme immobilisation techniques holds promise for addressing societal challenges such as sustainable production, environmental protection and healthcare. By enabling more efficient biocatalytic processes, this research contributes to reducing industrial waste, minimizing energy consumption and enhancing access to pharmaceuticals and bio-based products. Moreover, the development of eco-friendly manufacturing practices through biocatalysis aligns with global efforts towards sustainability and mitigating climate change. The widespread adoption of these technologies can foster a more environmentally conscious society while stimulating economic growth and innovation in biotechnology and related industries.

Originality/value

This study offers a pioneering approximation method using the independent polynomials of the complete bipartite graph to investigate enzyme reaction kinetics. The comprehensive validation of this method through comparison with established solution techniques ensures its reliability and accuracy. The findings hold promise for advancing the field of biocatalysts and provide valuable insights for designing efficient enzyme reactors.

超越传统模型:固定酶反应器中非线性 Michaelis-Menten 动力学的整阶和分数阶分析
目的本研究探讨了在各种几何形状(包括球体、圆柱体和扁平颗粒)的多孔催化剂中固定酶的问题。目的是通过先进的数学建模,了解固定化酶内的不可逆 Michaelis-Menten 动力学过程。设计/方法/途径根据反应-扩散方程,结合与 Michaelis-Menten 动力学相关的非线性变量,建立数学模型。这项研究引入了分数导数来研究酶反应动力学,解决了现有文献中的一个重要空白。研究采用了一种基于完整二叉图独立多项式的新型近似方法,来探索底物浓度和有效因子在各种参数值范围内的解。通过双方位多项式近似法 (BPAM) 生成的分析解决方案与伯努利小波法 (BWM)、泰勒级数法 (TSM)、阿多米分解法 (ADM) 和四阶 Runge-Kutta 法 (RKM) 等成熟方法进行了严格测试。首先,使用整数阶和分数阶 Michaelis-Menten 模型分析了平面、圆柱和球形催化剂的无量纲底物浓度随距离变化的行为。其次,研究还调查了无量纲有效因子随 Thiele 模量的变化情况。未来的研究应涉及更广泛的实验验证,以证实研究结果。此外,该研究假设了理想的条件和统一的催化剂特性,这可能无法完全反映现实世界的复杂性。将传质限制、非均匀催化剂结构和酶失活动力学等因素考虑在内,可以提高模型的准确性并扩大其适用范围。此外,将分析扩展到多酶系统和复杂的反应网络,将使人们对生物催化过程有更全面的了解。通过准确预测底物浓度和有效因子,该方法可有效利用多孔催化剂中的固定酶。在制药、食品加工和生物燃料生产等各种生物催化应用中,实施这些研究成果可提高工艺效率、降低运营成本和提高产品产量。此外,这项研究还促进了酶固定化技术的创新,为努力开发可持续的、经济上可行的生物工艺的工程师和研究人员提供了实用的见解。通过提高生物催化过程的效率,这项研究有助于减少工业废物、最大限度地降低能源消耗以及提高药品和生物基产品的可及性。此外,通过生物催化技术开发生态友好型生产实践符合全球为实现可持续发展和减缓气候变化所做的努力。这些技术的广泛采用可以促进社会提高环保意识,同时刺激生物技术和相关产业的经济增长和创新。通过与已有的求解技术进行比较,对该方法进行了全面验证,确保了其可靠性和准确性。研究结果有望推动生物催化剂领域的发展,并为设计高效的酶反应器提供有价值的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Engineering Computations
Engineering Computations 工程技术-工程:综合
CiteScore
3.40
自引率
6.20%
发文量
61
审稿时长
5 months
期刊介绍: The journal presents its readers with broad coverage across all branches of engineering and science of the latest development and application of new solution algorithms, innovative numerical methods and/or solution techniques directed at the utilization of computational methods in engineering analysis, engineering design and practice. For more information visit: http://www.emeraldgrouppublishing.com/ec.htm
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