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5. Machine Learning and Artificial Intelligence for Advanced Materials Processing: A review on opportunities and challenges

Author

Srivastava Shashank, Kumar Indradeep, Kumar Manish, Shakier Hussein Ghafel, B Swathi, and Chahuan Neeraj

Subjects
machine learning, artificial intelligence, advanced materials processing, predictive modelling, decision-making, material design, Environmental sciences, GE1-350
Abstract

This research paper explores the opportunities and challenges associated with the use of machine learning and artificial intelligence in advanced materials processing. With the exponential growth of data, advanced analytical techniques and powerful computational tools, machine learning and artificial intelligence can be leveraged to develop novel materials with tailored properties, enhance process optimization, and improve manufacturing efficiencies. However, the integration of these technologies into materials processing systems is not without challenges, including data acquisition and pre-processing, algorithm selection and optimization, and the interpretation of results. This paper provides an overview of the state-of-the-art in machine learning and artificial intelligence for advanced materials processing, highlighting case studies and examples of successful applications, and identifying potential future research directions. The goal of this research is to provide insights and recommendations to accelerate the adoption of these technologies and their impact on the development of advanced materials.

Published
2024
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6. Exploring the Future of Advanced Materials Processing: Innovations and Challenges Ahead: A Review

Author

Sharma Avdhesh Kumar, Ramacharyulu D Atchuta, Lakhanpal Sorabh, Shakier Hussein Ghafel, Reddy Uma, and Kumari Vandna

Subjects
materials processing, advanced materials, artificial intelligence, composite materials, renewable resources, Environmental sciences, GE1-350
Abstract

This research paper investigates the future of advanced materials processing, with a focus on the innovations and challenges that lie ahead. The study begins by exploring the current state of advanced materials processing and the latest trends in the field, including the use of advanced manufacturing technologies, such as additive manufacturing, to create complex geometries and novel materials. The paper then examines the challenges facing the field, including the need to develop new processing techniques that can handle a wider range of materials and produce materials with specific properties. The study also analyses the potential impact of emerging technologies, such as artificial intelligence and machine learning, on the future of materials processing. Finally, the paper concludes with a discussion of the key innovations and trends that are likely to shape the future of materials processing, including the use of sustainable materials, the development of new nanomaterials, and the integration of advanced sensors and data analytics into the manufacturing process. Overall, this research paper provides a comprehensive analysis of the future of advanced materials processing and highlights the critical role that innovation will play in shaping the field in the coming years.

Published
2024
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7. Advancing therapeutic efficacy: nanovesicular delivery systems for medicinal plant-based therapeutics.

Author

Saadh, Mohamed J., Mustafa, Mohammed Ahmed, Kumar, Sanjay, Gupta, Pooja, Pramanik, Atreyi, Rizaev, Jasur Alimdjanovich, Shareef, Hasanain Khaleel, Alubiady, Mahmood Hasen Shuhata, Al-Abdeen, Salah Hassan Zain, Shakier, Hussein Ghafel, Alaraj, Mohd, and Alzubaidi, Laith H.

Subjects
PLANT extracts, TECHNOLOGICAL innovations, BACTERIAL diseases, MEDICINAL plants, INDIVIDUALIZED medicine
Abstract

The utilization of medicinal plant extracts in therapeutics has been hindered by various challenges, including poor bioavailability and stability issues. Nanovesicular delivery systems have emerged as promising tools to overcome these limitations by enhancing the solubility, bioavailability, and targeted delivery of bioactive compounds from medicinal plants. This review explores the applications of nanovesicular delivery systems in antibacterial and anticancer therapeutics using medicinal plant extracts. We provide an overview of the bioactive compounds present in medicinal plants and their therapeutic properties, emphasizing the challenges associated with their utilization. Various types of nanovesicular delivery systems, including liposomes, niosomes, ethosomes, and solid lipid nanoparticles, among others, are discussed in detail, along with their potential applications in combating bacterial infections and cancer. The review highlights specific examples of antibacterial and anticancer activities demonstrated by these delivery systems against a range of pathogens and cancer types. Furthermore, we address the challenges and limitations associated with the scale-up, stability, toxicity, and regulatory considerations of nanovesicular delivery systems. Finally, future perspectives are outlined, focusing on emerging technologies, integration with personalized medicine, and potential collaborations to drive forward research in this field. Overall, this review underscores the potential of nanovesicular delivery systems for enhancing the therapeutic efficacy of medicinal plant extracts in antibacterial and anticancer applications, while identifying avenues for further research and development. The role of nanovesicular delivery systems in enhancing the therapeutic potential of medicinal plant extracts against bacterial infections and cancer. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Targeting the pancreatic tumor microenvironment by plant-derived products and their nanoformulations.

Author

Saadh, Mohamed J., Mustafa, Mohammed Ahmed, Malathi, H., Ahluwalia, Gunveen, Kaur, Sumeet, Al-Dulaimi, Mohammad Abd Alrazaq Hameed, Alubiady, Mahmood Hasen Shuhata, Zain Al-Abdeen, Salah Hassan, Shakier, Hussein Ghafel, Ali, Mohammed Shnain, Ahmad, Irfan, and Abosaoda, Munther Kadhim

Abstract

Pancreatic cancer remains a significant health issue with limited treatment options. The tumor stroma, a complex environment made up of different cells and proteins, plays a crucial role in tumor growth and chemoresistance. Targeting tumor stroma, consisting of diverse non-tumor cells such as fibroblasts, extracellular matrix (ECM), immune cells, and also pre-vascular cells is encouraging for remodeling solid cancers, such as pancreatic cancer. Remodeling the stroma of pancreas tumors can be suggested as a strategy for reducing resistance to chemo/immunotherapy. Several studies have shown that phytochemicals from plants can affect the tumor environment and have anti-cancer properties. By targeting key pathways involved in stromal activation, phytochemicals may disrupt communication between the tumor and stroma and make tumor cells more sensitive to different treatments. Additionally, phytochemicals have immunomodulatory and anti-angiogenic properties, all of which contribute to their potential in treating pancreatic cancer. This review will provide a detailed look at how phytochemicals impact the tumor stroma and their effects on pancreatic tumor growth, spread, and response to treatment. It will also explore the potential of combining phytochemicals with other treatment options like chemotherapy, immunotherapy, and radiation. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Reinventing Production: A Case Study on implementing the strategic Innovations in Sustainable Remanufacturing

Author

Sharma Aman, Bhong Mahesh, Patil Pravin P., Saraswat Manish, Vinod Kumar S., Manjunatha, and Shakier Hussein Ghafel

Subjects
Environmental sciences, GE1-350
Abstract

The understanding of sustainable remanufacturing as an innovative method has come about as a solution to the ecological difficulties posed by industrial manufacturing. The present study investigates the concept of industrial reinvention via a review of novel practices in the field of remanufacturing. Remanufacturing is an organizational strategy that seeks to increase the operational lifecycle of items, hence reducing the production of waste and maximizing resource use. The remanufacturing process includes a thorough set of phases, involving removal, repair, and enhancement, with the goal of rebuilding already utilized products to their former functionality as well as performance standards. This study examines the current state of procedures, methods, and strategies that contribute to the evolution of the remanufacturing operation in an environmentally friendly form. The abstract underlines the urgent requirement for sustainable solutions in industrial production as a response to problems with the environment. The idea of remanufacturing has been suggested as an effective way to solve these issues. This recent discussion presents an easy-to-understand representation of the remanufacturing process, emphasizing its essential relevance in increasing the lifespan of goods and decreasing the production of waste. The subsequent section of the abstract describes the primary objective of the research, which is the investigation of novel methods in the field of green remanufacturing. The paper aims to investigate multiple methods, tools, and strategies that are currently impacting the emergence of remanufacturing companies.

Published
2023
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10. The SAFT-VR Morse equation of state for liquid alkali metals.

Author

Kazem, Tareq Jwad, Alsalamy, Ali, Al Mashhadani, Zuhair I., Abbass, Reathab, Shakier, Hussein Ghafel, Dawood, Ashour H., Ramadan, Montather F., Gatea, M. Abdulfadhil, and Shariyati, Reza

Subjects
*LIQUID metals, *LIQUID density, *EQUATIONS of state, *SPEED of sound, *VISCOSITY, *HIGH temperatures
Abstract

In this work, the thermo-physical properties of liquid alkali metals using the SAFT-VR Morse equation of state (EoS) have been estimated. The saturated liquid density, compressed liquid density, viscosity, and speed of sound of pure liquid alkali metals have been calculated using the SAFT-VR Morse EoS. The model capability has been evaluated in mixed liquid alkali metals systems. In this regard, the densities of K-Cs, Na-K, and Na-K-Cs systems have been predicted. The modified Enskog equation has been combined with the SAFT-VR Morse model to correlate the viscosity of liquid metals. The average error (ARD%) between model estimation and experimental data for saturated liquid density, compressed liquid density, viscosity, and speed of sound have been obtained 1.61, 4.4, 3.15, and 35.2, respectively. As well, the average errors of calculated binary and ternary liquid density of K-Cs, Na-K, and Na-K-Cs systems have been obtained, 0.8, 0.65, and 4.89 respectively. The results indicated that the SAFT-VR Mors EoS can estimate the thermo-physical properties of liquid alkali metals up to high pressure and temperature, accurately. [Display omitted] [ABSTRACT FROM AUTHOR]

Published
2023
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