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Athletic Performance and Psychological Resilience Akram, Muhammad; Maqbool, Tahmina; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł
African Multidisciplinary Journal of Sciences and Artificial Intelligence Vol 2 No 2 (2025): African Multidisciplinary Journal of Sciences and Artificial Intelligence
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/amjsai.v2i2.5203

This study investigates how higher psychological resilience and physical performance are enabled by mental development, mental hardness, lexical memory, and conditional motivation. It investigates how the psychological factors enable long-term motivation, disease avoidance, and mental improvement—factors that all come together to make the athlete more resilient both psychologically and physically.

Athletic Performance and Psychological Resilience Akram, Muhammad; Maqbool, Tahmina; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł
African Multidisciplinary Journal of Sciences and Artificial Intelligence Vol 2 No 2 (2025): African Multidisciplinary Journal of Sciences and Artificial Intelligence
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/amjsai.v2i2.5203

This study investigates how higher psychological resilience and physical performance are enabled by mental development, mental hardness, lexical memory, and conditional motivation. It investigates how the psychological factors enable long-term motivation, disease avoidance, and mental improvement—factors that all come together to make the athlete more resilient both psychologically and physically.

Emerging Applications and Challenges of Nanotechnology in Medicine and Nutrition Akram, Muhammad; Mahmood, Abid; Hasan, Mohammed Khudhair; Umaru, Isaac John; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.5484

Emerging applications of nanotechnology in medicine and nutrition present both significant opportunities and challenges that warrant thorough investigation. This study aims to explore the intersection of nanotechnology and genomic nutrition, focusing on how these advancements can enhance preventive care and health outcomes. Employing a qualitative descriptive methodology, we conducted a comparative analysis of existing literature and case studies to assess the implications of these technologies on dietary customization and patient-provider relationships. Our findings reveal that nanotechnology facilitates the development of targeted nutritional interventions that align with individual genetic profiles, thereby improving adherence to dietary guidelines and mitigating disease risk. Furthermore, we identify that the integration of continuous health monitoring technologies fosters a collaborative partnership between patients and healthcare providers, enhancing communication and decision-making processes in treatment and preventive initiatives. The implications of this research underscore the necessity for healthcare systems to adopt technological advancements to address the complexities of modern medicine effectively. By embracing these innovations, the potential for precision medicine is significantly amplified, paving the way for improved health outcomes and personalized nutrition strategies in the future.

Evolution of DNA Technology in Treating Animal Diseases Akram, Muhammad; Umaru, Isaac John; Mahmood, Abid; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben; Al-Musawi, Jehan Mohammad
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.5582

A single gene mutation can result in aberrant cell activity and the production of a faulty protein. The cell will certainly operate very poorly or not at all as a result of this mutation. Given that the genetic material may be a therapeutic agent; this might be seen as qualitatively distinct from other conventional drugs. Gene therapy may be able to rectify or perhaps cure the pathophysiology of a disease by changing the genetic composition of cells. In veterinary medicine, genetic engineering has been used to xenografts, and detects, prevent, and treat illnesses. Among the challenges that gene therapy faces include transfection, intracellular vector stability, cellular and nuclear entrance, and ethical concerns. Deficits in gene transfer vectors and a lack of knowledge about the biological interactions between these vectors and the host are two examples of fundamental challenges.

Microbial Genetics: Foundations, Applications, and Future Directions in Science and Biotechnology Akram, Muhammad; Umaru, Isaac John; Mahmood, Abid; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben; Al-Musawi, Jehan Mohammad
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.5652

This field is essential to comprehending not just basic biological processes but also how they are used in biotechnology, agriculture, and medicine. Microbial genetics is the study of genetic material, which includes horizontal gene transfer, DNA replication, gene expression, and mutation. Many microorganisms, in contrast to larger species, have genomes that are small and relatively basic, enabling researchers to accurately examine the regulation and function of genes. Mechanisms like transformation, transduction, and conjugation, which speed up the acquisition and spread of genetic characteristics like antibiotic resistance, are primarily responsible for the genetic plasticity of microorganisms, especially bacteria. Given that existing treatment approaches are being challenged by the growth consequences. Additionally, using cutting-edge molecular methods like whole-genome sequencing, recombinant DNA technology, and CRISPR-Cas systems, microbial genetics aids in the creation of novel antibiotics, vaccines, and diagnostic instruments. The intricacies of microbial communities, or microbiomes, and their interactions with hosts and the environment have also been clarified by research in microbial genetics. Our knowledge of microbial ecology, pathogenicity, and symbiosis has increased as a result. The discipline is still developing in industrial settings, but the combination of systems genetics and computational biology holds promise for deciphering intricate regulatory networks and enabling predictive modeling of microbial behavior. As microbial genetics advances, ethical issues—especially those pertaining to gene editing and the discharge of genetically engineered organisms—become more significant. To sum up, microbial genetics is a fundamental component of contemporary biology and biotechnology, offering deep understanding of microbial life and laying the groundwork for advancement in a wide range of scientific and industrial domains. Addressing global health, sustainability, and environmental management concerns requires ongoing study in this area.

Cell Dynamics: Mechanisms, Technologies, and Applications in Health and Disease Akram, Muhammad; Umaru, Isaac John; Mahmood, Abid; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben; Al-Musawi, Jehan Mohammad
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.5653

The intricate and well-coordinated activities of cells in response to both internal and external stimuli are referred to as cell dynamics. These behaviors help living things grow, differentiate, maintain, and adapt. Using a variety of interdisciplinary techniques from molecular biology, biophysics, computational modeling, and live-cell imaging, this field examines the dynamic processes that control cell morphology, intracellular transport, cytoskeletal reorganization, signal transduction, and cell motility. The capacity of cells to alter their structure and function in real time, allowing for quick reactions to changes in the environment, damage, or developmental signals, is a key component of cell dynamics. The complex coordination of cytoskeletal filaments, vesicle trafficking channels, and signaling networks that underpin activities including mitosis, migration, immunological surveillance, and synaptic plasticity has been made visible by developments in high-resolution imaging and single-cell analysis. Recent research has demonstrated that cellular activities incorporate stochastic fluctuations, spatial compartmentalization, and emergent features resulting from the combined actions of molecular complexes, in addition to deterministic biochemical routes. It has been demonstrated that the mechanical characteristics of the cellular microenvironment, such as the extracellular matrix composition and substrate stiffness, are essential for regulating dynamic cellular responses, especially during wound healing, tissue formation, and cancer progression. Additionally, the enormous datasets produced by live-cell imaging and omics technologies are being decoded more and more using computational models and artificial intelligence tools, which offer fresh perspectives on the temporal and spatial control of cellular activities. In addition to expanding our understanding of basic cell biology, an understanding of cellular dynamics may help develop therapeutic approaches that target dysregulated cellular activities in conditions including cancer, dementia, and immunological disorders. In order to anticipate cellular outcomes and manipulate cell destiny for applications in synthetic biology and regenerative medicine, it will be crucial to combine quantitative modeling with experimental data as we continue to clarify the fundamentals of cellular structure and adaptability.

Cloning in Plants and Animals: Divergent Pathways and Ethical Boundaries in Biotechnology Akram, Muhammad; Umaru, Isaac John; Aslam, Nosheen; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben; Al-Musawi, Jehan Mohammed; Mahmood, Abid
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.6140

The creation of genetically identical creatures by cloning is essential to contemporary biotechnology, agriculture, and medical research. Although the basic idea of cloning is the same in all kingdoms, there are substantial differences between plants and animals in terms of its use, effectiveness, and moral consequences. Cloning is a common, natural occurrence in plants and is frequently accomplished using asexual reproduction procedures such as tissue culture, grafting, and vegetative propagation. Because plant cells are highly totipotent, practically any somatic cell may grow again into a whole organism given the right circumstances. The production of genetically engineered plants with enhanced features, the preservation of uncommon species, and the large-scale multiplication of genetically uniform crops have all been made easier by this regenerative potential. Animal cloning, on the other hand, poses far more biological and technological difficulties. Due to developmental errors, aberrant gene expression, and insufficient reprogramming of the donor nucleus, this procedure usually has poor success rates and necessitates intricate management. It brings up important issues about biodiversity, animal care, and the ethical ramifications of cloning sentient creatures. Furthermore, animal cloning is more closely regulated and scrutinized by the public than plant cloning, which is generally recognized in agricultural operations and conservation initiatives. This is particularly true when it comes to food production and possible human cloning. The difference in the effectiveness and uses of cloning is mostly explained by the difference in totipotency between plant and animal cells. The accuracy of modification is becoming closer thanks to recent technological advancements like CRISPR-Cas9, yet the ethical and practical possibilities of cloning in these two domains are still not comparable. The intricate relationship between biological viability, technical development, and societal acceptability of interspecies cloning is shown by this comparative study. Guidance on the proper application and control of cloning technologies in biomedicine and agriculture depends on an understanding of these distinctions.

Emerging Applications and Challenges of Nanotechnology in Medicine and Nutrition Akram, Muhammad; Mahmood, Abid; Hasan, Mohammed Khudhair; Umaru, Isaac John; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.5484

Emerging applications of nanotechnology in medicine and nutrition present both significant opportunities and challenges that warrant thorough investigation. This study aims to explore the intersection of nanotechnology and genomic nutrition, focusing on how these advancements can enhance preventive care and health outcomes. Employing a qualitative descriptive methodology, we conducted a comparative analysis of existing literature and case studies to assess the implications of these technologies on dietary customization and patient-provider relationships. Our findings reveal that nanotechnology facilitates the development of targeted nutritional interventions that align with individual genetic profiles, thereby improving adherence to dietary guidelines and mitigating disease risk. Furthermore, we identify that the integration of continuous health monitoring technologies fosters a collaborative partnership between patients and healthcare providers, enhancing communication and decision-making processes in treatment and preventive initiatives. The implications of this research underscore the necessity for healthcare systems to adopt technological advancements to address the complexities of modern medicine effectively. By embracing these innovations, the potential for precision medicine is significantly amplified, paving the way for improved health outcomes and personalized nutrition strategies in the future.

Evolution of DNA Technology in Treating Animal Diseases Akram, Muhammad; Umaru, Isaac John; Mahmood, Abid; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben; Al-Musawi, Jehan Mohammad
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.5582

A single gene mutation can result in aberrant cell activity and the production of a faulty protein. The cell will certainly operate very poorly or not at all as a result of this mutation. Given that the genetic material may be a therapeutic agent; this might be seen as qualitatively distinct from other conventional drugs. Gene therapy may be able to rectify or perhaps cure the pathophysiology of a disease by changing the genetic composition of cells. In veterinary medicine, genetic engineering has been used to xenografts, and detects, prevent, and treat illnesses. Among the challenges that gene therapy faces include transfection, intracellular vector stability, cellular and nuclear entrance, and ethical concerns. Deficits in gene transfer vectors and a lack of knowledge about the biological interactions between these vectors and the host are two examples of fundamental challenges.

Microbial Genetics: Foundations, Applications, and Future Directions in Science and Biotechnology Akram, Muhammad; Umaru, Isaac John; Mahmood, Abid; Hasan, Mohammed Khudhair; Abdulghafoor, Hind A.; Khan, Fahad Said; Ozdemir, Fethi Ahmet; Sołowski, Gaweł; Ali, Jaouher Ben; Al-Musawi, Jehan Mohammad
African Journal of Biochemistry and Molecular Biology Research Vol 2 No 2 (2025): African Journal of Biochemistry and Molecular Biology Research
Publisher : Darul Yasin Al Sys

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.58578/ajbmbr.v2i2.5652

This field is essential to comprehending not just basic biological processes but also how they are used in biotechnology, agriculture, and medicine. Microbial genetics is the study of genetic material, which includes horizontal gene transfer, DNA replication, gene expression, and mutation. Many microorganisms, in contrast to larger species, have genomes that are small and relatively basic, enabling researchers to accurately examine the regulation and function of genes. Mechanisms like transformation, transduction, and conjugation, which speed up the acquisition and spread of genetic characteristics like antibiotic resistance, are primarily responsible for the genetic plasticity of microorganisms, especially bacteria. Given that existing treatment approaches are being challenged by the growth consequences. Additionally, using cutting-edge molecular methods like whole-genome sequencing, recombinant DNA technology, and CRISPR-Cas systems, microbial genetics aids in the creation of novel antibiotics, vaccines, and diagnostic instruments. The intricacies of microbial communities, or microbiomes, and their interactions with hosts and the environment have also been clarified by research in microbial genetics. Our knowledge of microbial ecology, pathogenicity, and symbiosis has increased as a result. The discipline is still developing in industrial settings, but the combination of systems genetics and computational biology holds promise for deciphering intricate regulatory networks and enabling predictive modeling of microbial behavior. As microbial genetics advances, ethical issues—especially those pertaining to gene editing and the discharge of genetically engineered organisms—become more significant. To sum up, microbial genetics is a fundamental component of contemporary biology and biotechnology, offering deep understanding of microbial life and laying the groundwork for advancement in a wide range of scientific and industrial domains. Addressing global health, sustainability, and environmental management concerns requires ongoing study in this area.

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