Sujansathiendran

Explore Cellular Neurophysiology at UCL. Dive into the intricate world of Neuronal Calcium Signaling, exploring transport mechanisms, glial cells, synapse dynamics, bioelectricity, action potentials, ion channels, and the transformative realm of optogenetics. Please note that these materials are intended for personal use only and should be used in accordance with academic integrity guidelines.

Explore Cellular Neurophysiology at UCL. Dive into the intricate world of Neuronal Calcium Signaling, exploring transport mechanisms, glial cells, synapse dynamics, bioelectricity, action potentials, ion channels, and the transformative realm of optogenetics.

Explore Molecular Biology for Neuroscientists at UCL. Navigate the intricate landscape of extrachromosomal replications, plasmids, bacteriophage lambda, and the Polymerase Chain Reaction. Delve into the nuanced use of plasmids, genome allelic variations, and the intersection of bioinformatics with data storage, searching, and sequencing. Please note that these materials are intended for personal use only and should be used in accordance with academic integrity guidelines.

Explore Essential Molecular Biology at UCL. Dive into the intricate world of RNA, exploring detection, manipulation technologies, RNA processing, and transcription. Tailored for Year 2 students, these notes provide a humanized academic guide, enriching your understanding of RNA dynamics. Please note that these materials are intended for personal use only and should be used in accordance with academic integrity guidelines.

Explore Essential Molecular Biology at UCL. Navigate the intricacies of Transcriptional Regulation and Translation in this specialized resource tailored for Year 2 students. Uncover the molecular orchestration governing gene expression. These notes offer a humanized academic guide, deepening your comprehension of transcriptional and translational processes. Please note that these materials are intended for personal use only and should be used in accordance with academic integrity guidelines.

Explore Essential Molecular Biology at UCL. Delve into the complex world of cancer, unraveling oncogenic transformation, understanding oncogenes, exploring metastatic growth, and dissecting redox regulation and metabolic reprogramming. Tailored for Year 1 students, these notes provide a humanized academic guide, enriching your understanding of the molecular intricacies within the realm of cancer biology. Please note that these materials are intended for personal use only and should be used in ac...

Explore Essential Molecular Biology at UCL. Unveil the intricacies of DNA dynamics, covering damaged DNA, repair mechanisms, detection, and cutting-edge recombinant technologies. Tailored for Year 1 students, these notes offer a humanized academic guide, enriching your understanding of DNA replication, structure, packaging, and transformative technologies. Please note that these materials are intended for personal use only and should be used in accordance with academic integrity guidelines.

Explore Essential Molecular Biology at UCL. Navigate the intricate realm of protein trafficking and translocation, unraveling the dynamics of protein movement from the ER. These notes, tailored for Year 1 students, provide a humanized academic guide, enhancing your comprehension of essential molecular processes. Please note that these materials are intended for personal use only and should be used in accordance with academic integrity guidelines.

Explore Mammalian Physiology at UCL. From cellular dynamics and skeletal muscle to the intricacies of the endocrine, nervous, cardiovascular, gastrointestinal, and respiratory systems — these notes offer a humanized academic guide tailored for Year 1 students.

Embark on a comprehensive exploration of Chemistry for Biology Students at UCL. Uncover the dynamics of chemical and enzyme kinetics, ions and chemical forces, delve into the principles of spectroscopy, and explore the intricacies of structure, bonding, self-assembly, and thermodynamics in biological molecules.