Biological Sciences

This course explores the fundamental cellular and developmental processes that drive the formation and organization of animal organisms. It combines cell biology and developmental biology, providing both theoretical foundations and practical laboratory experience. The cell biology section covers mitosis, the cell cycle, apoptosis, cell-cell and cell-matrix interactions, and the cytoskeleton, as well as main cell biology techniques. The developmental biology section explores gametogenesis, fertilization, early embryonic stages, and examples of organogenesis.

This course explores neuronal signaling in vertebrates and invertebrates. Students gain an in-depth understanding of chemical synaptic transmission. Students look at the processes involved in synaptic plasticity and its role in learning, memory and the regulation of behaviors. Students also explore sensory transduction and how the nervous system acquires and integrates information from the environment. There is a particular focus on vision, hearing, and pain. Throughout the course, students learn about the experimental approaches that have contributed to our understanding. Students develop analytical, presentation, and teamwork skills through formative group presentations of published research.

The course covers major aspects of the physiology of the human body using an integrated approach. The course covers fundamental principles of how the body works. Topics include: the physiological systems and homeostasis; neural and hormonal communication; nervous system physiology; digestive system; cardiac physiology, blood vessels and blood pressure; respiratory system; urinary system; skeletal and muscular system; sensory mechanisms; biological rhythms; central-peripheral communication in energy homeostasis. 

This course examines the fusion of physics of biology that forms the basis of modern medical imaging and radiation therapy technology and traces its roots from the foundational theories to its implementation in medical procedures. Students learn how such technology is applied to disease management, as well as the modern innovations that pave the way towards the future of healthcare. Topics include how medical technology is one of the most important applications of science and technology; how it provides the means to protect and preserve lives in today’s world of ageing population, proliferation of chronic diseases, global pandemics and rising pollution. The course requires students to take prerequisites.

This course analyzes the different steps of nervous system development during prenatal, postnatal, and adult life, and the pathological consequences of its alterations. Examples of key molecular and cellular processes are studied in several models (invertebrate, vertebrate, in vitro and organoids).

This course explores the concept of physical activity and the importance of encouraging people to move more and sit less as part of health promotion efforts. Students examine measuring movement behaviors to equip students with the ability to judge data based on how it was obtained. Students identify and analyze various factors that impact how much or little people move. This includes looking into the psychology of physical activity, environmental assessments, and policy enquiries. Insights allow students to design an intervention that can improve movement behaviors. Students can gain tangible knowledge and skills for assessing, understanding, and changing movement behaviors across diverse populations.

This course covers the underlying principles and wide-ranging industrial, environmental, pharmaceutical, and biomedical applications of microbiology. The objectives are (a) to gain an understanding of the role of microorganisms for biotechnology applications in the fields of medicine, agriculture, organic chemistry, synthetic biology, public health, biomass conversion, bioremediation, and biomining; and (b) to review advances in genetics and molecular biology of industrial microorganisms, enzyme engineering, environmental microbiology, food microbiology, and molecular biotechnology. A particular focus will be on the meaning and impact of microbiology on human health and the development of new therapeutic approaches. The course requires students to take prerequisites.

This course focuses on key events that take place in different stages of vertebrate nervous system development including neural induction, neurogenesis, glial biology, neuronal growth and polarity, axonal guidance, synapse formation, and regeneration. Pathological states such as muscular dystrophy, spinal cord injury, Parkinson’s disease, and other neurodegenerative diseases are examined, both in terms of understanding the deficits as well as examining potential solutions to improve the outcomes of these neuronal diseases. Latest findings are discussed, allowing students to learn the current state of research in developmental neurobiology. The course requires students to take prerequisites.

This course provides the skills needed to critically evaluate brain-related information from diverse sources and engage in evidence-based discussions. This knowledge and ability to analyze complex neuroscientific concepts can be highly valuable for you as a future leader, enabling you to make informed decisions, understand human behavior, and effectively communicate with others in areas related to neuroscience and its implications.