CELLULAR BIOCHEMISTRY, HUMAN SYSTEMATICS

Degree course: 
Corso di Long single cycle degree (6 years) in SCHOOL OF DENTISTRY
Academic year when starting the degree: 
2024/2025
Year: 
1
Academic year in which the course will be held: 
2024/2025
Course type: 
Basic compulsory subjects
Credits: 
5
Period: 
Second semester
Standard lectures hours: 
30
Detail of lecture’s hours: 
Lesson (30 hours)
Requirements: 

The required knowledge are the basic concepts of general and organic chemistry, general biology and cytology.

In order to take the Biochemistry exam, as written in the Regulation of the Course with regard to prerequisites, students must have successfully passed the Chemistry exam.

To verify the learning of the knowledge and skills imparted in class, an oral exam will take place. The questions plan to verify the knowledge of the biochemical processes related to the cellular metabolism of carbohydrates, lipids, amino acids and proteins, their regulation, and the mechanism of plasma transport of oxygen and lipids.

Assessment: 
Voto Finale

The course target is the acquisition by students of the fundamentals regulating the metabolism of molecules of biologic relevance. During the course there will be addressed clinical aspects where the metabolic processes play a critical role in the pathology outcome. The student will be guided to the understanding of the mechanisms that go under the generic name of metabolism, the processes of production and use of energy, the role of the signals (hormones, cytokines, growth factors, etc) in physiology and pathology. The student will learn the function of Biochemistry in clinical medicine, in diagnostic applications and drug therapy, with a learning addressed to the specificities of the profession. The course also aims to educate the student to know the biochemical approaches that have been used to define biological molecules as targets for the pharmacological activity of drugs and to know how to research independently the scientific information.

Chemistry, physical, genetic and evolutionary fundamentals
Water: Weak interactions of acqueous systems, water ionization, weak acids and bases, pH in buffer solutions, water as reagent, Integration of living organisms in water.
Carbohydrates: definitions and classification of aldose and ketoses. Cyclic and Linear molecules. Complex sugars (hexosamine and sialic acid). Disaccharides with biologic relevance (sacarose, maltose, lactose, cellobiose). Structural omopolysaccharides: cellulose; deposit omopolysaccharides.: starch and glycogen. Heteropolysaccharides: glycosaminoglycans.
Proteins: Chemical classification of amino acids. Carboxylic and amino groups reactivity, R and S (D or L) configuration and their biological relevance; Peptidic bond and its chemical-physical characteristics; protein structures: primary, secondary, tertiary and quaternary. Protein function: enzymes and enzymic kinetics, inhibition, covalent and non covalent regulation of enzymes.
Lipids: Simple lipid, fatty acids, classification. Role of double bond in molecular stability. Isomery, Complex lipids: triglycerides, glicerophospholipids, sphingolipids. Biological membrane structure. Cholesterol and its derivates, Glycoproteins, Structural organization of biological membranes, signaling throughout biological membrane: receptors and second messengers.
Oxygen transporters: structural and functional properties of myoglobin and hemoglobin.
Metabolism: Introduction and general concepts; bioenergy, ATP-ADP system as Energy transfer between catabolism and anabolism. Molecular basis of energy content of ATP. Substrate phosphorylation, Energy charge and its role in metabolism regulation, Respiratory chain and oxidative phosphorylation, Glucose activation, Glycogen metabolism and its control mechanisms, Glycolysis and its energy balance, Shunt of hexose monophosphate its biological role and regulation, Glycogen metabolism, Oxidative decarboxylation of piruvic acid. Gluconeogenesis nad its control. Fatty acid oxidation, ketonic bodies, Biosynthesis of lipids and cholesterol and their regulation, Krebs cycle and its energy balance with control. Anaplerotic reactions. Amino acid metabolism; transamination and transdesamination. Defensive mechanisms against ammonia, glutamine biosynthesis and urea cycle. Metabolic adaptation during starvation.
Heme and bilirubin metabolism.
Hormones: general properties and mechanisms. Hormones functions of hypothalamus hypophysis axis, steroids, insulin, glucagon, adrenaline.

The course aims to make the student assume the fundamentals that regulate the metabolism of molecules of biological interest. During the course, references will be made to clinical situations in which these processes are decisive in the appearance of clinical symptoms.

Chemistry, physical, genetic and evolutionary fundamentals
Water: Weak interactions of acqueous systems, water ionization, weak acids and bases, pH in buffer solutions, water as reagent, Integration of living organisms in water.
Carbohydrates: definitions and classification of aldose and ketoses. Cyclic and Linear molecules. Complex sugars (hexosamine and sialic acid). Disaccharides with biologic relevance (sacarose, maltose, lactose, cellobiose). Structural omopolysaccharides: cellulose; deposit omopolysaccharides.: starch and glycogen. Heteropolysaccharides: glycosaminoglycans.
Proteins: Chemical classification of amino acids. Carboxylic and amino groups reactivity, R and S (D or L) configuration and their biological relevance; Peptidic bond and its chemical-physical characteristics; protein structures: primary, secondary, tertiary and quaternary. Protein function: enzymes and enzymic kinetics, inhibition, covalent and non covalent regulation of enzymes.
Lipids: Simple lipid, fatty acids, classification. Role of double bond in molecular stability. Isomery, Complex lipids: triglycerides, glicerophospholipids, sphingolipids. Biological membrane structure. Cholesterol and its derivates, Glycoproteins, Structural organization of biological membranes, signaling throughout biological membrane: receptors and second messengers.
Oxygen transporters: structural and functional properties of myoglobin and hemoglobin.
Metabolism: Introduction and general concepts; bioenergy, ATP-ADP system as Energy transfer between catabolism and anabolism. Molecular basis of energy content of ATP. Substrate phosphorylation, Energy charge and its role in metabolism regulation, Respiratory chain and oxidative phosphorylation, Glucose activation, Glycogen metabolism and its control mechanisms, Glycolysis and its energy balance, Shunt of hexose monophosphate its biological role and regulation, Glycogen metabolism, Oxidative decarboxylation of piruvic acid. Gluconeogenesis nad its control. Fatty acid oxidation, ketonic bodies, Biosynthesis of lipids and cholesterol and their regulation, Krebs cycle and its energy balance with control. Anaplerotic reactions. Amino acid metabolism; transamination and transdesamination. Defensive mechanisms against ammonia, glutamine biosynthesis and urea cycle. Metabolic adaptation during starvation.
Heme and bilirubin metabolism.
Hormones: general properties and mechanisms. Hormones functions of hypothalamus hypophysis axis, steroids, insulin, glucagon, adrenaline.

The course aims to make the student assume the fundamentals that regulate the metabolism of molecules of biological interest. During the course, references will be made to clinical situations in which these processes are decisive in the appearance of clinical symptoms.

Lectures (30 hours, in person) will be imparted to students by using slide projections (usually in Italian but, in cases of recently published material, also in English). During the explanation in the classroom, the students are invited to interact with the teacher with questions and curiosity. During the lectures the teacher will also present cases and daily facts that can make understand the application / importance of the subjects of the teachings.

Students have the obligation to attend classes as established in the educational regulations of the study course and to sign the time sheet for taking the exam.
Teacher undertakes to make projected presentations available to lectures and other material of interest (articles) through the University computer platforms (eg, elearning) to which students have access.

In the teacher's presentations there will be links to web pages for further information. For reception students make an appointment by email with the teacher.

Professors

Parent course