Biochemistry and biochemical analysis of food

A.Y. 2020/2021
Overall hours
Learning objectives
The course aims to provide the basis of structure, properties and functions of the main biological macromolecules, and the basic knowledge on the main metabolic pathways that occur in the body. Moreover, the course will provide the methodological principles of biochemical approaches used to characterize and analyze food: enzymatic methods, immunochemical methods, separation techniques and molecular biology techniques.
Expected learning outcomes
The student will be able to understand the functioning of the main biological processes and the biochemical transformations that main nutrients undergo in metabolism, also depending on the state of nutrition. The student will acquire the knowledge to critically understand the application of biological systems in vitro and/or in biotechnological processes. The student will be able to critically evaluate, both in quantitative and qualitative terms, the results obtained by the main biochemical methodologies suitable for the characterization of food.
Course syllabus and organization

Single session

Lesson period
First semester
Teaching methods
The lessons will be held synchronously preferentially by using Microsoft Teams.
Some lessons, situation permitting, will be in attendance. The methods and criteria for attending face-to-face lessons, which require a reservation with a special app, will be published in the Ariel pages of the course, as well as any change due to the evolution of the legislation imposed by Covid- 19.

Program and reference material
The program and the reference material will not change.

Learning verification procedures and assessment criteria

The exam will be in written form using EXAM.NET + SEB platform, in webconference mode as indicated by the University guidelines or, where the regulation allows it, in attendance, always in writing.
Course syllabus
Amino acids: general properties. Physical properties and chemical reactivity of side chains. Proteins: primary structure and post-translational modifications. The peptide bond. Secondary structure: alpha-helix and beta-sheet. Tertiary structure. Quaternary structure and its functional role. Collagen as an example. Quaternary structure and allosteric regulation: myoglobin and haemoglobin. Enzymes: enzymatically catalysed reactions. Michelis-Menten. Competitive and Uncompetitive inhibition of non-cooperative enzymes. Allosteric enzymes. Covalent regulation of enzymatic activity.
Introduction to metabolism: nature and role of cofactors. ATP, NAD and FAD. Glycolysis. Lactic and alcoholic fermentation. Metabolism of hexoses other than glucose. Gluconeogenesis. Control of glycolysis and gluconeogenesis. Role of fructose-2,6-bisphosphate. Hormonal regulation. Glycogen synthesis and brakedown. Pentose phosphate pathway. Pyruvate conversion to acetyl-CoA. Krebs cycle. Electron transport and oxidative phosphorylation. Energetic Balance of the total oxidation of glucose. Catabolism of fatty acids: beta oxidation. Catabolism of unsatured fatty acids. Fatty acid biosynthesis. Cholesterol biosynthesis. Plasma lipoproteins. Amino acid metabolism: protein digestion and transamination reaction. The urea cycle. Basis of amino acid carbon skeletons catabolism.
Biochemical Analysis of Food
Principles of UV-vis spectrophotometry. Enzymatic methods: principles of enzymology. Enzymatic assays: quantification of enzyme activity and its meaning for food quality. Thermal inactivation of enzymes. Use of enzymatic tests for the quantification of specific compounds in foods. Immunochemical methods: structure and properties of antibodies. Principles and application of semi-quantitative immunochemical methods (Dot Blot). Principles and application of quantitative immunochemical methods (ELISA). Lateral flow tests. Application of molecular biology techniques to food safety issues. Classical and real-time PCR. Electrophoretic methods: principles of electrophoretic techniques. PAGE, SDS-PAGE, IEF, 2D-PAGE. Chromatographic methods: principles of chromatographic techniques. Gel-permeation chromatography. Ionic exchange chromatography. Hydrophobic Interaction Chromatography. Reverse phase chromatography. Affinity chromatography.
Prerequisites for admission
The prerequisites for this course are the basic concepts of cell biology, and the ability to recognize the chemical reactivity of the major functional groups in molecules (-OH, -COOH, -SH, -NH2). Basic mathematics for quantitative approach to biochemistry.
Teaching methods
Frontal lessons and practical classes
Teaching Resources
Biochemical Analysis of Food
Slides presented in class are downloadable from the ARIEL web site of the course.
Assessment methods and Criteria
To verify learning achievements in the course in Biochemistry and Biochemical Analysis of Food students go through a final written exam, in which open-ended questions are proposed. The achievement of the objectives established by the course will be evaluated taking into account the candidate's ability to accurately define the topics, to offer an overall systematic view of the topics, and familiarity with the specific language. It is mandatory to sign up at the exam on the SIFA within the indicated deadline. Evaluation is expressed in thirtieths. Results are communicated to the students by an automatically-generated e-mail.
BIO/10 - BIOCHEMISTRY - University credits: 8
Laboratories: 16 hours
Lessons: 56 hours