Studying at the University of Verona

Here you can find information on the organisational aspects of the Programme, lecture timetables, learning activities and useful contact details for your time at the University, from enrolment to graduation.

Type D and Type F activities

A.A. 2024/2025 A.A. 2023/2024 A.A. 2022/2023 A.A. 2021/2022 A.A. 2020/2021 A.A. 2019/2020 A.A. 2018/2019 A.A. 2017/2018 A.A. 2016/2017 A.A. 2015/2016 A.A. 2013/2014 A.A. 2012/2013 A.A. 2011/2012 A.A. 2010/2011 A.A. 2009/2010 A.A. 2005/2006

This information is intended exclusively for students already enrolled in this course.
If you are a new student interested in enrolling, you can find information about the course of study on the course page:

Laurea in Bioinformatica - Enrollment from 2025/2026

Type D and Type F activities

Type D educational activities are at the student's choice, Type F activities are additional knowledge useful for job placement (internships, transversal skills, project works, etc.). According to the Didactic Regulations of the Course, some activities can be chosen and entered independently in the booklet, others must be approved by a special committee to verify their consistency with the study plan. Type D or F training activities can be covered by the following activities.

1. Teachings delivered at the University of Verona.

Include the teachings listed below and/or in the Catalog of Teachingshttps://www.univr.it/it/catalogo-insegnamenti - Opens in a new window (which can also be filtered by language of delivery via Advanced Search).

Booklet entry mode: if the teaching is included among those listed below, the student can enter it independently during the period- Opens in a new window in which the syllabus is open; otherwise, the student must make a request to the Secretariat, sending to carriere.scienze@ateneo.univr.it- Opens in a new window the form- Opens in a new window in the period indicated- Opens in a new window.

2. CLA language certificate or equivalency.

In addition to those required by the curriculum, the following are recognized for those matriculated from A.Y. 2021/2022:

  • English language: 3 CFUs are recognized for each level of proficiency above that required by the course of study (if not already recognized in the previous course of study).
  • Other languages and Italian for foreigners: 3 cfu are recognized for each proficiency level starting from A2 (if not already recognized in the previous study cycle).

These cfu will be recognized, up to a maximum of 6 cfu in total, of type F if the teaching plan allows it, or of type D. Additional elective credits for language knowledge may be recognized only if consistent with the student's educational project and if adequately motivated.

Those matriculated up to A.Y. 2020/2021 should consult the information found here- services - cla - language exercises - science and engineering https://www.scienzeingegneria.univr.it/?ent=iniziativa&id=4688 - Opens in a new window.

Booklet entry modeapply for the certificate- Opens in a new window orequivalency- services - recognition of external language certifications - cla Opens in a new window to the CLA and send it to the Student Secretariat - Careers for the inclusion of the exam in the career, by email: carriere.scienze@ateneo.univr.it- Opens in a new window

3. Soft skills

Discover the training paths promoted by the University's TALC - Teaching and learning centerhttps://talc.univr.it/ - Opens in a new window, intended for students regularly enrolled in the academic year of course delivery https://talc.univr.it/it/competenze-trasversali- Opens in a new window

Booklet entry mode: The teaching is not intended to be included in the syllabus. Only upon obtaining theOpen Badgehttps://talc.univr.it/it/servizi/open-badge - Opens in a new window will the booklet CFUs be automatically validated. The registration of CFUs in career is not instantaneous, but there will be some technical time to wait.

4. Contamination lab

The Contamination Lab Verona (CLab Verona) is an experiential pathway with modules dedicated to innovation and business culture that offers the opportunity to work in teams with students from all courses of study to solve challenges launched by companies and institutions. The pathway allows students to receive 6 CFUs in the D or F area. Discover the challenges: https://www.univr.it/clabverona- Opens in a new window

PLEASE NOTE: To be eligible to take any teaching activity, including electives, you must be enrolled in the year of the course in which it is offered. Therefore, it is recommended that undergraduates of the December and April sessions DO NOT take extracurricular activities of the new academic year, in which they are not enrolled, since these degree sessions are valid with reference to the previous academic year. Therefore, for activities carried out in an academic year in which they are not enrolled, no recognition of CFUs can be given.

5. Internship/internship period

In addition to the CFUs stipulated in the curriculum (check carefully what is indicated on the Educational Regulationshere- services - internships and apprenticeships - science and engineering It opens in a new window you can find information on how to activate the internship.

Check in the regulations which activities can be Type D and which can be Type F.

Please also note that for internships activated from October 1, 2024, it will be possible to recognize excess hours in terms of Type D credits, limited only to internship experiences carried out at host institutions outside the University.

Academic year:
Semester 1  From 10/1/24 To 1/31/25
years Modules TAF Teacher
2° 3° Attention Laboratory D Pietro Sala (Coordinator)
2° 3° Elements of Cosmology and General Relativity D Claudia Daffara (Coordinator)
2° 3° Introduction to quantum mechanics for quantum computing D Claudia Daffara (Coordinator)
2° 3° Introduction to smart contract programming for ethereum D Sara Migliorini (Coordinator)
2° 3° Python programming language [English edition] D Carlo Combi (Coordinator)
2° 3° BEYOND ARDUINO: FROM PROTOTYPE TO PRODUCT WITH STM MICROCONTROLLER D Franco Fummi (Coordinator)
2° 3° APP REACT PLANNING D Graziano Pravadelli (Coordinator)
2° 3° HW components design on FPGA D Franco Fummi (Coordinator)
Semester 2 From 3/3/25 To 6/13/25
years Modules TAF Teacher
2° 3° Attention Laboratory D Pietro Sala (Coordinator)
2° 3° LaTeX Language D Enrico Gregorio (Coordinator)
2° 3° Python programming language [Edizione in italiano] D Carlo Combi (Coordinator)
2° 3° Rapid prototyping on Arduino D Franco Fummi (Coordinator)
2° 3° Programming Challanges D Romeo Rizzi (Coordinator)
2° 3° Tools for development of applications of virtual reality and mixed D Andrea Giachetti (Coordinator)
2° 3° Development and life cycle of software of artificial intelligence software D Marco Cristani (Coordinator)
2° 3° Protection of intangible assets (SW and invention)between industrial law and copyright D Mila Dalla Preda (Coordinator)
List of courses with unassigned period
years Modules TAF Teacher
Subject requirements: mathematics D Franco Zivcovich (Coordinator)

General Biology  (2024/2025)

Teaching code

4S00997

Teacher

Elisabetta Trabetti

Coordinator

Elisabetta Trabetti

Credits

6

Language

Italian

Scientific Disciplinary Sector (SSD)

BIO/13 - EXPERIMENTAL BIOLOGY

Period

Semester 2 dal Mar 3, 2025 al Jun 13, 2025.

Courses Single

Authorized

Lessons timetable MoodleMoodle Seminars 0

Learning objectives

The course purposes are: (i) to give basic knowledge about living organism characteristic: procariots, eucariots, viruses, through the acquisition of the fundamental concepts of biology and of the structural, functional and molecular principles of cellular processes; (ii) to describe the fundamental concepts of genetics and the transmission of hereditary characters in different organisms, with specific exam-ples of pathological traits in humans; (iii) to provide basic knowledge on the mechanisms governing the flow of genetic information and the development of organisms; (iv) to provide basic knowledge of animal behavior; (v) to educate to the critical evaluation of experimental data, describing and discuss-ing past and contemporary important experiments; (vi) to provide the up-to-date methodologies used in the biological molecules studies. At the end of the course, students should demonstrate to have acquired notions to become fruitful for a critical analysis of the mechanisms which regulate intra/intercellular activities, cellular interactions and reproduction, organism-to-organism interactions and organisms-to-environment interactions and cause mutations. Students are expected to be autonomous in the evaluation of the mentioned process-es. They should also demonstrate to have acquired knowledge of the flow of genetic information, growth and development of living organisms, Mendelian genetics and of animal behavior. Students should also demonstrate to have acquired basic knowledge of methodologies used in the biological molecules studies and their capability to expose reasoning in a critical and precise manner using ap-propriate scientific language. Students will be able to use the specific notions of biology and genetic bases of life to propose appropriate and original solutions in computer applications; students will also acquire the ability to read and understand advanced biological topics and will therefore be able to attend more advanced courses (including a master's degree) both in the biotechnology and bioinformatics field.

Prerequisites and basic notions

There are no prerequisites.

Program

• GENERAL OUTLINE OF BASIC BIOLOGY ISSUES: characteristics of the living beings, levels of biological organisation. Transmission of information between organisms and across generations, hierarchical classification of living organisms, and energy flow through ecosystems.
• CHEMICAL ELEMENTS OF LIFE. Chemical elements, organic molecules and macromolecules in living organisms. Characteristics and properties of water, an essential constituent of life.
• PRINCIPAL INSTRUMENTS AND METHODS OF CELL INVESTIGATIONS: cell size, basic optical and electron microscopy concepts, and cell fractionation.
• THE CELL. Cell theory. Organisation of prokaryotic and eukaryotic cells. Characteristics and functions of membranes, organelles, cytoskeleton, cilia, flagella, cell wall, extracellular matrix. Animal and plant cells. Mitochondria and plastids and endosymbiont theory. Essential characteristics of different cells and significant tissue types.
• BIOLOGICAL MEMBRANES. Structure and proposed models. Membrane lipids and proteins, their function. Movement through the plasma membrane: osmosis, simple and facilitated diffusion, directly and indirectly, active transport. Exocytosis and endocytosis. Cell junctions in animal and plant cells.
• CELL COMMUNICATION. Types of cellular communication. Sending and receiving the signal. Surface and intracellular receptors. Signal transduction and second messengers. Cellular response to signals.
• ENERGY FLOWS THROUGH LIVING ORGANISMS. Energy and metabolism: energy and biological work; general aspects of metabolism, anabolism and catabolism, energy coupling, energy transfer systems. Function and regulation of enzymes as biological catalysts.
• METABOLIC PATHWAYS THAT RELEASE ENERGY. Anaerobic and aerobic respiration, fermentation. Photosynthesis, photorespiration. The classification of living beings is based on the methods of capturing energy and sources of carbon.
• NUCLEAR ORGANIZATION. Cell cycle and its regulation, apoptosis, fundamental aspects of deregulation and cancer. Mitosis, meiosis and sexual reproduction.
• PRINCIPLES OF HEREDITY. Mendel’s laws. Physical association or independence. Crossing-over and recombination. Sex determination systems in animals and some examples of Mendelian traits in humans. Extensions of Mendelian principles.
• DNA AS THE HEREDITARY MATERIAL IN THE CELL. Essential elements of DNA structure, replication and biological ability of cells to preserve hereditary material.
• GENE EXPRESSION AND REGULATION IN DIFFERENT ORGANISMS. Essential elements of genetic information pathway and their regulation in prokaryotic and eukaryotic cells.
• BIOINFORMATIC in Sistem Biology. General aspects and examples of application.
• DEVELOPMENT BIOLOGY. Essential elements of cell differentiation and morphogenesis, somatic and germ cells, and stem cells. Model organisms in biology. Genetic control of development, maternal effect genes, segmentation genes, and homeotic genes.
• DARWIN AND EVOLUTION. Natural selection, synthetic theory of evolution (neo-Darwinism). Evidence for evolution: fossils, comparative anatomy, developmental biology and evolutionary patterns. Molecular comparison among organisms, universality of the genetic code, evolutionary changes in proteins and DNA.
• GENERAL BIOLOGY OF VIRUES AND PROKARIOTES. Hints of virus classification, their origin hypothesis. Lytic and lysogenic cycle. Examples of viruses and types of infections are viroids and prions. Archaea and Bacteria domains. Binary fission and reproduction of bacteria. Types of genetic information transfer. Evolution of bacterial populations, sporulation, biofilm. Colonisation of extreme environments; symbiotic relationship
• ANIMAL BEHAVIOUR. The influence of sensory stimuli, learning, and genetic heritage. The selection for survival and reproductive success, the concept of total fitness.

Bibliography

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Visualizza la bibliografia con Leganto, strumento che il Sistema Bibliotecario mette a disposizione per recuperare i testi in programma d'esame in modo semplice e innovativo.

Didactic methods

The didactic methods adopted for teaching consist of frontal lessons accompanied by multimedia presentations such as PowerPoint, videos and animations, self-evaluation quizzes, also making use of the range of innovative tools at the service of teaching (links to multimedia resources, Wooclap, Jove and others interactive software, etc) specially integrated into the Moodle platform and usable by all students of the course. Some fundamental biological experiments will be described, and practical examples will be illustrated to develop the ability to interpret experimental data and critically rework the knowledge acquired. Any other supplementary and in-depth material will be made available on the University's Moodle platform on the page dedicated to teaching. During the academic year, an individual reception service is available by emailing the teacher during flexible hours. Students are advised to choose a text from those indicated in the Bibliography sheets of the University Library System.

Learning assessment procedures

The exam consists of a written test made up of 40-45 questions (single response, multiple choice, true/false, completion tests) relating to all the topics indicated in the course programme to verify both the achievement of the theoretical knowledge and the ability of students to reason and re-elaborate the knowledge acquired individually. The maximum duration of the Biology test is 75 minutes.

Students with disabilities or specific learning disorders (SLD), who intend to request the adaptation of the exam, must follow the instructions given HERE

Evaluation criteria

To pass the test, students shall demonstrate comprehension and knowledge of teaching topics, reasoning skills and personal re-elaboration of notions.
The Biology test is considered passed if the evaluation is at least 18/30.

Criteria for the composition of the final grade

Single test examination

Exam language

Italiano

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