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Pharmaceutical Science with Drug Development
Bachelor of Science
Course Details
CAO Code | AU857 |
---|---|
Level | 7 |
Duration | 3 Years |
CAO Points | 241 (2024) |
Method of Delivery | On-campus |
Campus Locations | Sligo |
Mode of Delivery | Full Time |
Work placement | Yes |
Course Overview
Pharmaceutical Science combines a range of scientific subjects that are vital in the development, discovery, processing and manufacturing of different drugs and therapies. The overall philosophy of this degree is to produce science graduates who can assume positions of responsibility in the area of pharmaceutical science.
Ireland is now the third largest exporter of pharmaceuticals globally, accounting for €116+ billion in exports annually. Pharmaceutical exports jumped to almost €9bn in January 2024, up 48% from the same time in 2023. This industry accounted for 47.5% of all Irish exports across the month.
Over 30,000 people are employed in biopharma companies in Ireland, with 90+ companies operating here. With 19 of the world’s top 20 pharmaceutical firms based in Ireland, the demand within the pharmaceutical and MedTech industries for skilled graduates is at an all-time high.
Overview
This degree provides students with a broad but thorough background in the chemical, biological, and technological disciplines as they relate to the study of medicinal products. It allows students to develop a range of skills, covering scientific, engineering, regulatory and quality issues, as well as delivering excellent communication skills. Modules are based around the core pharmaceutical sciences, but with emphasis also placed on modern technology and advances within the sector.
Students have the option to complete a work placement between Year 3 and Year 4. This can last for four months or a full year. Some students have taken the opportunity to travel to the USA, Italy, Malta and the UK to complete their work placement.
A final year project allows students to make use of the knowledge and skills they have gained throughout the programme. Students can also apply for an Abbott Excellence Science Award. Successful students get an internship and valuable work experience with one of the many leading pharmaceutical companies in our region.
Our degrees have a strong lab and practical element which allows students to build their competencies and skills. We also recognise the importance of transferable skills such as data presentation, information-sourcing and scientific-technical writing which enhances employability, and expands students knowledge and understanding of the sector.
Year 1
Students start with learning the fundamentals of the basic science subjects in biology, chemistry, physics, maths, and an introduction to pharmaceutical science as a subject. Tutorials in all of these subjects are provided to support students who may not have studied these before. Students have laboratory sessions in all of the subjects. This is an excellent way of getting hands-on experience with science and to get to know their classmates.
Year 2
As students progress through the degree, subjects become more specialised. Modules include Dosage Formulation, Biopharmaceuticals, Pharmaceutical Manufacturing, Quality Systems, Validation, and Pharmaceutical Legislation.
Year 3
The emphasis in Year 3 is on applying the knowledge gained in the first two years to the specific needs of the pharmaceutical sector. Students have the option to complete a work placement between Year 3 and Year 4. This can last for four months or a full year.
Common Entry
Environmental Science with Ecology
Occupational Safety and Health
Biomedical Science
Pharmaceutical Science with Drug Development
Course Details
Year 1
Semester | Module Details | Credits | Mandatory / Elective |
---|---|---|---|
1 |
Mathematics for Science 1In this module, the fundamentals of mathematics required for a Science qualification are covered. All effort in this semester is focused on the student's need to understand and practice basic mathematical processes and their application to real life and science. Students are supported in their efforts by a comprehensive VLE site containing videos, notes and quizzes relevant to each topic. There are supervised tutorials twice a week to help solve the problems encountered in the module. Learning Outcomes 1. Perform calculations involving basic operations without a calculator. 2. Use powers and scientific notationto express values and evaluate expressions. 3. Perform unit conversions and simple pharmaceutical calculations 4. Manipulate and solve mathematical expressions correctly. 5. Plot and analyse linear, quadraticand simultaneous equations. |
05 | Mandatory |
1 |
Introduction to Pharmaceutical ScienceThis module introduces students to the fundamental aspects of the pharmaceutical industry sector, both nationally and internationally. The pharmaceutical industry is one of the largest and most exciting sectors to be working in today. It is a rapidly changing environment where many advances have taken place over the past 25 years. Furthermore, it will continue to develop and evolve at an ever-increasing pace over the next decade. New drugs, new technologies and exciting new discoveries have driven this evolution. Learning Outcomes 1. Recognise the general requirements of the pharmaceutical Industry in Ireland/Globally . 2. Identify the main types/sources and classes of pharmaceutical products. 3. Explain the manufacturing cycle in the production of pharmaceuticals. 5. Describe the role of the regulatory authorities in the Pharmaceutical industry. |
05 | Mandatory |
1 |
Physics 1This is an introductory Physics course relevant to all fields of Science. The principal topics include mechanics, materials and heat and consist of lab investigations in these areas. Learning Outcomes 1. Explain physical laws and definitions of Mechanics, Materials,and Heat.. |
05 | Mandatory |
1 |
Chemistry 1This module introduces students to general fundamentals of chemistry, including atomic theory, bonding, solution concentration, pH, stoichiometry, oxidation and reduction. Learning Outcomes 1. Use the periodic table to define and describe the structure of atoms, ions and molecules. |
05 | Mandatory |
1 |
Information Technology 1This module deals with the practical applications of Information Technology. It serves as an introduction to the computer systems the student will use while taking their chosen course in the college. It also covers the fundamental skills of word processing, presentation and spreadsheet software. The teaching methods used will be a combination of lectures, self-study, labs, tutorials, problem-solving exercises and computer-based learning. Learning Outcomes 1. Use the IT infrastructureand Virtual Learning Environment to perform standard IT tasks to assist in their future studies 2. Identify the main component parts and peripheral devices of a standard computer system. |
05 | Mandatory |
1 |
Biology 1The module aims to introduce learners to the structure and function of the major biological macromolecules of the cell. The module also introduces learners to the structure and functions of eukaryotic and prokaryotic cells. Learning Outcomes 1. Describe the structures and functions of the eukaryotic cells andcell organelles. 2. Describe the structures and functions of the prokaryotic cells 3. Illustrate how cellsdivide. 4. Describe the structure and function of biological macromolecules |
05 | Mandatory |
2 |
Mathematics for Science 2This module introduces the functions which occur most commonly in science and ways of examining their behaviour. The primary focus is to understand where these functions occur, both in real life and science, and to provide students with the ability to recognise and analyse them appropriately. The module also introduces statistical methods and analysis. Learning Outcomes 1. Analyse and sketch polynomial functions of a linear, quadratic and cubic nature. Discuss real world applications of these functions 2. Analyse and sketchfunctions of a sinusoidal and rational nature. Discuss real world applications of these functions 3. Analyse and sketchfunctions of alogarithmic and exponentialnature. Discuss real world applications of these functions 4. Use differential Calculus toanalyse max/min curves and solve optimisation problems. 5. Identify different types of data and use appropriate tables and curves to analyse data sets. |
05 | Mandatory |
2 |
Physics 2This is an introductory Physics course relevant to all fields of Science. The principal topics include waves, sound, electricity, magnetism, light & optics and nuclear physics and consist of lab investigations in these areas. Learning Outcomes 1. Explain physical laws and definitions of waves, sound, electricity, magnetism, light & optics and nuclear physics. |
05 | Mandatory |
2 |
Introduction to Drug Discovery and DevelopmentThis module introduces students to historical and contemporary aspects of drug discovery and development and examines the importance of regulation within the pharmaceutical sector. Learning Outcomes 1. Discuss the drug discovery process, from both historical and comtemperory perspective. |
05 | Mandatory |
2 |
Chemistry 2This module introduces student to fundamentals of Organic Chemistry and Physical Chemistry. Learning Outcomes 1. Describe the structural characteristics of the various homologous series and functional groups. |
05 | Mandatory |
2 |
Information Technology 2This module deals with advanced practical applications of Information Technology. It covers the software packages for spreadsheets, desktop publishing, electronic notebooks and data management. The teaching methods used will be a combination of lectures, self-study, labs, tutorials, and any combination of discussion, case study, problem-solving exercises and computer-based learning. Learning Outcomes 1. Model problems using advanced features of Excel and build on concepts learned in Information Technology 1 3. Create brochures and information leaflets using an appropriate software 4. Use online cloud tools and other software packages for data management and collaboration. |
05 | Mandatory |
2 |
Biology 2The module also introduces the structure and functions of the different organ systems of the body. Learning Outcomes 1. Describe the structure and function of therespiratory and excretory systems 5. Perform and report on, biological laboratory experiments and communicate information accurately and effectively using written, visual and numeral forms |
05 | Mandatory |
Year 2
Semester | Module Details | Credits | Mandatory / Elective |
---|---|---|---|
1 |
MicrobiologyThe aim of this module is to introduce the student to both the theoretical and practical aspects of basic microbiological techniques required to safely handle, investigate and manipulate micro-organisms in laboratory setting. Students will be provided with the opportunity to acquire knowledge of the subject matter through a variety of lecturer led activities and self-directed study. Such activities will include traditional and interactive lectures, problem solving and revision tutorials and laboratory practical classes. Theoretical and practical problems will be employed to assist students in the development of their analytical and problem solving capabilities. Learning Outcomes 1. Understand that microorganisms comprise a diverse range of organisms that includes bacteria, fungi, protozoans, algae, viruses and sub-viral particles. |
05 | Mandatory |
1 |
Organic Chemistry 1This module examines the structure and chemistry of aliphatic organic molecules, covering saturated and unsaturated hydrocarbons (both cyclic and alicyclic) and the various functional groups. Reactivity and reaction mechanisms for a selection of functional group inter-conversions will be studied as will some important organometallic compounds. Learning Outcomes 1. Expalin the concept of hybridisation in describing the structure of some hydrocarbon molecules |
10 | Mandatory |
1 |
BiochemistryThis module enables students to explain the functions, structures and properties of biomolecules including their roles in disease. Additionally, the development of laboratory-related skills is facilitated among students. Learning Outcomes 1. Describe the structure, function and characteristics of, carbohydrates, fats, nucleic acids and proteins (including those used to treat disease). 4. Demonstrate proficiency in the performance of a variety of laboratory techniques. |
05 | Mandatory |
1 |
Environment Health and SafetyThis module will give students a foundation in Environmental Health and Safety enabling them to apply these fundamentals to the area of pharmaceutical science. Learning Outcomes 1. Identify hazards in the workplace and apply appropriate control measures with special reference to the needs of the pharmaceutical sector. |
05 | Mandatory |
1 |
Physical ChemistryThis module introduces students of physical sciences to the concepts of gas behaviour, thermodynamics, chemical equilibrium, electrolytes and acid-base behaviour. Learning Outcomes 1. Define various laws that are fundamental to physical chemistry. |
05 | Mandatory |
2 |
Introduction to BiopharmaceuticalsIntroduction to Biopharmaceuticals will provide the student with a broad overview of the Biopharmaceutical sector. Learning Outcomes 1. Demonstrate knowledge of the various technologies and disciplines that contribute to Biotechnology and Biopharmaceutical drug target discovery. |
05 | Mandatory |
2 |
Organic Chemical SynthesisThis module further enhances aspects of organic chemical synthesis building on techniques covered in semester 1. Learning Outcomes 1. Recognise a range or organic functional groups and their reactivity 2. Demonstrate competence in the practical application of a range of synthetic organic chemical techniques. 3. Calculate chemical yields (theoretical, actual and percent),perform productreconciliation and explain losses 4. Demonstrate the ability to maintain a proper laboratory notebook, which includes clear descriptions of original data, observations and experimental procedures 5. Evaluate the risks associated with an experiment and understand how to mitigate against such risks |
05 | Mandatory |
2 |
Inorganic ChemistryThis course provides a theoretical and a practical introduction to inorganic chemistry. Fundamental aspects of inorganic chemistry relevant to pharmaceutical science are presented in the theory component of the module. The module develops the ability to carry out inorganic chemistry analytical techniques with confidence and with a high level of accuracy and precision. Learning Outcomes 1. Describe the basic concepts of inorganic chemistry including atomic number, atomic mass, atomic orbitals and electronegativity values 2. Describe the concepts of molecular bonding including models such as MO theory and VSEPR 3. Describe chemistry concepts related to acids, bases and ions in solution. 4. Demonstrate understanding of special topics such as catalysis, coordination chemistry and/or electron transfer. 5. Demonstrate ability to work safely in a chemical laboratory. 6. Perform inorganic chemistry analytical techniques. 7. Record dataof analytical work and write concise experimental reports. 8. Analyse experimental data and draw conclusions on validity of data. |
10 | Mandatory |
2 |
Pharmaceutical Analytical MethodsIntroductory analytical techniques building on chemistry 1 and chemistry 2. The course introduces the student to fundamental chemical analytical techniques with a focus on chemical structures, concentration terms, classical and instrumental methods of determining qualitative and quantitative data. This module covers volumetric analysis including the application of primary and secondary standards. The module provides an introduction to instrumental techniques, such as, infrared spectroscopy, ultraviolet visible spectroscopy, atomic spectrometry, electroanalytical and chromatography. Learning Outcomes 1. Explain the purpose of most common analytical tests and describe fundamental strategies for the performance of classical and instrumental chemical analysis. 2. Explain the fundamental principles of a range of instrumental and classical methods of analysis. 3. Calculate chemical compositions from raw instrumental and noninstrumental analytical data and express chemical compositions in a range of concentration units. 4. Interpret qualitative data and ascertain chemical structures from analytical measurements. 5. Evaluate the reliability of analytical data using simple statistical and quality control techniques. |
05 | Mandatory |
2 |
Pharmaceutical MicrobiologyThe aim of this module is to introduce the student to both the theory and practical aspects of microbiology related to the production of a range of biomedical products, including pharmaceuticals, medical devices and immunodiagnostic materials. Students will be provided with the opportunity to acquire knowledge of the subject matter through a variety of lecturer led activities and self-directed study. Such activities will include traditional and interactive lectures, problem solving and revision tutorials and laboratory practical classes. Theoretical and practical problems will be employed to assist students in the development of their analytical and problem solving capabilities. Learning Outcomes 1. Understand microbial ecology and its relationship to biomedical products manufacture. |
05 | Mandatory |
Year 3
Semester | Module Details | Credits | Mandatory / Elective |
---|---|---|---|
1 |
Pharmaceutical Processing and Medical Device ManufactureThis module details the diverse array of manufacturing processes & equipment employed in the pharmaceutical industry, in combination with the product packaging techniques. Additionally, it provides the student with a broad understanding of the various types of medical devices available and the modes and methods of manufacture. Learning Outcomes 1. To detail the mainstream systems and equipment used for generation of EP and USP grade water for Pharm/Biopharma production and manufacture. |
05 | Mandatory |
1 |
Biopharmaceuticals 2This course aims to provide the student with a broad understanding of the various aspects of the biomanufacturing process. The module will explore the technologies employed during upstream, downstream, formulation, fill-finish and delivery of biopharmaceuticals. Learning Outcomes 1. Identify and evaluate the key factors that are involved in upstream and downstream bioprocessing. 2. Identify key challenges involved in the formulation of biopharmaceuticals and explain the principal stages of sterile fill-finish operations. 3. Demonstrate knowledge of the key elements in a systematic approach to Biopharmaceutical Process Validation. |
05 | Mandatory |
1 |
Pharmaceutical ChemistryThis module provides the student with an understanding of the chemistry behind (i) the structure of some selected groups of organic chemical molecules relevant to pharmaceutical and chemical industry and (ii) the intermolecular forces and chemistry behind liquid / solid / gas interfaces that give rise to their characteristic properties. Learning Outcomes 1. Name, identify and recognise the structure of a range of selected organic groups of molecules that are relevant to the pharmaceutical and chemical industry, including their structure, stereochemistry and synthesis. 2. Demonstrate knowledge of interfacial chemistry at the liquid / gas / solid boundaries. 3. Relate the concepts of interfacial chemistry and the functions of the organic groups covered in the module to their role in pharmaceutical and chemistry related applications. 4. Demonstrate numerical and problem solving skills to examine properties and illustrate examples relevant to the content of the module. |
05 | Mandatory |
1 |
Scientific CommunicationsThrough team problem based project work, this module addresses written and spoken communication of scientific information and emphasises personal and professional development skills for students including self awareness, interpersonal skills, interview skills, organisation and project management skills. Learning Outcomes 1. Identify and assess own skill set in relation to graduate opportunities. 2. Establish and demonstrate active pursuit of career goals. 4. Write a fully referenced technical report. |
05 | Mandatory |
1 |
Statistics for ScientistsThis course is designed to provide an introduction to a range of statistical tools of relevance to scientists. Specific topics include an overview of statistical distributions, significance testing, uncertainty determination, linear regression and experimental design. The application of statistics for quality control and practical experience in the application of statistical features in the widely available Microsoft Excel is particularly emphasised. The teaching methods used will be a combination of lectures, self-study, labs, tutorials, and any combination of discussion, case study, problem-solving exercises and computer-based learning. Learning Outcomes 1. Describe basic statistical terms which are of relevance to the area of analytical science. 2. Graphically display and numerically summarise data using appropriatetables, graphs and measures of centre, spread and position. 3. Explain and apply concepts of basic probability including, conditional probability, Bayes’ theorem, independent events and counting formulae; 4. Make interferences about population parameters using sample statistics using confidence interval estimates and tests of statisticalhypotheses 5. Describe the application of statistics tosampling, quality control, analytical method validation andexperimental design. 6. Use an appropriate method for analysingrelationships between variables in a dataset |
05 | Mandatory |
1 |
Pharmaceutical Pre-Formulation StudiesThis module aims to provide the student with an understanding of the techniques employed in the early phase of research & development, in which pre-formulation studies focus on assessing the physical and chemical properties of a drug molecule that affect the molecules performance and activity. This provides important information for formulation design or supports the need for molecular modification prior to the compounding process that will assist in developing a stable, safe and effective formulation with maximum bioavailability. Learning Outcomes 1. Report on the terminology and concepts t o establish the physicochemical parameters of a new/existing drug entity 2. Describe the thermodynamics of Colloidal Systems and the stability of dispersed systems 4. Examine methods t o establish a compounds compatibility with common excipients 5. Explain different processing strategies to support the dosage form design, drug processing and storage |
05 | Mandatory |
2 |
Pharmaceutical FormulationThis module aims to provide the student with an in-depth understanding of the fundamental activities and processes underpinning the formulation design, the bulk product manufacture and quality control activities of the primary pharmaceutical dosage forms (formulations). Learning Outcomes 1. Summarise the process and main objectives in designing and developing a formulated drug product. 5. Identifyrelevant compendial tests and specifications for QC of conventional dosage forms. 6. Propose and prepare appropriate pharmaceutical formulation based on end use and r elate preformulation activities to dosage form design, development and manufacture to solve formulation problems 7. Demonstrate an awareness of current advances in drug delivery and formulation Design. 8. Generate and follow Standard Operating procedures (SOP’s) in the execution of key manufacturing and QC processes |
10 | Mandatory |
2 |
Pharmaceutical Quality SystemsThis module will demonstrate the importance of the systems approach both to quality and manufacturing within the highly regulated pharmaceutical sector. systems such as ISO 9000:2015 and ISO17025:2017 will be examined and topics such as document and product traceability will be analysed. Learning Outcomes 1. Evaluate the development and importance of Quality System Standards. 4. Illustrate the importance of documentation as required by a Quality System. |
05 | Mandatory |
2 |
Active Ingredient SynthesisThis module involves the synthesis of a range of Active Pharmaceutical Ingredients and associated regulatory aspects of the process. Learning Outcomes 1. Demonstrate competence in the application of a range of organic chemical synthetic techniques to the production of some common active pharmaceutical ingredients. 3. Determinequantities ofstarting materials as well as relevantglassware and equipment required for each synthesis 4. Generate and follow Standard Operating Procedures (SOP’s) in theuse of some standard laboratory equipment. 5. Recordand report onthe synthetic method, including any deviations or variations to the process. 6. While working as a member of a group, evaluate the risks associated with each synthetic method and understand how to mitigate against these risks |
05 | Mandatory |
2 |
Pharmaceutical AnalysisThis module addresses the essential practical and theoretical aspects of pharmaceutical analysis with a particular focus on separation science. Students will engage in testing and reporting on the quality of a selection of pharmaceutical APIs and finished products using both compendial and non-compendial methods with due consideration to GMP throughout. The module also addresses the issues of quality within measurements and also addresses aspects of sample preparation and pre-treatment. Learning Outcomes 1. Describe the purpose of the most common analytical tests carried out in the context of pharmaceutical manufacturing and quality control. 2. Relate key structural and physicochemical properties of pharmaceutical compounds to their analysis: eg appropriateanalytical techniques, sample preparation and analytical conditions. 3. Identify suitable sample preparation techniques for a variety of pharmaceutical samples. 6. Perform qualitative and quantitative laboratory analyses on Pharmaceutical APIsand Finished Products using a selection of compendial and non-compendialmethods and with due consideration of GLP/GMP 7. Interpret data from qualitative and quantitative chromatographic determinations in relation to a stated test hypothesis or quality specification. |
10 | Mandatory |
Progression
Graduates may progress to Level 9 Masters or Level 10 PhD programmes across a range of disciplines in ATU or in other third level institutions.
Graduates have completed further study in order to become Pharmacists. Students complete this further study in Scotland, Ulster University, or Liverpool.
ATU Sligo hold an agreement with the Royal College of Surgeons in Ireland (RCSI) in Dublin, where students can progress onto their pharmacy degree programme.
Download a prospectus
Entry Requirements
Leaving Certificate Entry Requirement | 5 subjects at O6/H7 English or Irish at O6/H7 Maths at O6/H7 or Foundation Maths at F2 |
QQI/FET Major Award Required | Any |
Additional QQI/FET Requirements | C20139 or 5N1833 or C20174 or C20175 or 5N18396 or 5N0556 or Leaving Certificate Maths at 06/H7/F2 |
Testimonial
“I loved the 50:50 split between theory and practical lab work on the degree. For example, you might be learning all about a reaction between raw materials that will result in a white powder drug in a theory class. Then, you step into the lab and actually get to make this white powder yourself. It helps you understand everything you were told in the theory class.
It also helps you prepare for the real world. The modules relate directly to different areas of the industry that you will eventually move into. On top of that, most of our lecturers have worked in the industry in the past and know exactly what they are talking about. As the class size is small, the lecturers and staff get to know you on a first-name basis. The help and advice they offer is unbelievable too.
In late September 2019, about thirty students were interviewed for the Abbott internships of which four, including me, were offered twelve month contracts. I was placed in the Business Excellence Department of their Diagnostics Division in Sligo from January 2020 to January 2021. In Business Excellence you are involved with almost every other department, assisting with idea generation, coordinating and leading monthly target reviews, and assisting with cost improvement projects. I really enjoyed the experience and what I learnt has enhanced what I have learnt during my studies. Since graduating, I have secured a full-time position as an Associate Quality Professional with Abbott.”
Alannah McGrory, Pharmaceutical Science with Drug Development graduate and now employed as an Associate Quality Professional with Abbott
Fees
Total Fees EU: €3000
This annual student contribution charge is subject to change by Government. Additional tuition fees may apply. Click on the link below for more information on fees, grants and scholarships.
Total Fees Non-EU: €12000
Subject to approval by ATU Governing Body (February 2025)
Further information on feesCareers
Graduates work in the pharmaceutical, biopharmaceutical, biomedical and medical device sectors in the areas of legislation and regulatory affairs, formulation, analysis, validation, production and quality systems. There is a very high direct employment rate from this degree to companies such as Abbott, AbbVie, Pfizer, Eli Lily. Baxter and Allergan.
Ireland’s life sciences sector has a global reputation for operational and innovational excellence. Ireland is now the third largest exporter of pharmaceuticals globally, accounting for €116+ billion in exports annually. Pharmaceutical exports jumped to almost €9bn in January 2024, up 48% from the same time in 2023. This industry accounted for 47.5% of all Irish exports across the month.
20 pharmaceutical firms based in Ireland, the demand within the pharmaceutical and MedTech industries for skilled graduates is at
an all-time high.
Further Information
Contact Information
T: +353 (0)71 931 8510
E: admissions.sligo@atu.ie