Design of equipment, processes and facilities for food, biotechnology and related food process industries.

Principles of Quality Control System design in a food plant with emphasis on total quality management. Review of the statistical background of quality control as applied to food quality attributes. Quality control charts, sampling techniques and acceptance sampling plans as applied to foods and beverages.

FE 503 Advanced Microbiology (3-0)3 /Course Web Page

Application of basic microbiological concepts to biotechnology. Cultivation of microorganisms, growth kinetics, continuous culture. Preservation, maintenance and isolation of microorganisms for industrial processes. Cell composition, anabolism and catabolism.

FE 504 Advanced Food Plant Sanitation (3-0)3/Course Web Page

The role of sanitation in food industry, the relationship of microorganisms to sanitation. Introduction to HACCP (Hazard Analysis at Critical Control Points), sanitation practices in different food processing systems, cleaning compounds, sanitizers, waste product handling.

Methods of production of dairy, horticultural, meat products.  Fats and oils and their products and all other food processing industries including sugar, chocolate, beverage etc.

The principles of empirical and model building and optimization are covered. Response Surface Methodology (RSM), Evolutionary Operation (EVOP), Taguchi methods and the philosophy of statistically designed experiments for product/process development are considered.

FE 507 Advanced Instrumental Methods in Food Analysis (3-0)3  

Theory and application of  spectroscopic and chromatographic techniques for food and biological analysis. The content for instruments may include UV-VIS Spectroscopy, GC, HPLC, ICP-AES. Preparation of a project on application of advanced instrumental techniques on food or biological samples will be required from students at the end of the semester.

Molecular characterization of food components with respect to molecular weight and structure, crystal structure and thermal properties. Functional characterization of food components as emulsifiers, stabilizers, texturizers, gelling and foaming agents. Relationship between molecular and functional properties of food components. Porosity and pore structure. Textural characterization of food materials with emphasis on food gels, emulsion and porous solid food materials.

Principles of food processing and preservation with emphasis on the application of biotechnology. Treatment of food industry and agricultural wastes. Production of nutrients, fermented food stuffs, processing aids, flavors, functional food ingredients etc. via enzyme, fermentation technology and tissue culture.

FE 515 Food Additives, Contaminants and Toxicology (3-0)3 

Acute, chronic and genetic toxicology of naturally occurring food substances, intentional and incidental food additives. Incidence and mode of action of foodborne pathogenic bacteria, mycotoxins, detoxification processes, residue analysis in foods. Food-drug interactions.

FE 516 Sensory Evaluation of Foods (3-0)3/Course Web Page  

Principles and methods of subjective evaluation of foods; statistical evaluation and interpretation of data; correlation and subjective and objective methods.

FE 517 Introduction to Process Principles (3-0)3

Relationship of microorganisms to food manufacture and preservation, industrial fermentation and processing. Cultivation of microorganisms, growth kinetics, continuous culture. Preservation, maintenance and isolation of microorganisms for industrial processes.

FE 519 Food Processing and Packaging (2-0)2/Course Web Page  

Immersed and solid state fermentations and fermenters. Growth kinetics development of inocula  and media for industrial fermentations. Primary and secondary metabolites. Fermentation economics.

Cell structure and function. The chemistry of major constituents; structure of proteins and their functions, protein characterization and purification techniques, enzyme reaction and kinetics, biosynthesis and degradation of amino acids, structure of nucleic acids, replication of DNA, protein synthesis (transcription and translation).

Health potential foods such as dietary fiber, limonoids, antioxidants, essential oils, peptides and proteins, lactic acid bacteria, etc. Application of functional materials, low allergen foods.

Determination of thermal inactivation parameters (for enzymes, biologically active compounds, microorganisms and bacterial spores), modes of heat tarnsfer, heat penetration measurement, heat penetration curves, methods of determining lethality of thermal processes (the graphical or general method, Ball formula method), conventioanal thermal processing, aseptic processing, surface sterilization, commercial sterilization systems, evaluation of the probability of  spoilage from a given process, examples of thermal process and heat treatment calculations.

FE 531 Biological Systems Simulation and Modeling (3-0)3

This course includes definition of biological systems, model development, simulation techniques. Methods for solving differential equations such as Runge-Kutta, Euler methods will be taught in this course and a computer language (either Fortran or C++) will be used for solving biological system models. Response Surface Methodology can also be introduced to the concept of this course.  

FE 532 Food Engineering Principles (3-0)3/Course Web Page  

Principles of fluid dynamics, heat and mass transfer in food processing operations.  Formulation of continuum problems using "shell" balances.  Velocity distributions in laminar Flow.  Shell energy balances and temperature distributions in Laminar flow and solids. Concentration distributions in solids and laminar flow.  

FE 533  Enzyme Characterization and Kinetics (3-0)3/Course Web Page

Structure of enzymes, enzyme-substrate interaction, multi substrate reactions, specificity of enzymes, control of enzyme activity in cell, enzyme nomenclature, enzyme extraction and purification, determination of enzyme activity, enzyme kinetics, methods of plotting enzyme kinetics data, molecular weight, optimum pH, heat stability, optimum temperature and substrate specificity of enzymes.

FE 534   Multivariate Statistical Analysis for Engineers (3-0) 3

The course will cover the statistical tools for the analysis of process data. Basics of matrix algebra, statistics and graphical techniques to describe data, normal distribution, test of normality, hypothesis testing will be introduced first.  The methods to compare several multivariate population means will be included.  Techniques that are used for modeling and monitoring multivariate processes will be covered; linear regression, principal component analysis, factor analysis, discrimination and clustering analysis will be given to model and classify process data, and also to monitor and diagnose the process. Students who want to take this course should be familiar to a software to perform required matrix operations.

This course will focus on the statistical process monitoring and control techniques used in science and engineering.  The content covers statistical process monitoring charts for variables and attributes. Descriptive statistics including mean, standard deviation, variance, probability distributions will be given. The concept of univariate charts such as Shewhart, cumulative sum and exponentially weighted moving average charts will be followed by autocorrelation and crosscorrelation in process data. The techniques for multivariable processes with correlated data will be introduced. The definition and guidelines of experimental design and factorial experiments will be covered.

This course is about the methods and techniques used in the design and analysis of experiments. It emphasizes the connection between the experiment and the model that the experimenter can develop from the results of the experiment. As an introduction to the course, the fundamental concepts of experimental design, such as randomization and blocking, comparison of treatments, the analysis of variance along with simple graphical techniques will be presented. Factorial and fractional factorial designs with particular emphasis on the two-level design system will be introduced. Fitting regression models, Response surface methods (RSM), which are the tools for process optimization trough designed experiments, and Taguchi methods, will also be covered.

FE 538 Bioprocess Engineering Principles (3-0)3

Contents include bioprocess develpment with an interdisciplinary point of view. Course starts with basic engineering calculations, physical processes, fluid flow, heat and mass transfer and unit operations. Reactor and reaction basics are given and reaction engineering is studied with an engineering point of view but applied to biological processes. Emphasis is given to bioreactor operations and application to biological systems. Course ends with bioprocesses using plant cell cultures and bioreactors. Students are expected to give presentations on such applications.

Contents vary according to interests of student and instructors in charge. Typical topics are Food Science, Food Technology, Food Processing, Biotechnology, etc.

Conducting research and preparing journal papers, reports and theses. Methods of research procedures for drafting, outlining and revision, design of layout. Extensive writing practice with journal papers and reports.

FE 598 Seminar Non-Credit (0-2)

A seminar must be given by each student on his research area which is graded by academic member of staff. The topic of the seminar is specified by the student and his supervisor.

M.S. students choose and study a topic under the guidance of a faculty member normally his/her advisor.