December 2004
Volume 42 Number 6

Active Assessment for HACCP Training: Integrating Pedagogical Reasoning with Primary Trait Analysis

Y. Martin Lo
Associate Professor and Extension Specialist, Food Processing and Safety
Department of Nutrition and Food Science
University of Maryland
College Park, Maryland
ymlo@umd.edu

Kazuko Fukushima
Research Associate, Food Safety
Department of Nutrition and Food Science
University of Maryland
College Park, Maryland
fkazuko@wam.umd.edu

Thomas E. Rippen
Senior Extension Specialist
Sea Grant Extension Program
Maryland Cooperative Extension
University of Maryland Eastern Shore
Princess Anne, Maryland
terippen@mail.umes.edu

Susan L. Gdovin
Associate Director
Center for Teaching Excellence
University of Maryland
College Park, Maryland
sg91@umail.umd.edu

Tae-Shik Hahm
Visiting Scientist
Department of Nutrition and Food Science
University of Maryland
College Park, Maryland
thahm@umd.edu

Introduction

The Hazard Analysis Critical Control Point (HACCP) programs specific to the processes involved in food production offer the food industry a comprehensive and science-based approach to enhance food safety. In addition to ensuring proper sanitation operation, assessing the likelihood of hazard occurrence, establishing critical limits, and assessing program validity, the success of HACCP lies in proper training of employees on the production floor and in quality control.

As the only higher education institution in the Mid-Atlantic area offering HACCP training to regional poultry and seafood processors, the University of Maryland has committed its resources across the state to promote effective HACCP education. However, much of the learning in the training workshops inherently has been rote, relying solely on intensive lectures and handout materials. To effectively convey important yet complicated information to the students, we believe that the training mechanism for HACCP workshops needs to be transformed so that emerging food safety issues can be adequately addressed.

Pedagogical research shows that the more students become involved with "real life" situations, the more they learn. This forms the foundation for problem-based learning (PBL), which emphasizes that the problem is encountered first by students and that learning takes place in response to the students' attempts to resolve the problem. It has been shown that, with PBL approach, complex, real problems motivate students to identify and research concepts and principles needed to solve the problems. Moreover, proactive approaches that encompass both cognitive and motivational goals must become the core emphasis of educational experiences. It is believed that such experiences will assist the students in meeting the content and process skills expected by the industry.

However, to prove the effectiveness of HACCP trainings, it is critical to establish an active mechanism to properly assess student performance. This article describes the establishment of an interactive HACCP training program based on Primary Trait Analysis (PTA) and the six aspects of a pedagogical reasoning model: comprehension, transformation, implementation, evaluation, reflection, and new comprehension.

Interactive HACCP Training Program

To reinforce critical thinking, our training focuses on breakout sessions to ensure students can control the processes, know the critical points, and properly use available tools. Equally important is how the students are guided to extend scientific principles during discussions. The HACCP problem scenarios are defined in collaboration with industrial supervisors based on three knowledge base components: subject matter knowledge, knowledge of learner, and knowledge of educational purposes and values.

Fundamental to the problem scenarios is the knowledge of the subject matter. Because most of the students have started their job and are familiar with the processes, this component comes first. Knowledge of the learner is often neglected in the design of a problem scenario. However, we've moved from information dissemination to a situation where learning is student-centered, with students exerting more control over the learning to be completed. The knowledge of educational purposes and values enables the instructor to interweave the HACCP scenario with students' job-specific interests.

Use of Primary Trait Analysis (PTA) is a key to the design of our problem scenarios. Basically, once the student identifies a process of interest, the factors or traits that would count for grade (such as "comprehension," "solution identification," and "control of variables") are selected. A five-point scale using descriptive statements on that trait is constructed. Depending on the process, most problems are designed based on one or two traits. For example, "comprehension" is a good trait for students working in Quality Assurance. For the scenario "What happens when the same bacteria contamination repeatedly occurs?" a typical five-point scale is:

1. Student merely identifies the problem (acknowledging safety concerns);

2. Student describes the problem (knowing the severity of the hazards);

3. Student explains the problem (associating with processing conditions);

4. Student analyzes the problem (understanding suitable preventative measures);

5. Student synthesizes the problem (knowing control criteria and proper reactions).

A list of traits that we use in the HACCP workshops is provided in Table 1. It is important to note that the scale is not additive or subtractive. Each level represents a different skill in pedagogical reasoning, a valuable tool for student assessment.

Tools for Active Assessment

Evaluation and grading on student performance is more challenging for a training workshop than for any classroom testing. The grade on student performance is calculated based as follows: (1) 60% on problem scenario analysis during breakout, (2) 30% on quiz containing technical questions, and (3) 10% on closing interview.

At the beginning of working on a particular problem, the students, to be successful need to comprehend both the science content and available resources as the first part of their report to the class (Level 1). In the second or third breakouts, the students have to consider the potential pitfalls and determine the most appropriate approach, i.e., transforming the information for accomplishing the task. In this process, the students are expected to integrate the content knowledge required for this task (Level 2). After the students enter the implementation process (Level 3), they evaluate and reflect on various outcomes of the situation (Level 4) and are expected to develop new comprehension of the topics (Level 5).

In addition, a 5-minute closing interview is conducted. Prior to the interview, students are given a hypothetical product a food company is about to launch, with the availability of processing capacities similar to the company that they work for. Desirable quality measures are provided along with potential challenges. During this interview, students are asked to present how they would ensure product safety and why.

Similar grading criteria based on the PTA five-point scale are used (Table 2). During the academic years of 2000 to 2002, at least 60 students completed this HACCP training program with a grade average of 80.4 ± 3.1, better than the 72.2 ± 4.5 from previous years (1998 to 1999). Through direct conversations with the participants, both students and their supervisors found this program enjoyable and successful.

This article is online at http://www.joe.org/joe/2004december/iw4.shtml.

Copyright © by Extension Journal, Inc. ISSN 1077-5315. Articles appearing in the Journal become the property of the Journal. Single copies of articles may be reproduced in electronic or print form for use in educational or training activities. Inclusion of articles in other publications, electronic sources, or systematic large-scale distribution may be done only with prior electronic or written permission of the Journal Editorial Office, joe-ed@joe.org.

If you have difficulties viewing or printing this page, please contact JOE Technical Support.