Research Article| April 01 2004 Micropipetting: An Important Laboratory Skill for Molecular Biology Jon S. Miller, Jon S. Miller Search for other works by this author on: This Site PubMed Google Scholar Michell E. Sass, Michell E. Sass Search for other works by this author on: This Site PubMed Google Scholar Susan J. Wong, Susan J. Wong Search for other works by this author on: This Site PubMed Google Scholar James Nienhuis James Nienhuis Search for other works by this author on: This Site PubMed Google Scholar The American Biology Teacher (2004) 66 (4): 291–296. https://doi.org/10.2307/4451672 Views Icon Views Article contents Figures & tables Video Audio Supplementary Data Peer Review Share Icon Share Twitter LinkedIn Tools Icon Tools Get Permissions Cite Icon Cite Search Site Citation Jon S. Miller, Michell E. Sass, Susan J. Wong, James Nienhuis; Micropipetting: An Important Laboratory Skill for Molecular Biology. The American Biology Teacher 1 April 2004; 66 (4): 291–296. doi: https://doi.org/10.2307/4451672 Download citation file: Ris (Zotero) Reference Manager EasyBib Bookends Mendeley Papers EndNote RefWorks BibTex toolbar search Search Dropdown Menu nav search search input Search input auto suggest search filter All ContentThe American Biology Teacher Search This content is only available via PDF. Copyright National Association of Biology Teachers Article PDF first page preview Close Modal You do not currently have access to this content.
The techniques of forensic anthropology and pathology can provide new information to increase student interest in studying the structural details of the human skeleton. We present a simplified methodology for assessing skeletal ethnicity, sex, age, and stature. An inexpensive method has been devised for constructing an osteometric board to allow students to measure long bones accurately. The effects of aging and the influence of lifestyle alterations on skeletal elements are presented along with the prediction of their effects on the living individual. This laboratory is intended to acquaint students with the process of collecting and analyzing data, interpreting scientific results, and assessing the accuracy of their conclusions. Gathering and analyzing their own data sets gives students a better understanding of the scientific method and an increased ability to translate this understanding to other scientific disciplines.
A previously published classroom teaching method for helping students visualize and understand Michaelis-Menten kinetics (19) was used as an anticipatory set with high school and middle school science teachers in an Illinois Math and Science Partnership Program. As part of the activity, the teachers were asked to collect data by replicating the method and to analyze and report the data. All concluded that the rate data they had collected were hyperbolic. As part of a guided inquiry plan, teachers were then prompted to reexamine the method and evaluate its efficacy as a teaching strategy for developing specific kinetic concepts. After further data collection and analysis, the teachers discovered that their data trends were not, in fact, hyperbolic, which led to several teacher-developed revisions aimed at obtaining a true hyperbolic outcome. This article outlines the inquiry process that led to these revisions and illustrates their alignment with several key concepts, such as rapid equilibrium kinetics. Instructional decisions were necessary at several key points, and these are discussed.
Modern aspects of many subjects (e.g., computer science and some aspects of medical science) are now taught in many high schools, but the plant sciences are often given short shrift. A collaboration was therefore established with a high school biology program in which pilot workshops could be developed to enable advanced students to gain insights into modern plant science techniques. A successful example is the workshop on plant biotechnology presented in this report. This workshop is simple and flexible, taking into account that most high school biology laboratories and classrooms are not set up for sophisticated plant science/biotechnology projects. It is suitable for from 10 to 30 students, depending upon space and facilities available. Students work in pairs or trios, and learn simple disinfestation and transfer techniques for micropropagation and potential subsequent transformation treatments. Students gain insights into: sterile technique and hygiene; plant hormones and their physiological effects; plant cell, tissue and organ culture; the influence of environmental factors on response of cells and tissues cultured in vitro; and an understanding of the phenomenon of organogenesis and resulting plant growth and development. This workshop has been tested on several classes of students and following analysis, several refinements were included in subsequent iterations. Results of the students' experiments have been positive and instructive, with student learning outcomes above expectations. Further details of the workshop techniques and approach will be presented.
