An Expert Derived Feedforward Histology Module Improves Pattern Recognition Efficiency in Novice Students

Histology is a visually oriented, foundational anatomical sciences subject in professional health curricula that has seen a dramatic reduction in educational contact hours and an increase in content migration to a digital platform. While the digital migration of histology laboratories has transformed histology education, few studies have shown the impact of this change on visual literacy development, a critical competency in histology. The objective of this study was to assess whether providing a video clip of an expert’s gaze while completing leukocyte identification tasks would increase the efficiency and performance of novices completing similar identification tasks. In a randomized study, one group of novices (n = 9) was provided with training materials that included expert eye gaze, while the other group (n = 12) was provided training materials with identical content, but without the expert eye gaze. Eye movement parameters including fixation rate and total scan path distance, and performance measures including time-to-task-completion and accuracy, were collected during an identification task assessment. Compared to the control group, the average fixation duration was 13.2% higher (P < 0.02) and scan path distance was 35.0% shorter in the experimental group (P = 0.14). Analysis of task performance measures revealed no significant difference between the groups. These preliminary results suggest a more efficient search performed by the experimental group, indicating the potential efficacy of training using an expert’s gaze to enhance visual literacy development. With further investigation, such feedforward enhanced training methods could be utilized for histology and other visually oriented subjects.     

Mexican Educators Survey on Anatomical Sciences Education and a Review of World Tendencies

Anatomical sciences curricula have been under constant reform over the years, with many countries having to reduce course hours while trying to preserve laboratory time. In Mexico, schools have historically been autonomous and unregulated, and data regarding structure and methods are still lacking. A national survey was sent by the Mexican Society of Anatomy to 110 anatomical sciences educators. The questionnaire consisted of 50 items (open and multiple choice) for gross anatomy, microscopic anatomy, neuroanatomy, and embryology courses in medical schools across Mexico. A clinical approach was the most common course approach in all disciplines. Contact course hours and laboratory hours were higher in Mexican anatomy education compared to other countries, with the highest reported contact hours for embryology (133.4 ± 44.1) and histology (125 ± 33.2). There were similar contact hours to other countries for gross anatomy (228.5 ± 60.5). Neuroanatomy course hours (43.9 ± 13.1) were less than reported by the United States and similar to Saudi Arabia and higher than the United Kingdom. Dissection and microscopy with histological slides predominate as the most common laboratory activities. Traditional methods prevail in most of the courses in Mexico and only a few educators have implemented innovative and technological tools. Implementation of new methods, approaches, and curricular changes are needed to enhance anatomical sciences education in Mexico.     

Histology and Embryology Education in China: The Current Situation and Changes Over the Past 20 Years

In mainland China, histology and embryology (HE) are taught in one course as an essential component of medical curricula. The effectiveness of HE courses directly affects the quality of medical students. To determine the present situation and changes in HE teaching in Chinese medical schools, a nationwide survey was conducted among the HE departmental leaders. In total, 66 responses were included in the study, representing prominent Chinese mainland medical schools. The results revealed that most HE teachers have medical educational backgrounds; an increasing number of teaching staff with PhDs have joined the teaching staffs. A range of 71 to 90 HE curriculum contact hours is predominant. The ratio of theory to practice for HE contact hours is 1:1 at half of the surveyed medical schools. The numbers of students in each laboratory are less than 30 and from 31 to 60 at 23 and 36 medical schools, respectively. Virtual microscopy is employed in 40% of the surveyed medical schools. Didactic teaching is the most common strategy, although new teaching approaches are being employed gradually. During the past 20 years, both the total number of HE teachers and the number of HE teachers with medical educational backgrounds have been reduced in at least half of the surveyed schools. A total of 83.33% of the surveyed schools have reduced their HE contact hours. Almost half of the Chinese medical schools remained unchanged in both their ratio of theory to practice and the number of students in each laboratory. The data derived from this study help to understand the development of the HE discipline at Chinese medical schools.     

How to Make Educational Lemonade Out of a Didactic Lemon: The Benefits of Listening to Your Students

When educators develop and introduce new learning approaches or resources, they usually have specific didactic goals in mind that they want to achieve. However, these goals may not always match the needs of their students, who often confound such plans by finding new and different uses for the educational tools that are offered to them. Originating from the author’s work as the histology component director at the University of Michigan, the experience described here provides an example of a learning resource being reappropriated by the learning community. In order to encourage dental students to study histological micrographs after faculty-guided laboratory sessions were eliminated, the author prepared and offered them a series of PowerPoint files with histology images and some corresponding questions. However, instead of increasing their motivation to use the online virtual microscopy resources, students adapted this new tool for reviewing the material and for self-evaluation whether they were prepared for upcoming examinations. Although the product did not succeed as originally devised, it turned into a very popular review resource for the author’s students. Students’ feedback and critical input, as well as their active participation in producing additional, similar learning tools were the deciding factors for this successful change of purpose and the further development and refinement of this new learning resource.     

Are we throwing histology out with the microscope? A look at histology from the physician's perspective

A trend in medical schools across the United States is the refurbishing of histology laboratories with digital microscopy systems. Although such systems may reduce curricular time, they do not teach basic microscope skills, and students who learn solely with these systems may be less prepared for their practices or specialties, particularly in rural areas that may not be equipped with digital microscope technology. At the West Virginia School of Osteopathic Medicine (WVSOM), students are trained to practice in a wide variety of environments, especially rural areas. A research survey was conducted to gather information for evidence‐based decisions about histology education at WVSOM. The survey asked a range of questions concerning histology knowledge, tissue preparation, and microscopy. Responses did not differ significantly between physicians in urban versus rural practices. Ninety percent of physicians do not utilize digitized images, and only 50% have microscopes readily available. Regardless of the technology available, 90% feel that students must have microscope training and 88% of physicians feel that histology is important to the medical curriculum and use their histology knowledge often (weekly or daily) (66%). These results demonstrate that histology education should move toward a blending of traditional microscope and glass slides with computer‐based instructional technologies. Anat Sci Educ 2:205–209, 2009. © 2009 American Association of Anatomists.     

Medical education in the anatomical sciences: The winds of change continue to blow

At most institutions, education in the anatomical sciences has undergone several changes over the last decade. To identify the changes that have occurred in gross anatomy, microscopic anatomy, neuroscience/neuroanatomy, and embryology courses, directors of these courses were asked to respond to a survey with questions pertaining to total course hours, hours of lecture, and hours of laboratory, whether the course was part of an integrated program or existed as a stand‐alone course, and what type of laboratory experience occurred in the course. These data were compared to data obtained from a similar survey in 2002. Comparison between the data sets suggests several key points some of which include: decreased total hours in gross anatomy and neuroscience/neuroanatomy courses, increased use of virtual microscopy in microscopic anatomy courses, and decreased laboratory hours in embryology courses. Anat Sci Educ 2: 253–259, 2009. © 2009 American Association of Anatomists.     

Using color and grayscale images to teach histology to color‐deficient medical students

Examination of histologic and histopathologic microscopic sections relies upon differential colors provided by staining techniques, such as hematoxylin and eosin, to delineate normal tissue components and to identify pathologic alterations in these components. Given the prevalence of color deficiency (commonly called “color blindness”) in the general population, it is likely that this reliance upon color differentiation poses a significant obstacle for several medical students beginning a course of study that includes examination of histologic slides. In the past, first‐year medical students at Michigan State University who identified themselves as color deficient were encouraged to use color transparency overlays or tinted contact lenses to filter out problematic colors. Recently, however, we have offered such students a computer monitor adjusted to grayscale for in‐lab work, as well as grayscale copies of color photomicrographs for examination purposes. Grayscale images emphasize the texture of tissues and the contrasts between tissues as the students learn histologic architecture. Using this approach, color‐deficient students have quickly learned to compensate for their deficiency by focusing on cell and tissue structure rather than on color variation. Based upon our experience with color‐deficient students, we believe that grayscale photomicrographs may also prove instructional for students with normal (trichromatic) color vision, by encouraging them to consider structural characteristics of cells and tissues that may otherwise be overshadowed by stain colors. Anat Sci Ed 2:84–88, 2009. © 2009 American Association of Anatomists.     

Use of interactive live digital imaging to enhance histology learning in introductory level anatomy and physiology classes

Histology is one of the main subjects in introductory college-level Human Anatomy and Physiology classes. Institutions are moving toward the replacement of traditional microscope-based histology learning with virtual microscopy learning amid concerns of losing the valuable learning experience of traditional microscopy. This study used live digital imaging (LDI) of microscopic slides on a SMART board to enhance Histology laboratory teaching. The interactive LDI system consists of a digital camera-equipped microscope that projects live images on a wall-mounted SMART board via a computer. This set-up allows real-time illustration of microscopic slides with highlighted key structural components, as well as the ability to provide the students with relevant study and review material. The impact of interactive LDI on student learning of Histology was then measured based on performance in subsequent laboratory tests before and after its implementation. Student grades increased from a mean of 76% (70.3-82.0, 95% CI) before to 92% (88.8-95.3, 95% CI) after integration of LDI indicating highly significant (P < 0.001) enhancement in students' Histology laboratory performance. In addition, student ratings of the impact of the interactive LDI on their Histology learning were strongly positive, suggesting that a majority of students who valued this learning approach also improved learning and understanding of the material as a result. The interactive LDI technique is an innovative, highly efficient and affordable tool to enhance student Histology learning, which is likely to expand knowledge and student perception of the subject and in turn enrich future science careers.     

An update on the status of anatomical sciences education in United States medical schools

Curricular changes continue at United States medical schools and directors of gross anatomy, microscopic anatomy, neuroscience/neuroanatomy, and embryology courses continue to adjust and modify their offerings. Developing and supplying data related to current trends in anatomical sciences education is important if informed decisions are going to be made in a time of curricular and course revision. Thus, a survey was sent to course directors during the 2012–2013 academic years to gather information on total course hours, lecture and laboratory hours, the type of laboratory experiences, testing and competency evaluation, and the type of curricular approach used at their institution. The data gathered were compared to information obtained from previous surveys and conclusions reached were that only small or no change was observed in total course, lecture and laboratory hours in all four courses; more gross anatomy courses were part of an integrated curriculum since the previous survey; virtual microscopy with and without microscopes was the primary laboratory activity in microscopic anatomy courses; and neuroscience/neuroanatomy and embryology courses were unchanged. Anat Sci Educ 7: 321–325. © 2014 American Association of Anatomists.