Morphometric and histopathological evaluation of modified Elnady's plastinated tissue compared to non-plastinated tissue: Highlighting its relevance for teaching and research.

The present study aims to evaluate the morphometric and histopathological properties of Modified Elnady's plastinated tissue after a period compared to non-plastinated tissue. The plastination technique is utilized in research and teaching due to the potential health risks associated with prolonged exposure to formalin. The tissues and organs are permanently dried during plastination and can be used for further anatomical, histopathological and surgical educational purposes. This method involves drying tissue and allowing synthetic materials like glycerin to permeate it. The study compared non-plastinated and plastinated tissue post-plastination to determine if structural alterations differed from those linked to plastination. The study examined the histopathological examination of dogs' skin, muscles, liver, lung, and intestine using formalin-fixed organs for paraffin embedding and previously plastinated organs for a plastinated group. The study examined non-plastinated and plastinated tissues, their histological composition and biometric parameters revealing typical structures in the non-plastinated group. Plasmodiumted tissues exhibited a compacted appearance, volume changes, nuclear clarity, and cytoplasmic hypereosinophilia, with statistical differences between the two groups. The study reveals that plastinated tissues, after 5 years of plastination, maintain their histological architecture well, with some exceptions. Plastinated tissues can be utilized in future microscopic and immunological studies and will be beneficial for teaching and research.

3D visualization and printing: An "Anatomical Engineering" trend revealing underlying morphology via innovation and reconstruction towards future of veterinary anatomy.

The amalgamation of veterinary anatomy, technology and innovation has led to development of latest technological advancement in the field of veterinary medicine, i.e., three-dimensional (3D) imaging and reconstruction. 3D visualization technique followed by 3D reconstruction has been proven to enhance non-destructive 3D visualization grossly or microscopically, e.g., skeletal muscle, smooth muscle, ligaments, cartilage, connective tissue, blood vessels, nerves, lymph nodes, and glands. The core aim of this manuscript is to document non-invasive 3D visualization methods being adopted currently in veterinary anatomy to reveal underlying morphology and to reconstruct them by 3D softwares followed by printing, its applications, current challenges, trends and future opportunities. 3D visualization methods such as MRI, CT scans and micro-CT scans are utilised in revealing volumetric data and underlying morphology at microscopic levels as well. This will pave a way to transform and re-invent the future of teaching in veterinary medicine, in clinical cases as well as in exploring wildlife anatomy. This review provides novel insights into 3D visualization and printing as it is the future of veterinary anatomy, thus making it spread to become the plethora of opportunities for whole veterinary science.

Establishing a veterinary anatomy core syllabus through a modified Delphi process.

Anatomy forms a key component of veterinary curricula, but, in the context of an evolving profession, curricula are adapting and changing accordingly. There is a lack of guidance for educators regarding the levels of anatomical knowledge required for a graduate to be considered safe or competent. A formal review of veterinary anatomy learning outcomes (LOs) is therefore timely to support curriculum development in this rapidly evolving field. This study aimed to create a set of LOs which reflect the recommended core requirements for a new graduate veterinarian. A consensus approach using a modified Delphi method was used. The Delphi panel consisted of 23 experienced and active veterinary anatomy educators from veterinary schools within the UK and Ireland. The process had four stages: (1) Research team review, pre-screening and modification of a list of existing LOs (adapted from the Core Regional Anatomy Syllabus) which then formed the initial set of outcomes sent for review; (2) Delphi Round 1; (3) Delphi Round 2; (4) Post-Delphi final screening and review. Qualitative data outlining the rationale for modification and rejection of LOs were analysed via content analysis. 167 LOs were initially presented to the Delphi panel in Round 1. 64 of those were accepted, 79 recommended for modification and 23 rejected. 122 LOs were presented to the Delphi panel in Round 2. Of these, 86 outcomes were accepted, 10 modified and 26 rejected. 160 LOs were ultimately accepted and form the Veterinary Anatomy Core Syllabus. Key themes arising from analysis include the removal of unnecessary detail and increased focus on the relevance of competencies required of a new veterinary graduate. The syllabus presented may be used by curriculum planners, teachers and students within veterinary education worldwide.

Exploring alternatives for securing anatomical structures in capturing digital images: A comparative analysis.

Teaching veterinary anatomy using digital platforms requires improved image quality, which may influence the fixation process. This study aimed to compare four embalming solutions for high-colour-quality images of different tissues compared to the original image. Four equine left pelvic limbs were cut into metameres and divided equally for application of 10% formaldehyde, 96% glycerine, 33% hypersaturated NaCl solution and modified Larssen solution, respectively, which was maintained for 3 days. After drying for 3 days at room temperature, photographs were obtained at time 0 (T0), without any fixation process (original colour); time 1 (T1), immediately after removal from the solutions; and every 24 h for 3 days (T2-T4). The image colour quality was investigated by digitally evaluating the cortical bone, tendon and bone marrow using histograms and CIEDE2000 as well as by 10 specialists in an online survey. CIEDE2000 and histograms revealed that all fixation solutions changed the original tissue colour at all the time points (p < 0.0001). According to the specialists, the 33% saline solution produced the best results compared to the original one. The modified Larssen solution demonstrated better results for the tendon, marrow and cortical bone at T3 (p = 0.0015). Considering the colour of digital images, the modified Larssen solution provided the best results; however, the visual evaluation by the specialists revealed the 33% saline solution as the best.

Supporting collaborative dissection through the development of an online wiki positively impacts the learning of veterinary anatomy.

An innovative series of dissections of the canine abdomen was created to facilitate social distancing in the dissection room following COVID-19 restrictions imposed in the UK. In groups of six, first-year veterinary students took turns dissecting selected parts of the canine abdomen while maintaining social distancing and documenting their work with video and photographs. Here, students learned about the canine abdominal anatomy by dissecting, recording the dissections of others in their group, and compiling the recorded material into a collaborative electronic media portfolio (Wiki). An online formative multiple-choice test was created to test students' knowledge of the canine abdominal anatomy. The result analysis showed that although students achieved the learning outcomes only by studying the Wiki, they had better performance in the anatomical areas where they learned through the dissection (p < 0.05). Student performance was very similar in the areas in which they were present in the dissection room and participated in recording the dissection compared with the areas that they effectively dissected (p > 0.05). A qualitative thematic analysis was developed to understand students' opinions via their feedback on this dissection approach. Our results showed that student collaboration and the development of practical skills were the most valued aspects of this dissection teaching initiative. Moreover, these results show that developing a group Wiki has a positive impact on student achievement of learning objectives, with a practical hands-on dissection being fundamental for the optimal learning of the canine abdominal anatomy.

Ancient Conceptions of the Human Uterus: Italic Votives and Animal Wombs.

The numerous votive uteri found across the central Italian peninsula from the fourth to first centuries BCE are puzzlingly evocative of the human simplex uterus, which is visually distinct from the bicornuate uteri characteristic of most other mammals. However, human dissection is not attested for this time and place, while animal butchery was common. This article uses modern veterinary anatomical imagery to argue that animal uteri - specifically as they appear when pregnant - were indeed models underlying the votive depictions. Some of the variant forms of the votives are highly evocative of various features of the pregnant bicornuate uterus. Further, medical views on the human uterus throughout classical antiquity were informed by animal uteri. Taken together, the visual and textual evidence indicate that animal models were inextricably integrated into ancient conceptions of the human uterus across the classical world, including in the production of the Italic votives in question.

Anatomía Comparada del Bazo de la Rata Blanca (Rattus norvegicus albinus), Una Revisión de la Literatura / Comparative Anatomy of the Spleen of the White Rat, (Rattus norvegicus albinus) a Literature Review

El bazo es el órgano linfático intraperitoneal más grande del organismo, presentando dos funciones principales: defensiva, mediante respuesta inmunitaria y filtración sanguínea. El objetivo de la presente revisión, fue obtener información actualizada sobre la anatomía del bazo de la rata albina (Rattus norvegicus albinus) y comparativa con la anatomía del bazo humano, perro, gato y cerdo, al representar las principales especies de importancia en la medicina, medicina veterinaria y en las ciencias biomédicas. Se realizó una búsqueda de material bibliográfico actualizado en diferentes sitios web científicos. Es así como, se revisaron 71 fuentes bibliográficas, en su gran mayoría artículos científicos (31), libros de anatomía humana y veterinaria (17), artículos especializados (17) y tesis (6). En general existe consenso, sobre la descripción anatómica del bazo, el cual se sitúa en la región hipocondriaca izquierda del abdomen, entre el fondo del estómago y el diafragma, irrigado por la arteria y vena esplénica. Se evidenció que existen similitudes en aspectos macroscópicos, al comparar el bazo de la rata blanca, con el bazo de otras especies (funcionalidad, peso relativo, ubicación topográfica). En aspectos microscópicos, el bazo en humanos y otros mamíferos se compone de estroma, además de parénquima, constituido a su vez por pulpa blanca y roja. En particular, existen diferencias entre el bazo de rata, humano, gato, perro y cerdo, en formas, tamaños y aspectos microscópicos, relacionados con la microcirculación e inmunidad. Mientras que existen semejanzas en procesos patológicos y respuestas a tratamientos farmacológicos y clínicos. Por lo anteriormente expuesto, se concluye que la rata albina constituye un buen modelo biológico, específicamente en aspectos anatómicos microscópicos del bazo de tipo inmunológico. Mientras que el bazo de cerdo es mejor comparativamente, en estudios anatómicos macroscópicos de tipo quirúrgicos, resultando ambos extrapolables, especialmente a la medicina humana.

SUMMARY: The spleen is the largest intraperitoneal lymphatic organ of the body, presenting two main functions: defensive, through immune response and blood filtration. The objective of the present review was to obtain updated information on the anatomy of the spleen of the albino rat (Rattus norvegicus albinus) and to compare it with the anatomy of the human, dog, cat and pig spleen, representing the main species of importance in medicine, veterinary medicine and biomedical sciences. A search for updated bibliographic material was carried out in different scientific websites. Thus, 71 bibliographic sources were reviewed, mostly scientific articles (31), human and veterinary anatomy books (17), specialized articles (17) and theses (6). In general, there is consensus on the anatomical description of the spleen, which is located in the left hypochondriac region of the abdomen between the fundus of the stomach and the diaphragm, irrigated by the splenic artery and vein. It was evidenced that there are similarities in macroscopic aspects when comparing the spleen of the white rat with the spleen of other species (functionality, relative weight, topographic location). In microscopic aspects, the spleen in humans and other mammals is composed of stroma, in addition to parenchyma, constituted in turn by white and red pulp. In particular, there are differences between rat, human, cat, dog and pig spleens in shapes, sizes and microscopic aspects related to microcirculation and immunity. While there are similarities in pathological processes and responses to pharmacological and clinical treatments. For the above mentioned, it is concluded that the albino rat constitutes a good biological model, specifically in microscopic anatomical aspects of the spleen of immunological type. While the pig spleen is comparatively better in macroscopic anatomical studies of surgical type, both are extrapolable especially to human medicine.

Conservation of Organs (Heart, Brain and Kidney) of Canine by Cold-Temperature Silicone Plastination in an Animal Anatomy Laboratory in Ecuador / Conservación de Órganos (Corazón, Encéfalo y Riñón) de Canino Mediante la Técnica de Plastinación en Silicona al Frío Realizada en Laboratorio de Anatomía Animal en Ecuador

SUMMARY: For the purposes of teaching anatomy, the use of cadaver preparations is considered the most efficient way of ensuring that students retain knowledge. Nevertheless, in Ecuador the use of animal specimens in universities must comply with the internationally accepted principles of replacement, reduction and refinement (3Rs). Plastination is an alternative technique which allows organs to be conserved in the long term and complies with the 3Rs. The object of the present work was to use cold-temperature silicone plastination with Biodur® products to obtain long-lasting, easy-to-handle canine organs for use as tools for the teaching of animal anatomy. Six canine cadavers were obtained from local animal protection charities. The hearts, brains and kidneys of the cadavers were dissected and fixed with formaldehyde 10 %. They were then dehydrated with acetone at -20 °C. The specimens were impregnated with Biodur® S10:S3 (-20 °C) and finally cured with Biodur® S6. We plastinated six hearts, twelve kidneys, four brains and one encephalic slice of canine. The application of cold-temperature plastination to canine organs followed the parameters established for the conventional protocol, enabling us to obtain organs of brilliant appearance, free of odours, in which the anatomical form was preserved. Thus the technique helped us to comply with the 3Rs, as we obtained easy-to-handle teaching models to replace fresh or formaldehyde-fixed samples for the teaching-learning of the canine anatomy.

En la enseñanza de la Anatomía, el uso de preparaciones cadavéricas se considera el método que permite a los estudiantes retener el conocimiento de una forma más eficiente. No obstante, en Ecuador, el uso de especímenes animales en las universidades se debe realizar bajo el principio internacional de reemplazo, reducción y refinamiento (3Rs). La técnica de plastinación es una técnica alternativa que permite preservar órganos a largo plazo y que se adapta al principio de las 3Rs. El objetivo del trabajo fue utilizar la técnica de plastinación en silicona al frío con productos Biodur® para obtener órganos caninos duraderos y manejables útiles como herramienta para la enseñanza de la anatomía animal. Se obtuvieron seis cadáveres de caninos de fundaciones locales para la protección animal. Se realizaron disecciones de corazones, cerebros y riñones de los cadáveres caninos. Los órganos se fijaron con formalina al 10 %. A continuación, se llevó a cabo la deshidratación con acetona a -20 °C. Los especímenes fueron impregnados con S10:S3 Biodur® (-20 °C) y al final fueron curados con Biodur® S6. Se lograron plastinar seis corazones, doce riñones, cinco encéfalos y un tallo encefálico de canino. La técnica de plastinación al frío utilizada para obtener órganos de canino conservó los parámetros empleados en el protocolo convencional y permitió obtener órganos que presentaron aspecto brillante, ausencia de olores y mantuvieron la forma anatómica. Por lo que, la técnica facilitó cumplir con el principio de las 3Rs al obtenerse modelos didácticos fáciles de manipular que pueden reemplazar muestras frescas o formolizadas en el proceso de enseñanza-aprendizaje de la anatomía del canino.

A Glimpse into Chilean Veterinary Anatomy Educators / Un Vistazo a los Educadores de Anatomía Veterinaria Chilenos

SUMMARY: In veterinary medicine, impressive technological advances in biochemistry, genetics and molecular biology have led to a reduction in the amount of time spent teaching anatomy and a shift toward anatomical research. As classically trained veterinary anatomists began to retire at the beginning of the 2000s, it became evident that there would be a shortage of qualified anatomists. This coincides with the increase in the hiring of recent graduates with general education experience and no specialization in the area. The aim of the study is to characterize the Chilean veterinary anatomy educator with an emphasis on their training and the academic environment they work in. Data were collected through a survey targeting a diverse population of university educators who teach content related to veterinary anatomy in Chile. The results showed that the Chilean veterinary anatomist has reached the master's level, with a wide range of continuous training experiences, from which it is perceived that he has acquired his anatomical and teaching skills. Furthermore, despite his self-perception as an educator/researcher, the evidence showed that research in veterinary anatomy is still in its infancy. However, strengths were identified related to the varied use of teaching resources, participation in the community and the dissemination of anatomical knowledge.

En medicina veterinaria, los impresionantes avances tecnológicos en bioquímica, genética y biología molecular han llevado a una reducción en la cantidad de tiempo dedicado a la enseñanza de la anatomía y un cambio hacia la investigación anatómica. Cuando los anatomistas veterinarios de formación clásica comenzaron a jubilarse a principios de la década de 2000, se hizo evidente que habría escasez de anatomistas cualificados. Esto coincide con el incremento en la contratación de recién egresados con experiencia en educación general y sin especialización en el área (licenciados, tesistas, etc.). El objetivo del estudio es caracterizar al educador de anatomía veterinaria chileno con énfasis en su formación y el ambiente académico en el que se desempeña. Los datos fueron recolectados a través de una encuesta dirigida a una población diversa de docentes universitarios que imparten contenidos relacionados con la anatomía veterinaria en Chile. Los resultados muestran que el anatomista veterinario chileno ha alcanzado el nivel de maestría, con una amplia gama de experiencias de formación continua, a partir de las cuales se infiere que ha adquirido sus competencias anatómicas y docentes. A pesar de su autopercepción como educador/investigador, la evidencia demostró que la investigación en anatomía veterinaria aún se encuentra en ciernes. No obstante, se identificaron fortalezas en actividades relacionadas con el uso variado de recursos didácticos, la participación en la comunidad y la difusión del conociminto.

ChatGPT for Veterinary Anatomy Education: An Overview of the Prospects and Drawbacks / ChatGPT para la Educación en Anatomía Veterinaria: Una Descripción General de las Perspectivas y los Inconvenientes

SUMMARY: The integration of artificial intelligence in veterinary medical education has the potential to revolutionize the way students learn veterinary anatomy. ChatGPT, launched by OpenAI in November 2022, has been the fastest-growing artificial intelligence (AI) application as a learning tool in the past few months. ChatGPT is a virtual assistant that provides students with detailed and relevant anatomical knowledge based on internet sources. Apart from the advantages of ChatGPT in veterinary anatomy education, the challenges and limitations must also be considered, as highlighted in this letter. Further research and evaluation are necessary to ensure the optimal integration of the ChatGPT tool into veterinary anatomy education. ChatGPT can provide students with valuable insights and educational support but cannot replace hands-on experiences; dissection-based laboratory sessions remain essential for developing practical skills and spatial understanding in veterinary anatomy education.

La integración de la inteligencia artificial en la educación médica veterinaria tiene el potencial de revolucionar la forma en que los estudiantes aprenden anatomía veterinaria. ChatGPT, lanzado por OpenAI en noviembre de 2022, ha sido la aplicación de inteligencia artificial (IA) de más rápido crecimiento como herramienta de aprendizaje en los últimos meses. ChatGPT es un asistente virtual que brinda a los estudiantes conocimientos anatómicos detallados y relevantes basados en fuentes de Internet. Además de las ventajas de ChatGPT en la educación en anatomía veterinaria, también se deben considerar los desafíos y las limitaciones, como se destaca en esta carta. Se necesitan más investigaciones y evaluaciones para garantizar la integración óptima de la herramienta ChatGPT en la educación en anatomía veterinaria. ChatGPT puede proporcionar a los estudiantes información valiosa y apoyo educativo, pero no puede reemplazar las experiencias prácticas. Las sesiones de laboratorio basadas en disecciones siguen siendo esenciales para desarrollar habilidades prácticas y comprensión espacial en la educación de la anatomía veterinaria.

Online veterinary anatomy education during Covid-19 pandemic in Iran: Challenges and opportunities.

BACKGROUND: The covid-19 pandemic changed veterinary anatomy in-person training to inexperienced virtual training rapidly. OBJECTIVES: This survey was designed to assess the perceptions of first- and second-year Iranian veterinary students on learning outcomes during the online transition. METHODS: The opinions of 684 students were examined using questionnaire. RESULTS: The data showed that 23.8% of students were interested in learning anatomy online and 24.8% were satisfied with it. Only 13.5% of the students in the survey generally agree with replacing remote teaching with ordinary training. Less than 1% of students considered online education suitable for the practical part of anatomy. Most of the students' sources for theoretical part included professor's booklets, narrated PowerPoint lectures, in-class notes, and anatomy books. Professors' dissection videos, YouTube videos and also anatomy atlases were the most used sources for practical part. Many students (69.3%) were comfortable using technology. Few numbers of the students (36.1%) were satisfied with the result of the online anatomy exam. Students commented missing dissection, lack of interaction and technology challenges as main negative-points of E-learning. While time management and reviewing the recorded lessons was described as one of the most important benefits. CONCLUSIONS: Online education cannot replace face-to-face education in anatomy and it can be used along ordinary training as an additional educational tool. However, group online learning activities, using dissection videos and 3-D software are suggested for online learning. The data of this study, collected for the first time in Iran, can be used for future decisions in veterinary anatomy.

Dissection videos as a virtual veterinary anatomy peer learning tool: Trialled at the University of Tehran during the Covid-19 pandemic.

The Covid-19 pandemic forced universities around the world to use online education instead of face-to-face teaching. Veterinary anatomy training was also affected, and laboratory classes were disrupted by this transition. To reduce the effects of virtual education on students' anatomy learning, peer learning using dissection videos was introduced at University of Tehran. This study describes the design and implementation of this method and evaluates the students' perceptions regarding this programme. The opinions of 98 students were examined using a questionnaire. The data showed that dissection videos were one of the main sources of anatomy study (67.3%). Among students who used videos, 69.6% students became more interested in anatomy and 73% learned anatomy better with this approach. Students used these videos to review anatomy (88.7%) and even learn new content (87.6%). Most surveyed students used laptops (73%) and cell phones (14.6%) to watch videos. In this study, 19.1% of respondents were estimated to be low users, 68.5% medium users and 12.4% high users. A large number of students (83.1%) trusted their peer teacher in providing the lesson. Dissection videos play an important role in conveying a three-dimensional understanding of anatomical structures, and peer teaching is also effective in learning because of the strong connection between tutors and tutees. This study supports students' acceptance of the use of peer dissection videos for learning online veterinary anatomy.

Using videos in active learning: An experience in veterinary anatomy.

Examination failure rate is high in veterinary anatomy in Brazilian universities. We report here our active learning experience in which students recorded video reports on veterinary anatomical specimens of locomotor apparatus to support classic learning. Eighteen students were divided into 2 groups, case group (V3) and control (E). Case group students individually recorded video reports of prosected specimens weekly. Acceptance and efficacy of the strategy were assessed with a Likert scale anonymous questionnaire and students' scores in theoretical exams. The method was highly accepted and the performance test proved that recording videos is an effective strategy for active learning in anatomy.

Evaluation of a 3D Computer Model of the Equine Paranasal Sinuses as a Tool for Veterinary Anatomy Education.

Detailed knowledge of anatomical systems is vital for clinical veterinary practice. However, students often find it difficult to transfer skills learned from textbooks to real-life practice. In this study, a three-dimensional computer model representing equine paranasal sinus anatomy (3D-ESM) was created and evaluated for its contribution to student understanding of the 3D dynamic nature of the system. Veterinary students and equine professionals at the University of Bristol were randomly allocated into experimental (3D model) and control (2D lecture) groups. A pre-/post-study design was used to evaluate the efficacy of the 3D model through a pre-/post-multiple-choice question (MCQ) anatomical knowledge exam and a pre-/post-questionnaire gathering information on participant demographics, confidence, and satisfaction. No statistically significant difference was found between 3D and 2D groups' post-MCQ exam scores (t39 = 1.289, p = .205). 3D group participant feedback was more positive than 2D group feedback, and 3D group satisfaction scores on Likert questions were significantly higher (t118 = -5.196, p < .001). Additionally, confidence scores were significantly higher in the 3D group than in the 2D group immediately following the study (p < .05). Participants' open-text responses indicated they found the 3D model helpful in learning the complex anatomy of the equine paranasal sinuses. Findings suggest the 3D-ESM is an effective educational tool that aids in confidence, enjoyment, and knowledge acquisition. Though it was not better than traditional methods in terms of anatomy knowledge exam scores, the model is a valuable inclusion into the veterinary anatomy curriculum.

Learning veterinary anatomy playing cards.

Gamification is a dynamic tool for educational transformation useful to encourage student interest and enhance learning. Here we present a study conducted to investigate the effectiveness of an educational card game developed by us in veterinary anatomy practicals to reinforce knowledge acquisition in veterinary students. A total of four sets of cards were designed, each one with different anatomical topics (structure identification, articulation and positioning, clinical anatomy, and comparative anatomy); students were arranged in small groups (7-10 students per group) and played the game at the end of each anatomy practical session, discussing the corresponding questions, randomly chosen, as a team. This activity was highly valued by students, most of whom (>80%) expressed that the game was enjoyable, challenging, helpful to improve their knowledge and understanding in clinical anatomy, and effective for anatomy exam preparation. Thus, the use of educational games in practical sessions seems to improve student engagement in the learning process individually and as a team.NEW & NOTEWORTHY The development and implementation of a card game as a training resource that allows learning veterinary anatomy in a motivating and cooperative environment, promoting teamwork, relationships, and trust and communication between colleagues, is described. Stimulating the ability to solve problems as a team has provided help to students preparing for their exams in a more dynamic and enjoyable way.

Pelvimetric characteristics in agoutis (Dasyprocta prymnolopha) bred under human care / Características pelvimétricas em cutias (Dasyprocta prymnolopha) criadas sob cuidados humanos

The aim of the study was to establish the pattern of the agouti pelvis by obtaining external and radiographic internal pelvimetric values. Forty-three agouti (Dasyprocta prymnolopha), females and males bred in under human care were used. The parameters measured were the external biiliac diameter; the external biischiatic diameter; right and left external ilioischiatic diameters and radiographic internal measurements (true conjugated, the diagonal conjugated; the vertical, the sacral, sagittal, coxal tuberosity, upper biiliac, lower biiliac, and biischiatic diameter. The inlet pelvic area and the outlet pelvic area were calculated, as well the height/width ratios of the entrance area of the pelvis and the pelvic outlet area were calculated. The mean values for each body measurement of females and males were: weight 1.91kg and 2.04kg, external biiliac diameter 6.32cm and 6.30cm, external biischiatic diameter 4.34cm and 4.28cm, right external ilioischiatic diameter 9.01cm and 9.33cm, left external ilioischiatic diameter 9.13cm and 9.30cm, true conjugated 3.90cm and 3.68cm, diagonal conjugated 7.13cm and 6.91cm, vertical diameter 2.59cm and 2.45cm, sacral diameter 2.63cm and 2.44cm, sagittal diameter 3.30cm and 3.09cm, coxal tuberosity diameter 2.52cm and 2.43cm, upper biiliac diameter 6.28cm and 6.24cm, lower biiliac diameter 2.98cm and 2.58cm, biischiatic diameter 2.60cm and 2.70cm, height/width ratio - vertical/ lower biiliac diameter 0.88cm and 0.95cm, sagital/coxal tuberosity diameter 1.32cm and 1.28cm, inlet pelvic area 82.38cm and 77.83cm and outlet pelvic area 24.76cm and 20.07cm. Agouti are dolichopelvic animals, demonstrating the existence of a discrete sexual dimorphism in adults and low intensity correlations between the external and internal measures studied.

O objetivo deste estudo foi estabelecer o padrão da pelve de cutia, masculina e feminina, por meio da obtenção dos valores médios da pelvimetria externa e interna radiográfica. Foram utilizadas 43 cutias (Dasyprocta prymnolopha), fêmeas e machos criadas sob cuidados humanos. Os parâmetros medidos foram o diâmetro biilíaco externo; o diâmetro biisquiático externo; diâmetros ilioisquiáticos externos direito e esquerdo e medidas internas radiográficas (diâmetros conjugado verdadeiro, diagonal conjugado, vertical, sacral, sagital, tuberosidade coxal, biilíaco superior, biilíaco inferior e diâmetro biisquiático). A área pélvica de entrada e a área pélvica de saída foram calculadas , assim como foram calculadas as razões altura/largura da área de entrada da pelve e da área de saída da pelve. Os valores médios para as medidas das fêmeas e dos machos foram, respectivamente: peso 1,91kg e 2,04kg, diâmetro biilíaco externo 6,32cm e 6,30 cm, diâmetro ilioisquiático externo 4,34cm e 4,28cm, diâmetro ilioisquiático externo direito 9,01cm e 9,33cm, diâmetro ilioisquiático externo esquerdo 9,13cm e 9,30cm, diâmetro conjugado verdadeiro 3,90cm e 3,68cm, diâmetro conjugado diagonal 7,13cm e 6,91cm, diâmetro vertical 2,59cm e 2,45cm, diâmetro sacral 2,63cm e 2,44cm, diâmetro sagital 3,30cm e 3,09cm, tuberosidade coxal diâmetro 2,52cm e 2,43cm, diâmetro biilíaco superior 6,28cm e 6,24cm, diâmetro biilíaco inferior 2,98cm e 2,58cm, diâmetro biisquiático 2,60cm e 2,70cm, relação altura/largura - vertical/diâmetro biilíaco inferior 0,88cm e 0,95cm, diâmetro sagital/coxal tuberosidade 1,32cm e 1,28cm, área pélvica de entrada 82,38cm e 77,83 cm e área pélvica de saída 24,76cm e 20,07cm. As cutias são animais dolicopélvicos, demonstrando a existência de um discreto dimorfismo sexual em adultos e correlações de baixa intensidade entre as medidas externas e internas estudadas.

Veterinary anatomy during the COVID-19 pandemic in brazil: research focused on pedagogical practice / Anatomía veterinaria durante la pandemia COVID-19 en brasil: investigación centrada en la práctica pedagógica

SUMMARY: Since the first Brazilian Veterinary Medicine course in 1910, many curricular changes have taken place. The pedagogical project have been centered on the student as a subject of learning and supported by the professors as a critical mediator of this process and the pandemic of COVID-19 accelerated this change. Many professors have taught video lessons to ensure continuity of teaching, research and extension, even at a distance. This paper, therefore, aims at reporting the development of animal anatomy didactic contents applied on online platforms in Portuguese language. To this, eight researches were developed addressing the teaching-learning of Morphological Sciences contents to be incorporated into distance education platforms that focused canine and feline anatomy, the study of neuroanatomy in the ovine, bovine, equine and primate species and the surgical anatomy of the locomotor apparatus of the equine specie. Thus, virtual teaching-learning platform can help, as a complementary tool to face-to-face classes, in obtaining the skills, abilities and attitudes required for the training of veterinary students in Brazil.

RESUMEN: Se han efectuado importantes cambios curriculares desde el primer curso de Medicina Veterinaria de Brasil en 1910. El proyecto pedagógico se ha centrado en el alumno como sujeto de aprendizaje con apoyo de los docentes como mediadores críticos de este proceso; con la pandemia de COVID-19 se aceleró este cambio. Muchos profesores han impartido lecciones en video para garantizar la continuidad de la docencia, la investigación y la extensión, incluso a distancia. Este artículo tiene como objetivo informar sobre el desarrollo de los contenidos didácticos sobre la anatomía animal, aplicados en plataformas online en portugués. Para ello, se desarrollaron ocho investigaciones que abordan la enseñanza-aprendizaje de contenidos de Ciencias Morfológicas para ser incorporados en plataformas de educación a distancia que enfocaran la anatomía canina y felina, el estudio de la neuroanatomía en las especies ovina, bovina, equina y primate, y la anatomía quirúrgica del aparato locomotor de la especie equina. De esta forma, la plataforma virtual de enseñanza-aprendizaje puede complementar las clases presenciales en la obtención de las habilidades y actitudes requeridas para la formación de los estudiantes de veterinaria en Brasil.

Veterinary anatomy teaching from real to virtual reality: An unprecedented shift during COVID-19 in socially distant era.

Teaching Veterinary Anatomy in a virtual world is an utmost requirement of the ongoing era of COVID-19 pandemic. Due to sudden lockdown, all the educational institutes, professional medical and veterinary colleges were closed (except emergency services) and academic activities were suspended altogether. This situation was challenging as well as thought-provoking for various academicians and professors to rethink about the means to keep the conduit of imparting education unceasing. This review focuses on the virtual reality aids that are being adopted worldwide and the initiatives taken by academicians during this era to impart best practical anatomy lessons yet being in a socially distant world. However, during the lockdown and social distancing, face-to face interactions were not feasible, and therefore, number of distant learning methods were created on virtual platforms for continuing the process of teaching veterinary anatomy closer to reality available at their doorsteps where academic staff was actively involved to reconstruct and renovate resources, upgraded their digital competencies to develop new ways to shift from one on one and merged to remote online teaching, and anatomy teaching was transformed to an abrupt 'virtual mode'. Adopting virtual reality (VR) aids such as 3D animations, software packages, virtual dissections and E-museum serves as a great saviour throughout this unprecedented pandemic in a socially distant world to continue the teaching connexion.

Breaking barriers: The landscape of human and veterinary medical anatomy education and the potential for collaboration.

Despite human (HUM) and veterinary (VET) medical institutions sharing the goal of educating future clinicians, there is little collaboration between them regarding curricular and pedagogical practices during the preclinical/basic science training years. This may be, at least in part, due to a lack of understanding of each type of curriculum. This study presents data about curricula, student populations, pedagogical methodologies applied, and anatomy educators' training at both HUM and VET institutions. Preclinical curricula, admissions criteria, and student demographics were analyzed for 21 institutions in the United States having both HUM and VET schools. This dataset was augmented by a questionnaire sent to anatomists internationally, detailing anatomy curricula, pedagogies applied, and anatomy educators' training. Many curricular similarities between both training programs were identified, including anatomy education experiences. However, VET programs were found to include more preclinical coursework than HUM programs. Students who matriculate to VET or HUM schools have similar academic records, including prerequisite coursework and grade point average. Median HUM class size was significantly larger, and the percentage of women enrolled in VET institutions was significantly higher. Training of anatomy educators was identical with one exception: VET educators are far more likely to hold a clinical degree. This study elucidates the substantial similarities between VET and HUM programs, particularly in anatomy education, underscoring the potential for collaboration between both types of programs in areas such as interprofessional education, bioethics, zoonotic disease management, and postgraduate training.

Three-Dimensional Printed Models of the Heart Represent an Opportunity for Inclusive Learning.

Three-dimensional (3D) printed models of anatomic structures offer an alternative to studying manufactured, "idealized" models or cadaveric specimens. The utility of 3D printed models of the heart for clinical veterinary students learning echocardiographic anatomy is unreported. This study aimed to assess the feasibility and utility of 3D printed models of the canine heart as a supplementary teaching aid in final-year vet students. We hypothesized that using 3D printed cardiac models would improve test scores and feedback when compared with a control group. Students (n = 31) were randomized to use either a video guide to echocardiographic anatomy alongside 3D printed models (3DMs) or video only (VO). Prior to a self-directed learning session, students answered eight extended matching questions as a baseline knowledge assessment. They then undertook the learning session and provided feedback (Likert scores and free text). Students repeated the test within 1 to 3 days. Changes in test scores and feedback were compared between 3DM and VO groups, and between track and non-track rotation students. The 3DM group had increased test scores in the non-track subgroup. Track students' test scores in the VO group increased, but not in the 3DM group. Students in the 3DM group had a higher completion rate, and more left free-text feedback. Feedback from 3DM was almost universally positive, and students believed more strongly that these should be used for future veterinary anatomy teaching. In conclusion, these pilot data suggest that 3D printed canine cardiac models are feasible to produce and represent an inclusive learning opportunity, promoting student engagement.