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Hormone Research in Paediatrics 2022Testes were associated with maleness from antiquity, and ancient societies had fanciful myths about the origins of the sexes and about fetal sexual development. 17th... (Review)
Review
Testes were associated with maleness from antiquity, and ancient societies had fanciful myths about the origins of the sexes and about fetal sexual development. 17th century anatomists developed the concept that mammals developed from eggs and discovered sperm in semen; in 1878, Hertwig observed sperm entering eggs (of sea urchins), establishing the cellular basis of sex development. Individuals with atypical genitalia were known clinically in the 17th century, with much debate about their origins, but by the late 19th century it was generally accepted that gonads determined sex, and that sex determined gender role. Testosterone was isolated in 1935, and Alfred Jost showed that both circulating testosterone and diffusible anti-Mullerian hormone were needed for male development. Patients with apparent androgen insensitivity were reported in 1937 and shown to be unresponsive to exogenous androgen by Lawson Wilkins in 1957; androgen receptor mutations were reported in 1989. Steroidogenic errors were associated with differences in sex development (DSDs) starting in the 1940s, and finding mutations in the responsible enzymes explained many forms of hyper- and hypo-androgenism in both sexes. Sex chromosomes were identified in the early 20th century; Y was associated with maleness, and the responsible SRY gene was identified in 1991. Early efforts to manage patients with DSDs were confounded by philosophical perspectives on the relative roles of prenatal biology versus postnatal environment. Approaches to natal sex assignment evolved in the later 20th century and now emphasize a team approach based on data, not guessing, parental involvement, cultural considerations, and the acknowledgement of uncertainty.
Topics: Female; Child; Animals; Pregnancy; Male; Humans; Androgens; Semen; Sexual Development; Disorders of Sex Development; Testosterone; Mammals
PubMed: 36446331
DOI: 10.1159/000527042 -
Frontiers in Cell and Developmental... 2020Meckel's cartilage was first described by the German anatomist Johann Friedrich Meckel the Younger in 1820 from his analysis of human embryos. Two hundred years after... (Review)
Review
Meckel's cartilage was first described by the German anatomist Johann Friedrich Meckel the Younger in 1820 from his analysis of human embryos. Two hundred years after its discovery this paper follows the development and largely transient nature of the mammalian Meckel's cartilage, and its role in jaw development. Meckel's cartilage acts as a jaw support during early development, and a template for the later forming jaw bones. In mammals, its anterior domain links the two arms of the dentary together at the symphysis while the posterior domain ossifies to form two of the three ear ossicles of the middle ear. In between, Meckel's cartilage transforms to a ligament or disappears, subsumed by the growing dentary bone. Several human syndromes have been linked, directly or indirectly, to abnormal Meckel's cartilage formation. Herein, the evolution, development and fate of the cartilage and its impact on jaw development is mapped. The review focuses on developmental and cellular processes that shed light on the mechanisms behind the different fates of this cartilage, examining the control of Meckel's cartilage patterning, initiation and maturation. Importantly, human disorders and mouse models with disrupted Meckel's cartilage development are highlighted, in order to understand how changes in this cartilage impact on later development of the dentary and the craniofacial complex as a whole. Finally, the relative roles of tissue interactions, apoptosis, autophagy, macrophages and clast cells in the removal process are discussed. Meckel's cartilage is a unique and enigmatic structure, the development and function of which is starting to be understood but many interesting questions still remain.
PubMed: 32984323
DOI: 10.3389/fcell.2020.00821 -
Journal of Anatomy Mar 2022As a result of many factors, including climate change, unrestricted population growth, widespread deforestation and intensive agriculture, a new pattern of diseases in... (Review)
Review
As a result of many factors, including climate change, unrestricted population growth, widespread deforestation and intensive agriculture, a new pattern of diseases in humans is emerging. With increasing encroachment by human societies into wild domains, the interfaces between human and animal ecosystems are gradually eroding. Such changes have led to zoonoses, vector-borne diseases, infectious diseases and, most importantly, the emergence of antimicrobial-resistant microbial strains as challenges for human health. Now would seem to be an opportune time to revisit old concepts of health and redefine some of these in the light of emerging challenges. The One Health concept addresses some of the demands of modern medical education by providing a holistic approach to explaining diseases that result from a complex set of interactions between humans, environment and animals, rather than just an amalgamation of isolated signs and symptoms. An added advantage is that the scope of One Health concepts has now expanded to include genetic diseases due to advancements in omics technology. Inspired by such ideas, a symposium was organised as part of the 19 International Federation of Associations of Anatomists (IFAA) Congress (August 2019) to investigate the scope of One Health concepts and comparative anatomy in contemporary medical education. Speakers with expertise in both human and veterinary anatomy participated in the symposium and provided examples where these two disciplines, which have so far evolved largely independent of each other, can collaborate for mutual benefit. Finally, the speakers identified some key concepts of One Health that should be prioritised and discussed the diverse opportunities available to integrate these priorities into a broader perspective that would attempt to explain and manage diseases within the scopes of human and veterinary medicine.
Topics: Anatomy; Anatomy, Comparative; Animals; Ecosystem; Education, Medical; One Health
PubMed: 34693516
DOI: 10.1111/joa.13570 -
Anatomical Record (Hoboken, N.J. : 2007) Apr 2022This special issue is unlike any other special issue published in this journal's history. You will not find the types of original research in anatomy and evolutionary...
This special issue is unlike any other special issue published in this journal's history. You will not find the types of original research in anatomy and evolutionary biology that you are accustomed to seeing adorning the pages of The Anatomical Record. Instead, the articles included cover the past and future of the discipline of anatomy broadly and of the American Association for Anatomy (AAA) more narrowly, and through two specific rhetorical frames: ethics; and diversity, equity, and inclusion. The articles in this issue are divided into two sections. The first section traces the history of anatomy and addresses many of the ethical dilemmas we face as a result of that history. The second section sets the stage for how the discipline and the AAA move forward to create a more diverse, equitable, and inclusive future for students, teachers, colleagues, and everyone else we touch through our work as anatomists. While this is only the beginning of our reconciliation with our past, the future certainly looks bright.
Topics: Anatomists; Anatomy; Humans
PubMed: 35194948
DOI: 10.1002/ar.24901 -
Acta Medica Academica Aug 2019The aim was to study Adriaan van den Spiegel's ideas on ocular anatomy. He is better known by his Latinized name as Adrianus Spigelius (1578 - 1625). He was a Flemish...
The aim was to study Adriaan van den Spiegel's ideas on ocular anatomy. He is better known by his Latinized name as Adrianus Spigelius (1578 - 1625). He was a Flemish physician and anatomist who lived and worked in Padua, where in 1605 he was elected to be Professor of Anatomy and Surgery. Chapter IX of book ten of Spigelius' work on human anatomy, entitled De humani corporis fabrica libri X tabulis aere icisis exornati (1627) was devoted to an anatomical description of the eye. Corresponding to contemporary ideas of the production of knowledge Spigelius endeavoured to enhance Andreas Vesalius' (1514-1564) anatomy, he did not repeat his predecessor's theories of ocular anatomy. He conceptualised that the eye has six muscles, five tunics and three humors, while he gave a brief description of ocular physiology combining anatomy and the functional role of the anatomic ocular parts. CONCLUSION: He managed to correct Vesalius' errors and to present ocular anatomy with original notes, which so far, have been ignored and are highlighted now.
Topics: Eye; History, 16th Century; History, 17th Century; Humans; Italy; Medical Illustration; Ophthalmologists; Ophthalmology
PubMed: 31718226
DOI: 10.5644/ama2006-124.264 -
Anatomy & Cell Biology Sep 2021Knowledge of the variant anatomy of the intradural venous sinuses is important to anatomists and clinicians alike. Herein, we report a cadaveric case of the rare venous...
Knowledge of the variant anatomy of the intradural venous sinuses is important to anatomists and clinicians alike. Herein, we report a cadaveric case of the rare venous sinus of Kelch, which some have believed is a remnant of the cranio-orbital sinuses. To our knowledge, only one other cadaveric case has been reported in the extant medical literature. Clinically, knowledge of such a variant venous sinus can minimize misdiagnoses such as when anatomical variations are noted on imaging. Surgically, such an understanding can avoid intraoperative complications such as iatrogenic hemorrhage.
PubMed: 33896800
DOI: 10.5115/acb.21.042 -
Otology & Neurotology : Official... Mar 2022The Johns Hopkins Otologic Research Laboratory was founded in 1924 as the first human temporal bone laboratory within the United States. To better understand the...
The Johns Hopkins Otologic Research Laboratory was founded in 1924 as the first human temporal bone laboratory within the United States. To better understand the contributions of the Johns Hopkins Otologic Research Laboratory to our understanding of presbycusis, we consulted with a medical librarian and archivist to search the Alan Mason Chesney Medical Archives, PubMed, JSTOR, and Johns Hopkins Bulletin for published and unpublished works from the lab. Between 1924 and 1938, Samuel J. Crowe, the Chairman of Otolaryngology, and anatomist Stacy R. Guild amassed a collection of ∼1,800 temporal bones. This collection allowed for an unprecedented period of discovery related to otologic disease. They combined hearing thresholds measured by the recently invented audiometer with new techniques for temporal bone decalcification, sectioning, and staining, and a method for the graphic reconstruction of the cochlea. Crowe and Guild used this unique opportunity to correlate otopathology with hearing and to make the first detailed descriptions of the otopathology of presbycusis. In 1931 and 1934, they observed spiral ganglion neuron and outer hair cell loss in the basal turn of the cochlea in individuals with high-frequency hearing loss. These were the first studies to reveal that stria vascularis degeneration and middle ear pathology were not the most common causes for high-frequency hearing loss. Aside from revealing the primary driving factors of presbycusis, this work provided insight into the tonotopic organization of the cochlea. After initially being recruited to help raise money for the laboratory, medical illustrator Max Brödel used the vertical histologic cross-sections of the cochlea to produce illustrations of the ear. The decision to produce histologic sections in the plane of the superior semicircular canal likely influenced Brödel's illustrations that share a similar orientation and would later become widely circulated. Significant contributions from the Otologic Research Laboratory were also made by Mary Hardy, D.Sc., a woman who has previously received little recognition for her work. The sectioning of temporal bones was stopped in 1938 due to World War II, but much of Crowe's and Guild's work continued into the 1940s until a rift between the two resulted in the temporary closure of the laboratory in 1949. Nearly 100 years after its founding, discoveries from the Johns Hopkins Otologic Research Laboratory remain relevant and emphasize the importance of continued human temporal bone research to improve our understanding and treatment of otologic disease.
Topics: Cochlea; Female; Hearing Loss, High-Frequency; Humans; Presbycusis; Stria Vascularis; Temporal Bone; United States
PubMed: 35061640
DOI: 10.1097/MAO.0000000000003466 -
Advances in Medical Education and... 2022This article presents a qualitative study of African anatomists and anatomy teachers on the Anatomage Table-a modern medical education technology and innovation, as an...
BACKGROUND
This article presents a qualitative study of African anatomists and anatomy teachers on the Anatomage Table-a modern medical education technology and innovation, as an indicator of African anatomy medical and anatomy educators' acceptance of EdTech. The Anatomage Table is used for digital dissection, prosection, functional anatomy demonstration, virtual simulation of certain functions, and interactive digital teaching aid.
MATERIALS AND METHODS
Anatomy teachers [n=79] from 11 representative African countries, Ghana, Nigeria [West Africa], Ethiopia, Kenya, Rwanda [East Africa], Namibia [South Africa], Zambia [Southern Africa], Egypt [North Africa], and Sudan [Central Africa], participated in this study. Focus group discussions [FGDs] were set up to obtain qualitative information from stakeholders from representative institutions. In addition, based on the set criteria, selected education leaders and stakeholders in representative institutions participated in In-depth Interviews [IDIs]. The interview explored critical issues concerning their perceptions about the acceptance, adoption, and integration of educational technology, specifically, the Anatomage Table into the teaching of Anatomy and related medical sciences in the African continent. Recorded interviews were transcribed and analyzed using the Dedoose software.
RESULTS
African anatomists are generally technology inclined and in favor of EdTech. The most recurring opinion was that the Anatomage Table could only be a "complementary teaching tool to cadavers" and that it "can't replace the real-life experience of cadavers." Particularly, respondents from user institutions opined that it "complements the traditional cadaver-based approaches" to anatomy learning and inquiry, including being a good "complement for cadaveric skill lab" sessions. Compared with the traditional cadaveric dissections a majority also considered it less problematic regarding cultural acceptability and health and safety-related concerns. The lifelikeness of the 3D representation is a major factor that drives acceptability.
PubMed: 35693029
DOI: 10.2147/AMEP.S358702 -
Sensors (Basel, Switzerland) Jun 2021Most accidents in the aviation, maritime, and construction industries are caused by human error, which can be traced back to impaired mental performance and attention... (Review)
Review
Most accidents in the aviation, maritime, and construction industries are caused by human error, which can be traced back to impaired mental performance and attention failure. In 1596, Du Laurens, a French anatomist and medical scientist, said that the eyes are the windows of the mind. Eye tracking research dates back almost 150 years and it has been widely used in different fields for several purposes. Overall, eye tracking technologies provide the means to capture in real time a variety of eye movements that reflect different human cognitive, emotional, and physiological states, which can be used to gain a wider understanding of the human mind in different scenarios. This systematic literature review explored the different applications of eye tracking research in three high-risk industries, namely aviation, maritime, and construction. The results of this research uncovered the demographic distribution and applications of eye tracking research, as well as the different technologies that have been integrated to study the visual, cognitive, and attentional aspects of human mental performance. Moreover, different research gaps and potential future research directions were highlighted in relation to the usage of additional technologies to support, validate, and enhance eye tracking research to better understand human mental performance.
Topics: Aviation; Construction Industry; Eye Movements; Eye-Tracking Technology; Humans; Technology
PubMed: 34201734
DOI: 10.3390/s21134289