The text invites readers to explore a demo of BMF's Projection Micro Stereolighography (PµSL) technology and learn more about the microArch S240, the latest 3D printer in their product line. The purpose of the presentation is to provide a deeper understanding of what sets BMF apart from other companies. Interested individuals are encouraged to visit the company's website or send an email for more information.

Researchers are turning towards 3D printing technology for glass fabrication as traditional manufacturing processes require complex high-temperature melting and casting, which presents a great challenge to the fabrication of arbitrarily complex glass devices. The emergence of 3D printing technology provides a good solution. A paper has reviewed recent advances in glass 3D printing, describing the history and development of related technologies while listing popular applications of 3D printing for glass preparation. The review has compared the advantages and disadvantages of various processing methods, summarised the problems encountered in the process of technology application, and proposes corresponding solutions to select the most appropriate preparation method in practical applications. The application of additive manufacturing in glass fabrication is in its infancy but has great potential. The methods for glass preparation with 3D printing technology are expected to achieve both high-speed and high-precision fabrication.

A survey of 430 students from the Medical University of Silesia in Poland found that medical students have knowledge of 3D printing and are keen to deepen their understanding. They believe that 3D printing provides opportunities in medicine and could be useful for creating anatomical models. However, they are not convinced that human cadavers should be abandoned entirely in anatomy classes, even though they appreciate the value of a more tangible learning experience. While many students already have knowledge of 3D printing through the internet, the results suggest that medical training should expand course curriculum to include information regarding 3D printing technology in medicine. This would allow students to study the current applications of 3D printing and know how to use those applications in their own clinical practice later. Students had no ethical doubts about the use of 3D printing in any form. This study is the first of its kind to examine the knowledge of additive technology in medicine among medical students.

The Department of Computers and Informatics at TU Kosice offers students the opportunity to study virtual reality technologies and computer graphics. This is a new subject which focuses on theoretical knowledge and practical experiences in 3D computer graphics, virtual reality technologies, and computer games. Students work in a laboratory with the latest virtual reality technologies including Microsoft Hololens, 3D scanning, and 3D printing. They also create content such as applications or virtual models and scenes. The department has also developed a new technology known as CAVE (Cave Automatic Virtual Environment). The ultimate goal of the department is to use these technologies for handicapped people education. The paper focuses on the experiences of virtual reality in education as both a subject of study and a tool for studying. Overall, the department is dedicated to keeping pace with advances in technology in order to provide its students with a practical education that can be applied in the field.

The potential challenges and opportunities arising from the development and proliferation of 3D printing technology are discussed in this paper. The focus is on how society would cope if 3D printing advanced to a stage where it became possible to replicate any commodity or currency form accurately and cheaply. The idea of replicating technology has a long intellectual history, with past writers and thinkers considering the effects that might result from the potential emergence of mass 3D printing capabilities. The paper examines George O. Smith’s Venus Equilateral series (1942-1945) and his treatment of the 3D printing phenomenon, as well as his attempts to incorporate the idea of mass replicating technology into a wider socio-economic framework. The paper ultimately concludes that while Smith’s technological portrayal may seem outdated, his insights on the potential social ruptures and cultural transformations that could result from mass replicating technology remain relevant today. Overall, the paper highlights the need to consider the implications of 3D printing technology and other forms of replicating technology as they continue to develop and become more widespread.

A review article in the Journal of Contemporary Brachytherapy explores emerging technologies that could drive future innovations in brachytherapy treatments for cancer. The article examines four topics that could have an impact in the future: intensity modulated brachytherapy (IMBT), 3D printing, innovations in treatment planning involving catheter placement and dwell times, and deep learning. IMBT utilises high-density shielding designs to achieve high-quality plans, while 3D printing allows for the customisation of applicators and treatment plans. Innovations in treatment planning involve new modelling approaches, solution algorithms, and advanced technologies. Machine learning technique deep learning could be used to automate all aspects of brachytherapy workflow. Although not all of these innovations are expected to reach the clinic, the review provides insight into what the future of brachytherapy may hold. The authors suggest that these technologies, once they have been translated into pilot testing and sensibly phased clinical trials, could ultimately make a positive difference for cancer patients.

The healthcare industry is rapidly developing new technologies that impact the way we care for patients, including robotics, advanced imaging, genetic processing techniques, and 3D printing. The Orthopaedic community is experiencing significant innovation, including complex pelvic reconstruction using 3D-printed custom implants and patient-specific instrumentation, diagnosis of periprosthetic arthroplasty infection, robotics in total hip arthroplasty, and hip cartilage restoration techniques. Innovation is a hallmark of advancement in medicine, and these articles aim to spark innovative ideas and healthy skepticism. While new technologies are exciting, there are failures, and innovation in new technology is at least one reason why patient outcomes are continually improving.

The integration of new technologies is the key to success in the military field. This article highlights the significance of technology as a fundamental factor that drives social change, especially in the military sphere. The text identifies various innovations in artificial intelligence, robotics, autonomous systems, space technology, 3D printing, biotechnology, materials science and quantum computing that will bring unprecedented transformations. The report discusses the significance of intelligence, autonomy, humanistic intelligence, and interconnection in shaping the future of military success. It indicates that new forms of war - hyper war, memetic war, and cyberspace war - have emerged as a result of technological advancement. Therefore, the future scientific and technological landscape in the military sphere will be characterized by a seamless integration of psycho-socio-technological systems that support human and machine connectivity. The report presents publications by various international analytical and consulting organizations, foreign governments, NATO, SIPRI, the Munich Security Conference, and the EU, presenting forecasts for the introduction and adaptation of new technologies and methods originating from the civilian sector into military programs for military transformation.