NIH/NIBIB Introduces New Center for Biomedical Engineering Technology Acceleration.

In Late January 2023, the National Institute of Biomedical Imaging and Bioengineering (NIBIB) launched a new center designed to accelerate biomedical discovery and therapeutics, in part by pulling together expert, multidisciplinary teams from throughout the National Institutes of Health (NIH) to quickly respond when national or global health crises strike. The inaugural director of this Center for BME Technology Acceleration, or BETA Center, is biomedical engineer Manu Platt, Ph.D., (Figure 1) who is also taking on the role of NIBIB associate director for scientific diversity, equity, and inclusion. Platt previously held appointments as professor, Wallace H. Coulter distinguished faculty fellow, and diversity director of the Center on Emergent Behaviors of Integrated Cellular Systems and Cellular Manufacturing and Technologies at the Georgia Institute of Technology and Emory University.

Hydrogel Tissue Bioengineered Scaffolds in Bone Repair: A Review.

Large bone defects due to trauma, infections, and tumors are difficult to heal spontaneously by the body's repair mechanisms and have become a major hindrance to people's daily lives and economic development. However, autologous and allogeneic bone grafts, with their lack of donors, more invasive surgery, immune rejection, and potential viral transmission, hinder the development of bone repair. Hydrogel tissue bioengineered scaffolds have gained widespread attention in the field of bone repair due to their good biocompatibility and three-dimensional network structure that facilitates cell adhesion and proliferation. In addition, loading natural products with nanoparticles and incorporating them into hydrogel tissue bioengineered scaffolds is one of the most effective strategies to promote bone repair due to the good bioactivity and limitations of natural products. Therefore, this paper presents a brief review of the application of hydrogels with different gel-forming properties, hydrogels with different matrices, and nanoparticle-loaded natural products loaded and incorporated into hydrogels for bone defect repair in recent years.

The digitization process and the evolution of Clinical Risk Management concept: The role of Clinical Engineering in the operational management of biomedical technologies.

Introduction: Digital transformation and technological innovation which have influenced several areas of social and productive life in recent years, are now also a tangible and concrete reality in the vast and strategic sector of public healthcare. The progressive introduction of digital technologies and their widespread diffusion in many segments of the population undoubtedly represent a driving force both for the evolution of care delivery methods and for the introduction of new organizational and management methods within clinical structures. Methods: The CS Clinical Engineering of the "Spedali Civili Hospital in Brescia" decided to design a path that would lead to the development of a software for the management of biomedical technologies within its competence inside the hospital. The ultimate aim of this path stems from the need of Clinical Engineering Department to have up-to-date, realistic, and systematic control of all biomedical technologies present in the company. "Spedali Civili Hospital in Brescia" is not just one of the most important corporate realities in the city, but it is also the largest hospital in Lombardy and one of the largest in Italy. System development has followed the well-established phases: requirement analysis phase, development phase, release phase and evaluating and updating phase. Results: Finally, cooperation between the various figures involved in the multidisciplinary working group led to the development of an innovative management software called "SIC Brescia". Discussion: The contribution of the present paper is to illustrate the development of a complex implementation model for the digitization of processes, information relating to biomedical technologies and their management throughout the entire life cycle. The purpose of sharing this path is to highlight the methodologies followed for its realization, the results obtained and possible future developments. This may enable other realities in the healthcare context to undertake the same type of pathway inspired by an accomplished model. Furthermore, future implementation and data collection related to the proposed Key Performance Indicators, as well as the consequent development of new operational management models for biomedical technologies and maintenance processes will be possible. In this way, the Clinical Risk Management concept will also be able to evolve into a more controlled, safe, and efficient system for the patient and the user.

Diagnostic quality assessment for low-dimensional ECG representations.

There have been several attempts to quantify the diagnostic distortion caused by algorithms that perform low-dimensional electrocardiogram (ECG) representation. However, there is no universally accepted quantitative measure that allows the diagnostic distortion arising from denoising, compression, and ECG beat representation algorithms to be determined. Hence, the main objective of this work was to develop a framework to enable biomedical engineers to efficiently and reliably assess diagnostic distortion resulting from ECG processing algorithms. We propose a semiautomatic framework for quantifying the diagnostic resemblance between original and denoised/reconstructed ECGs. Evaluation of the ECG must be done manually, but is kept simple and does not require medical training. In a case study, we quantified the agreement between raw and reconstructed (denoised) ECG recordings by means of kappa-based statistical tests. The proposed methodology takes into account that the observers may agree by chance alone. Consequently, for the case study, our statistical analysis reports the "true", beyond-chance agreement in contrast to other, less robust measures, such as simple percent agreement calculations. Our framework allows efficient assessment of clinically important diagnostic distortion, a potential side effect of ECG (pre-)processing algorithms. Accurate quantification of a possible diagnostic loss is critical to any subsequent ECG signal analysis, for instance, the detection of ischemic ST episodes in long-term ECG recordings.

Implementation of Health Technology Assessment and Management Course in Undergraduate Program in Biomedical Engineering ITB.

The Undergraduate Program in Biomedical Engineering ITB, Indonesia, introduce the Health Technology Assessment and Management as an elective course in 2021. This course is implemented to support the World Health Assembly that urges the member states to establish national strategies in health technology assessment and management, particularly medical devices. Furthermore, it is designed to give biomedical engineering students a broader insight into their career opportunities. Therefore, this course is delivered by the practitioner and guided by the main lecturer. The course syllabus is developed from the WHO Medical Devices Technical Series and European Network for Health Technology Assessment. It tries to implement HTA Core Model for Rapid Relative Effectiveness Assessments. A questionnaire is used to measure the students' perception of the course implementation. Moreover, it is used to obtain the students' comments and feedback. The course that is delivered by the practitioner not only gives the course content but also the context. After attending the course, students have a broader insight into the career opportunities as biomedical engineers in Indonesia.

Las normas técnicas para la formación en ingeniería biomédica, tecnología y administración en salud / Technical standards for the training in biomedical engineering, health technology and health management

Introducción: Los documentos normativos establecen el estado del arte relacionado con determinado campo del conocimiento. Existe una gran cantidad de normas relacionadas con los servicios de salud y su gestión, cuya aplicación es relevante en este sector. Objetivo: Exponer la importancia de las normas técnicas en la formación de los profesionales en ingeniería biomédica, tecnología y administración en salud. Desarrollo: Diferentes aspectos relacionados con el desempeño y las funciones de los profesionales en ingeniería biomédica, tecnología de la salud y administración en salud están recogidos en normas técnicas internacionales y en otras de carácter nacional, que resultan pertinentes y de gran utilidad para su formación en el nivel de grado y el posgrado. Conclusiones: Las profesiones abordadas requieren emplear los documentos normativos relacionados con sus funciones para contribuir con la calidad de los servicios de salud; de ahí la pertinencia de su incorporación en los planes de estudio de estas carreras(AU)

Introduction: Normative documents establish the state of the art related to a certain field of knowledge. There is a large number of standards related to health services and their management, whose application is relevant in this sector. Objective: To show the importance of technical standards in the training of professionals from the fields of biomedical engineering, health technology and health management. Development: Different aspects related to the performance and functions of professionals from the fields of biomedical engineering, health technology and health management are gathered in international and other national technical standards, relevant and useful for their training at the undergraduate and postgraduate levels. Conclusions: The addressed professions require the use of normative documents related to their functions in order to contribute to the quality of health services, hence the relevance of their incorporation into the curriculums of these major(AU)

Las normas técnicas para la formación en ingeniería biomédica, tecnología y administración en salud / Technical standards for the training in biomedical engineering, health technology and health management

Introducción: Los documentos normativos establecen el estado del arte relacionado con determinado campo del conocimiento. Existe una gran cantidad de normas relacionadas con los servicios de salud y su gestión, cuya aplicación es relevante en este sector. Objetivo: Exponer la importancia de las normas técnicas en la formación de los profesionales en ingeniería biomédica, tecnología y administración en salud. Desarrollo: Diferentes aspectos relacionados con el desempeño y las funciones de los profesionales en ingeniería biomédica, tecnología de la salud y administración en salud están recogidos en normas técnicas internacionales y en otras de carácter nacional, que resultan pertinentes y de gran utilidad para su formación en el nivel de grado y el posgrado. Conclusiones: Las profesiones abordadas requieren emplear los documentos normativos relacionados con sus funciones para contribuir con la calidad de los servicios de salud; de ahí la pertinencia de su incorporación en los planes de estudio de estas carreras(AU)

Introduction: Normative documents establish the state of the art related to a certain field of knowledge. There is a large number of standards related to health services and their management, whose application is relevant in this sector. Objective: To show the importance of technical standards in the training of professionals from the fields of biomedical engineering, health technology and health management. Development: Different aspects related to the performance and functions of professionals from the fields of biomedical engineering, health technology and health management are gathered in international and other national technical standards, relevant and useful for their training at the undergraduate and postgraduate levels. Conclusions: The addressed professions require the use of normative documents related to their functions in order to contribute to the quality of health services, hence the relevance of their incorporation into the curriculums of these major(AU)

Toward a More Ethical and Sustainable Biomedical Engineering Education.

Important Lessons Can be learned from the COVID-19 pandemic, which after more than two years of worldwide suffering is still among us. First, we now better understand that global health concerns cannot be tackled and solved individually and verify that the dream for universal health care is far from being fulfilled. Besides, biomedical technologies and medical devices, despite their transformative potential, cannot always reach those urgently needing them, due to centralized production, supply chain issues, intellectual property restrictions, and lack of raw materials and resources close to the point of care, which calls for a renovation of the biomedical industry aimed at sustainability and equity. To make matters worse, unethical behaviors of governments, companies, and citizens, from which the ongoing pandemic has provided plenty of examples, also endanger the already challenging progress toward the Sustainable Development Goals (SDGs), including "Goal 3" on "Good Health and Well Being."

Assessment of biomedical engineering knowledge using true-false questions.

The COVID-19 pandemic has caused a shift from on-campus to remote online examinations, which are usually difficult to invigilate. Meanwhile, closed-ended question formats, such as true-false (TF), are particularly suited to these examination conditions, as they allow automatic marking by computer software. While previous studies have reported the score characteristics in TF questions in conventional supervised examinations, this study investigates the efficacy of using TF questions in online, unsupervised examinations at the undergraduate level of Biomedical Engineering. We examine the TF and other question-type scores of 57 students across three examinations held in 2020 under online, unsupervised conditions. Our analysis shows significantly larger coefficient of variance (CV) in scores in TF questions (42.7%) than other question types (22.3%). The high CV in TF questions may be explained by different answering strategies among students, with 13.3 ± 17.2% of TF questions left unanswered (zero marks) and 16.4 ± 11.5% of TF questions guessed incorrectly (negative marks awarded). In unsupervised, open-book examination where sharing of answers among students is a potential risk; questions that induce a larger variation in responses may be desirable to differentiate among students. We also observed a significant relationship (r = 0.64, p < 0.05) between TF scores and the overall subject scores, indicating that TF questions are an effective predictor of overall student performance. Our results from this initial analysis suggests that TF questions are useful for assessing biomedical-theme content in online, unsupervised examinations, and are encouraging for their ongoing use in future assessments.

Engineering Aspects of Incidence, Prevalence, and Management of Osteoarthritis: A Review.

The knee is the biggest and complicated lower extremity joint that supports mobility and the entire weight of the human body and lies between the hip joint and ankle joint. Osteoarthritis (OA) is the most common joint disease in the knee among various musculoskeletal disorders globally, with an age-associated increase in incidence and prevalence. Health monitoring of the knee joints in daily life, and early OA diagnosis is challenging and draws attention to the various methods of diagnosis for this irreversible disease. In this review, electronic databases have been searched from inception for a detailed study about knee OA and its management. It focuses on various sensor technologies and different semi-invasive and non-invasive diagnosis methods with their limitations. In the last decade, various researchers have engrossed their attention to the potential of piezoelectric-based acoustic sensors to fabricate a wearable device for OA and its management. A sensor-based wearable device using vibroarthrography as a tool can be an appropriate solution for early-stage disease detection. We firmly believe that wearable technology for the detection of OA in daily life activities will play a significant role in managing this disease and help to reduce the chances of total knee replacements.

[Development of first-class biotechnology major under new economic situation].

The rapid development of bioeconomy urgently needs the support of biotechnology talents. Establishing an innovative training mode of biotechnology talents can provide support for regional economic development and industrial upgrading. Closely revolved around the concepts of new engineering disciplines development, such as serving the national strategy, docking industry, leading the future development and student-centered, a new economy-oriented training system was developed in School of Bioengineering of Dalian University of Technology. These systems include interdisciplinary curriculum system reconstruction, project-based teaching mode reform, evaluation system implementation and other aspects. The reform and exploration of the first-class biotechnology major under the new economic situation, puts forward the theory of value guidance, deep foundation, strong sense of innovation, technical and non-technical core ability literacy. This reform meets the industry demand for talent diversification, personalization, and dynamic change, helps the merge of industry and education, which provides a way for fostering first-class biotechnology-majored undergraduates.

Characterization and in vitro assessment of three-dimensional extrusion Mg-Sr codoped SiO2-complexed porous microhydroxyapatite whisker scaffolds for biomedical engineering.

BACKGROUND: Large bone defects have always been a great challenge for orthopedic surgeons. The use of a good bone substitute obtained by bone tissue engineering (BTE) may be an effective treatment method. Artificial hydroxyapatite, a commonly used bone defect filler, is the main inorganic component of bones. Because of its high brittleness, fragility, and lack of osteogenic active elements, its application is limited. Therefore, its fragility should be reduced, its osteogenic activity should be improved, and a more suitable scaffold should be constructed. METHODS: In this study, a microhydroxyapatite whisker (mHAw) was developed, which was doped with the essential trace active elements Mg2+ and Sr2+ through a low-temperature sintering technique. After being formulated into a slurry, a bionic porous scaffold was manufactured by extrusion molding and freeze drying, and then SiO2 was used to improve the mechanical properties of the scaffold. The hydrophilicity, pore size, surface morphology, surface roughness, mechanical properties, and release rate of the osteogenic elements of the prepared scaffold were detected and analyzed. In in vitro experiments, Sprague-Dawley (SD) rat bone marrow mesenchymal stem cells (rBMSCs) were cultured on the scaffold to evaluate cytotoxicity, cell proliferation, spreading, and osteogenic differentiation. RESULTS: Four types of scaffolds were obtained: mHAw-SiO2 (SHA), Mg-doped mHAw-SiO2 (SMHA), Sr-doped mHAw-SiO2 (SSHA), and Mg-Sr codoped mHAw-SiO2 (SMSHA). SHA was the most hydrophilic (WCA 5°), while SMHA was the least (WCA 8°); SMHA had the smallest pore size (247.40 ± 23.66 µm), while SSHA had the largest (286.20 ± 19.04 µm); SHA had the smallest Young's modulus (122.43 ± 28.79 MPa), while SSHA had the largest (188.44 ± 47.89 MPa); and SHA had the smallest compressive strength (1.72 ± 0.29 MPa), while SMHA had the largest (2.47 ± 0.25 MPa). The osteogenic active elements Si, Mg, and Sr were evenly distributed and could be sustainably released from the scaffolds. None of the scaffolds had cytotoxicity. SMSHA had the highest supporting cell proliferation and spreading rate, and its ability to promote osteogenic differentiation of rBMSCs was also the strongest. CONCLUSIONS: These composite porous scaffolds not only have acceptable physical and chemical properties suitable for BTE but also have higher osteogenic bioactivity and can possibly serve as potential bone repair materials.

Modeling optical design parameters for fine stimulation in sciatic nerve of optogenetic mice.

Optogenetics presents an alternative method for interfacing with the nervous system over the gold-standard of electrical stimulation. While electrical stimulation requires electrodes to be surgically embedded in tissue for in vivo studies, optical stimulation offers a less-invasive approach that may yield more specific, localized stimulation. The advent of optogenetic laboratory animals-whose motor neurons can be activated when illuminated with blue light-enables research into refining optical stimulation of the mammalian nervous system where subsets of nerve fibers within a nerve may be stimulated without embedding any device directly into the nerve itself. However, optical stimulation has a major drawback in that light is readily scattered and absorbed in tissue thereby limiting the depth with which a single emission source can penetrate. We hypothesize that the use of multiple, focused light emissions deployed around the circumference of a nerve can overcome these light-scattering limitations. To understand the physical parameters necessary to produce pinpointed light stimulation within a single nerve, we employed a simplified Monte Carlo simulation to estimate the size of nerves where this technique may be successful, as well as the necessary optical lens design for emitters to be used during future in vivo studies. By modeling multiple focused beams, we find that only fascicles within a nerve diameter less than 1 mm are fully accessible to focused optical stimulation; a minimum of 4 light sources is required to generate a photon intensity at a point in a nerve over the initial contact along its surface. To elicit the same effect in larger nerves, focusing lenses would require a numerical aperture [Formula: see text]. These simulations inform on the design of instrumentation capable of stimulating disparate motor neurons in mouse sciatic nerve to control hindlimb movement.

The RADxSM Tech Process: Accelerating Innovation for COVID-19 Testing.

In the wake of the COVID-19 pandemic, the need for rapid and accurate diagnostic testing across populations quickly became evident. In response, the National Institutes of Health (NIH) was determined not only to invest heavily in this area but to change the process by which grant proposals were reviewed and funded in order to spur faster development of viable technologies. The Rapid Acceleration of Diagnostics (RADx) initiative was designed to speed innovation, commercialization, and implementation of potential COVID-19 diagnostic technology. As part of this effort, the RADx Tech initiative focuses on the development, validation, and commercialization of innovative point-of-care, home-based, and clinical lab-based tests that can detect SARS-CoV-2. This effort was enabled through the NIH's National Institute of Biomedical Imaging and Bioengineering (NIBIB) Point-of-Care Technology Research Network (POCTRN).

A systematic approach to the scale separation problem in the development of multiscale models.

Throughout engineering there are problems where it is required to predict a quantity based on the measurement of another, but where the two quantities possess characteristic variations over vastly different ranges of time and space. Among the many challenges posed by such 'multiscale' problems, that of defining a 'scale' remains poorly addressed. This fundamental problem has led to much confusion in the field of biomedical engineering in particular. The present study proposes a definition of scale based on measurement limitations of existing instruments, available computational power, and on the ranges of time and space over which quantities of interest vary characteristically. The definition is used to construct a multiscale modelling methodology from start to finish, beginning with a description of the system (portion of reality of interest) and ending with an algorithmic orchestration of mathematical models at different scales within the system. The methodology is illustrated for a specific but well-researched problem. The concept of scale and the multiscale modelling approach introduced are shown to be easily adaptable to other closely related problems. Although out of the scope of this paper, we believe that the proposed methodology can be applied widely throughout engineering.

Innovation at a Children's Hospital: Personal Protective Equipment Efforts During the Pandemic.

The COVID-19 pandemic has affected life for everyone, and hospitals, in particular have been hard hit. In this study, we describe our efforts to develop personal protective equipment at a children's hospital early in the pandemic. We convened an innovation working group to organize our efforts and respond to the rapidly changing situation. We describe our work in four areas: (1) plexiglass shields for the emergency department, (2) face shields for clinical providers, (3) breath shields for ophthalmology, and (4) flip-up safety glasses for nurses. The hospital's supply chain is now caught up with addressing many pandemic-related shortages. Nevertheless, through our multidisciplinary approach to reacting to the pandemic's urgent needs, we demonstrated agility to bring stakeholders together to maximize the use of scarce resources and build resiliency. We believe this method can be rapidly replicated as future needs arise.

Advances in Micro/Nanoporous Membranes for Biomedical Engineering.

Porous membrane materials at the micro/nanoscale have exhibited practical and potential value for extensive biological and medical applications associated with filtration and isolation, cell separation and sorting, micro-arrangement, in-vitro tissue reconstruction, high-throughput manipulation and analysis, and real-time sensing. Herein, an overview of technological development of micro/nanoporous membranes (M/N-PMs) is provided. Various membrane types and the progress documented in membrane fabrication techniques, including the electrochemical-etching, laser-based technology, microcontact printing, electron beam lithography, imprinting, capillary force lithography, spin coating, and microfluidic molding are described. Their key features, achievements, and limitations associated with micro/nanoporous membrane (M/N-PM) preparation are discussed. The recently popularized applications of M/N-PMs in biomedical engineering involving the separation of cells and biomolecules, bioparticle operations, biomimicking, micropatterning, bioassay, and biosensing are explored too. Finally, the challenges that need to be overcome for M/N-PM fabrication and future applications are highlighted.