A 3D printed microfluidic PCR device towards detecting SARS-CoV-2

A 3D printed (3DP) microfluidic polymerase chain reaction (PCR) device was demonstrated by detecting synthetic SARSCoV-2 at 106 copies/μL. The microfluidic device was fabricated using stereolithography 3DP and had a reaction volume of ~22 nL. The microdevice showed PCR amplification with 85 base synthetic ssDNA targets and primers designed for a SARS-CoV-2-specific region. The device was 2.5 times faster compared to a qPCR instrument with >60,000 times smaller reagent volume. The 3DP microdevice is a promising technology to significantly reduce the manufacturing costs of microfluidic devices that could be used towards point-of-care applications. © 2023 SPIE.

Global Health Technologies are Transforming Intellectual Property and World Trade

The nano-enabled technology of 3-D printing for medical devices presents a dynamic new avenue for meeting patient needs. 3-D printers can generate food, soaps, cosmetics, body parts, metal devices, or medicines. This technology enables continuity of health care delivery despite disruptive breaks in any supply chain due to war, shortage, or broken distribution lines due to pandemic force majeure.1 Featuring custom-tailored attributes for each device, economic efficiency by eliminating transport costs during emergencies, avoiding issues of distribution supply chains, and offering biocompatibility, 3-D printed medical devices during the COVID-19 pandemic2 provided a very attractive alternative to enduring medical supply shortages worldwide. Beyond the covid-19 pandemic exigencies, 3-D printed medical devices promise custom-tailored meals to meet medical needs that are unique for each patient's metabolism and a wide variety of tools for patient care that will change the shape of global commerce.3 3-D printing offers the alluring promise of biocompatible medical devices, matching any patient's unique anatomy, using a specific patient's imaging data, or using a standard design to make multiple identical copies of the same device, but without delays for transport or shipping and insurance costs. The global health impact of these efforts, from the standpoint of patient safety4 and overall deterrence of unnecessary or unsafe medical practices, remains unclear due to the absence of regulation and monitoring. The reality is that commerce can reduce or eliminate transport and storage costs associated with shipping and can change international trade. Yet, 3-D printing simultaneously offers great promise to meet challenges arising from the arcane role of intellectual property rights (IPR)5 in shaping the creation and transfer of nanomedicines and nanotechnologies to attain health equity and meet universal needs of health for all. These millennial technological changes may permanently alter how civil society does business for global health. © 2022, Andover House, Inc.. All rights reserved.

3D-Printed Face Mask with Integrated Sensors as Protective and Monitoring Tool

The outbreak of the recent Covid-19 pandemic changed many aspects of our daily life, such as the constant wearing of face masks as protection from virus transmission risks. Furthermore, it exposed the healthcare system's fragilities, showing the urgent need to design a more inclusive model that takes into account possible future emergencies, together with population's aging and new severe pathologies. In this framework, face masks can be both a physical barrier against viruses and, at the same time, a telemedical diagnostic tool. In this paper, we propose a low-cost, 3D-printed face mask able to protect the wearer from virus transmission, thanks to internal FFP2 filters, and to monitor the air quality (temperature, humidity, CO2) inside the mask. Acquired data are automatically transmitted to a web terminal, thanks to sensors and electronics embedded in the mask. Our preliminary results encourage more efforts in these regards, towards rapid, inexpensive and smart ways to integrate more sensors into the mask's breathing zone in order to use the patient's breath as a fingerprint for various diseases. © The Author(s), under exclusive license to Springer Nature Switzerland AG 2023.

Towards Augmented Reality Guiding Systems: An Engineering Design of an Immersive System for Complex 3D Printing Repair Process

Over the past decade, additive manufacturing (AM) has become widely adopted for both prototyping and, more recently, end-use products. In particular, fused deposition modeling (FDM) is the most widespread form of additive manufacturing due to its low cost, ease of use, and versatility. While additive processes are relatively automated, many steps in their operation and repair require trained human operators. Finding such operators can be difficult, as highlighted during the recent COVID-19 pandemic. Augmented reality (AR) systems could significantly help address this challenge by automating the training for 3D printer operators. Given multidimensional design choices, however, a research gap exists in the system requirements for such immersive guidance. To address this need, we explore the applicability of AR to guide users through a repair process. In that context, we report on the system design as well as the results of the AR system assessment in a qualitative study with experts. © 2023 IEEE.

Leading by example: Leveraging academic innovation centers in times of crisis

Universities worldwide are increasingly investing in academic innovation centers that are designed to encourage their students to pursue careers focused on innovation and technology. This chapter explores the educational opportunities of these academic innovation centers during crisis situations by documenting how an academic innovation center at Florida State University - the Innovation Hub - was able to encourage university students to engage in creative problem solving through design thinking, emerging technologies, and experiential learning during the COVID-19 pandemic. The results of these efforts demonstrate that academic innovation centers, during times of global crisis, have a unique opportunity to lead by example, enhancing their educational impact by connecting students directly with real-world challenges as creative problem solvers with the power to improve their communities. © Springer Nature Switzerland AG 2021. All rights reserved.

Dual-Action Effect of Gallium and Silver Providing Osseointegration and Antibacterial Properties to Calcium Titanate Coatings on Porous Titanium Implants.

Previously, functional coatings on 3D-printed titanium implants were developed to improve their biointegration by separately incorporating Ga and Ag on the biomaterial surface. Now, a thermochemical treatment modification is proposed to study the effect of their simultaneous incorporation. Different concentrations of AgNO3 and Ga(NO3)3 are evaluated, and the obtained surfaces are completely characterized. Ion release, cytotoxicity, and bioactivity studies complement the characterization. The provided antibacterial effect of the surfaces is analyzed, and cell response is assessed by the study of SaOS-2 cell adhesion, proliferation, and differentiation. The Ti surface doping is confirmed by the formation of Ga-containing Ca titanates and nanoparticles of metallic Ag within the titanate coating. The surfaces generated with all combinations of AgNO3 and Ga(NO3)3 concentrations show bioactivity. The bacterial assay confirms a strong bactericidal impact achieved by the effect of both Ga and Ag present on the surface, especially for Pseudomonas aeruginosa, one of the main pathogens involved in orthopedic implant failures. SaOS-2 cells adhere and proliferate on the Ga/Ag-doped Ti surfaces, and the presence of gallium favors cell differentiation. The dual effect of both metallic agents doping the titanium surface provides bioactivity while protecting the biomaterial from the most frequent pathogens in implantology.

Significance of 3D printing for a sustainable environment

The additive manufacturing, also known as 3D-printing, allows for a complete control over the entire manufacturing process that can be tuned to any application. In recent years, it has been tested for its role in various areas like environmental contaminant monitoring, providing solutions for the energy generation and storage and healthcare. To encourage sustainable detection platforms for the pollutants, the sensing electrodes have been reported to be 3D printed because of enhanced electrochemical properties coming from the high surface area of the printed materials. In general, the conventional methods of electrode preparation are time consuming, expensive, and mostly not adaptable. 3D printing however, negates all these challenges. Similarly, in the energy generation and storage field, the rapid and lightweight materials used during 3D printing make them viable and suitable alternative. Since 3D printing is a bottom-up method for the fabrication, the amount of raw material consumed can be tuned and the by-products or wastage minimized. Apart from these demanding areas, additive manufacturing, in last 2 years which witnessed epidemic outspread, has supported health sector immensely in fight against COVID. 3D printing allowed the rapid manufacturing of COVID-19 detection kits and helped maintain the COVID-19 safeguards in place. Sample collection swabs, respirators and other components of the PPE kits were among many products developed using 3D printing during the pandemic. Keeping these things in mind, this review encapsulates the use of 3 D printing for energy application, detection of water and biological contaminants and as safeguard tool during covid pandemic.

Design Experience of Laboratory Practices in COVID Times

The development of laboratory practices is necessary for training mechatronics engineering students because they must learn in scenarios that allow checking the theories reviewed in class and implementing their solutions to real-world challenges posed in a course. Unexpectedly, the COVID pandemic caused a rethinking of how to develop the laboratory as a form of teaching, looking for online alternatives using simulation platforms, portable instruments, and 3D printing to design prototypes. This work presents the experience of two online laboratory practice activities in two mechatronics engineering subjects, which allowed students to complement their training without the risk of contagion, develop the planned competencies, and acquire skills in this form of teaching. © 2023 IEEE.

The Impact of Digitalization of the Economy on the Cooperation of Economic Entities in the Post-pandemic Period

According to the authors, the digital transformation of the global economic system, which has affected all areas of business and sectors of the economy, has led to the formation of a new business model aimed at creating a single financial and economic space without borders, contributing to new forms of obtaining added value and "digital dividends” by combining various technologies (for example, cloud technologies, sensors, big data, 3D printing), as well as the development of markets for goods and services, labor reserves and capital through transformations at all social levels. The authors believe that all of the above opens up expanded opportunities for organizing and doing business and allows increasing the potential for creating radically new products, services and innovative business models focused on sustainable business development in the new conditions of digitization of the economic system. In this regard, the paper explores key approaches to the definition of the term "digital transformation of business.” The trends of business digitalization and, accordingly, the factors that are inhibitors and drivers of the development of a new business model of cooperation and cooperation of modern organizations were identified. In the process of analysis, the authors determined the vector of development of business models in the context of the digital transformation of the global economic system. © 2023, The Author(s), under exclusive license to Springer Nature Switzerland AG.

Smart and functional textiles

Smart and Functional Textiles is an application-oriented book covering a wide range of areas from multifunctional nanofinished textiles, coated and laminated textiles, wearable e-textiles, textile-based sensors and actuators, thermoregulating textiles, to smart medical textiles and stimuli-responsive textiles. It also includes chapters on 3D printed smart textiles, automotive smart textiles, smart textiles in military and defense, as well as functional textiles used in care and diagnosis of Covid-19. • Overview of smart textiles and their multidirectional applications • Materials, processes, advanced techniques, design and performance of smart fabrics • Fundamentals, advancements, current challenges and future perspectives of smart textiles. © 2023 Walter de Gruyter GmbH, Berlin/Boston.

Application prospects of organoids in organ transplantation

In recent years, organoid technology has become one of the major technological breakthroughs in biomedical field. As miniature organs constructed by three-dimensional culture of tissue stem cells in vitro, organoids are highly consistent with the source tissues in terms of tissue structures, cell types and functions, which serve as an ideal model for biomedical basic research, drug research and development and clinical precision medicine, and show important potential value in regenerative medicine. Organ transplantation is one of the most effective approaches to treat organ failure. However, the source of donor organs is currently limited, which could not meet the patients' needs. Identifying suitable graft substitutes is the key to breaking through the predicament. Organoids could be derived from the autologous tissues of patients. Multiple studies have demonstrated that organoids possess potent transplantation and repairing capabilities and may effectively avert the risk of immune rejection and tumorigenicity, etc. In this article, the development process and main application directions of organoid technology were summarized, and the application prospect and challenges of organoids in organ transplantation were reviewed and predicted.Copyright © 2022 Journal of Zhongshan University. All right reserved.

Advances in medical textiles

Medical textile is one of the technical textiles sectors, growing faster due to developments in polymer science and technology and innovation in forming new textile structures. In this review, current market trends for the growth of medical textiles for both pre and post covid pandemic periods were discussed. Focus is given to the classification of medical textiles and devices, specific requirements of fibers and widely used types of fibers, and advanced developments in this field, including nanofibers, bicomponent fibers, superabsorbent polymers, and conductive materials used in a wide range of advanced medical devices. Various fabric structures (woven/knitted/nonwoven/braided) have been in use in biomedical devices;however, recent 3D shaped structures such as spacer fabrics, and 3D-printed materials have profoundly marked their significance with its ability to adapt to specific needs of the medical community. Smart wearable sensor technologies for monitoring, diagnosis, and treatment are discussed and critically reviewed, enabling the readers to understand the complexity of the nature of interdisciplinary approaches required for developing such complex structures and systems. Antimicrobial agents (synthetic and natural/organic) used in the development of medical textiles mainly wound dressings, advances in antiadhesive textile coatings, and antimicrobial assessments of medical fabrics are critically reviewed. Finally, a case study on 3D printing of complex structures is presented to update modern developments using fine detail resolution (FDR), a selective laser sintering that uses carbon dioxide laser to produce delicate and complex 3D structures suitable for medical applications. It is anticipated that readers will benefit from this critical overview of trends in this sector and the multidisciplinary approaches needed to meet the demands of the ever-growing consumer base. © 2023 Elsevier Ltd. All rights reserved.

Three-Dimensional Printing Process for Musical Instruments: Sound Reflection Properties of Polymeric Materials for Enhanced Acoustical Performance.

Acoustical properties of various materials were analyzed in order to determine their potential for the utilization in the three-dimensional printing process of stringed musical instruments. Polylactic acid (PLA), polyethylene terephthalate with glycol modification (PET-G), and acrylonitrile styrene acrylate (ASA) filaments were studied in terms of sound reflection using the transfer function method. In addition, the surface geometry parameters (Sa, Sq, Sz, and Sdr) were measured, and their relation to the acoustic performance of three-dimensional-printed samples was investigated. It was found that a higher layer height, and thus a faster printing process, does not necessarily mean poor acoustical properties. The proposed methodology also proved to be a relatively easy and rapid way to test the acoustic performance of various materials and the effect of three-dimensional printing parameters to test such a combination at the very beginning of the production process.

Assessment of 3D Printing for Surgical Instrument Manufacturing

Three-dimensional (3D) printing has emerged as a method for rapid prototyping and manufacturing of tools. In low-resource settings or field settings, the ability to perform surgeries is often limited by a lack of surgical instruments. On-demand manufacture of surgical instruments via 3D printing may offer a low-cost, reliable, convenient solution for provision of necessary care, particularly during trauma or emergency situations. The global coronavirus-19 disease pandemic has emphasized the need for rapid manufacturing of surgical instruments at the point of care, as the pandemic has often limited patient access to hospitals, due to measures to minimize the spread of infectious disease. Moreover, the ability to 3D print surgical instruments is a priority for enabling surgery during space missions. Recent progress has been made on 3D printing of commonly used surgical instruments from plastics. Important surgical tools such as forceps, scalpel handles, needle drivers, Army/Navy retractors, and hemostats have all been 3D printed, with typical print times on the order of hours. This paper assesses the current status of 3D printing of surgical instruments. The review will include 3D printing methods, raw materials, design times, print times, sterilization methods, and the types of surgical instruments that have been successfully printed. In addition, the results of mechanical testing and simulated surgical testing of 3D printed surgical instruments will be described. Finally, avenues for future work will be identified, including the need for faster print times, and the necessity for producing more intricate instruments via 3D printing. © 2022, Avestia Publishing. All rights reserved.

Pandemic Makers: How Citizen Groups Mobilized Resources to Meet Local Needs in a Global Health Crisis: ET&P

The enormous scale of suffering, breadth of societal impact, and ongoing uncertainty wrought by the COVID-19 pandemic introduced dynamics seldom examined in the crisis entrepreneurship literature. Previous research indicates that when a crisis causes a failure of public goods, spontaneous citizen ventures often emerge to leverage unique local knowledge to rapidly customize abundant external resources to meet immediate needs. However, as outsiders, emergent citizen groups responding to the dire shortage of personal protective equipment at the onset of COVID-19 lacked local knowledge and legitimacy. In this study, we examine how entrepreneurial citizens mobilized collective resources in attempts to gain acceptance and meet local needs amid the urgency of the pandemic. Through longitudinal case studies of citizen groups connected to makerspaces in four U.S. cities, we study how they adapted to address the resource and legitimacy limitations they encountered. We identify three mechanisms—augmenting, circumventing, and attenuating—that helped transient citizen groups calibrate their resource mobilization based on what they learned over time. We highlight how extreme temporality imposes limits on resourcefulness and legitimation, making it critical for collective entrepreneurs to learn when to work within their limitations rather than try to overcome them.

Overcoming Chip Shortages: Low-Cost Open-Source Parametric 3-D Printable Solderless SOIC to DIP Breakout Adapters

The COVID-19 pandemic exposed the vulnerability of global supply chains of many products. One area that requires improved supply chain resilience and that is of particular importance to electronic designers is the shortage of basic dual in-line package (DIP) electronic components commonly used for prototyping. This anecdotal observation was investigated as a case study of using additive manufacturing to enforce contact between premade, off-the-shelf conductors to allow for electrical continuity between two arbitrary points by examining data relating to the stock quantity of electronic components, extracted from Digi-Key Electronics. This study applies this concept using an open hardware approach for the design, testing, and use of a simple, parametric, 3-D printable invention that allows for small outline integrated circuit (SOIC) components to be used in DIP package circuits (i.e., breadboards, protoboards, etc.). The additive manufacture breakout board (AMBB) design was developed using two different open-source modelers, OpenSCAD and FreeCAD, to provide reliable and consistent electrical contact between the component and the rest of the circuit and was demonstrated with reusable 8-SOIC to DIP breakout adapters. The three-part design was optimized for manufacturing with RepRap-class fused filament 3-D printers, making the AMBB a prime candidate for use in distributed manufacturing models. The AMBB offers increased flexibility during circuit prototyping by allowing arbitrary connections between the component and prototyping interface as well as superior organization through the ability to color-code different component types. The cost of the AMBB is CAD $0.066/unit, which is a 94% saving compared to conventional PCB-based breakout boards. Use of the AMBB device can provide electronics designers with an increased selection of components for through-hole use by more than a factor of seven. Future development of AMBB devices to allow for low-cost conversion between arbitrary package types provides a path towards more accessible and inclusive electronics design as well as faster prototyping and technical innovation.

Customizable Fabrication Process for Flexible Carbon-Based Electrochemical Biosensors

In recent research, 3D printing has become a powerful technique and has been applied in the last few years to carbon-based materials. A new generation of 3D-printed electrodes, more affordable and easier to obtain due to rapid prototyping techniques, has emerged. We propose a customizable fabrication process for flexible (and rigid) carbon-based biosensors, from biosensor design to printable conductive inks. The electrochemical biosensors were obtained on a 50 µm Kapton® (polyimide) substrate and transferred to a 500 µm PDMS substrate, using a 3D-extrusion-based printing method. The main features of our fabrication process consist of short-time customization implementation, fast small-to-medium batch production, ease of electrochemical spectroscopy measurements, and very good resolution for an extrusion-based printing method (100 µm). The sensors were designed for future integration into a smart wound dressing for wound monitoring and other biomedical applications. We increased their sensibility with electro-deposited gold nanoparticles. To assess the biosensors' functionality, we performed surface functionalization with specific anti-N-protein antibodies for SARS-CoV 2 virus, with promising preliminary results.

Rapid Convergence: The Outcomes of Making PPE During a Healthcare Crisis

The U.S. National Institute of Health (NIH) 3D Print Exchange is a public, open-source repository for 3D printable medical device designs with contributions from clinicians, expert-amateur makers, and people from industry and academia. In response to the COVID-19 pandemic, the NIH formed a collection to foster submissions of low-cost, locally manufacturable personal protective equipment (PPE). We evaluated the 623 submissions in this collection to understand: what makers contributed, how they were made, who made them, and key characteristics of their designs. We found an immediate design convergence to manufacturing-focused remixes of a few initial designs affiliated with NIH partners and major for-profit groups. The NIH worked to review safe, effective designs but was overloaded by manufacturing-focused design adaptations. Our work contributes insights into: the outcomes of distributed, community-based medical making;the features that the community accepted as "safe"making;and how platforms can support regulated maker activities in high-risk domains. © 2023 Copyright held by the owner/author(s).

Effect of UV-C Radiation on 3D Printed ABS-PC Polymers.

During the initial stages of the COVID-19 pandemic, healthcare facilities experienced severe shortages of personal protective equipment (PPE) and other medical supplies. Employing 3D printing to rapidly fabricate functional parts and equipment was one of the emergency solutions used to tackle these shortages. Using ultraviolet light in the UV-C band (wavelengths of 200 nm to 280 nm) might prove useful in sterilizing 3D printed parts, enabling their reusability. Most polymers, however, degrade under UV-C radiation, so it becomes necessary to determine what 3D printing materials can withstand the conditions found during medical equipment sterilization with UV-C. This paper analyzes the effect of accelerated aging through prolonged exposure to UV-C on the mechanical properties of parts 3D printed from a polycarbonate and acrylonitrile butadiene styrene polymer (ABS-PC). Samples 3D printed using a material extrusion process (MEX) went through a 24-h UV-C exposure aging cycle and then were tested versus a control group for changes in tensile strength, compressive strength and some selected material creep characteristics. Testing showed minimal mechanical property degradation following the irradiation procedure, with tensile strength being statistically the same for irradiated parts as those in the control group. Irradiated parts showed small losses in stiffness (5.2%) and compressive strength (6.5%). Scanning electron microscopy (SEM) was employed in order to assess if any changes occurred in the material structure.

A versatile 3D printed multi-electrode cell for determination of three COVID-19 biomarkers.

3D-printing has shown an outstanding performance for the production of versatile electrochemical devices. However, there is a lack of studies in the field of 3D-printed miniaturized settings for multiplex biosensing. In this work, we propose a fully 3D-printed micro-volume cell containing six working electrodes (WEs) that operates with 250 µL of sample. A polylactic acid/carbon black conductive filament (PLA/CB) was used to print the WEs and subsequently modified with graphene oxide (GO), to support protein binding. Cyclic voltammetry was employed to investigate the electrochemical behaviour of the novel multi-electrode cell. In the presence of K3[Fe(CN)6], PLA/CB/GO showed adequate peak resolution for subsequent label-free immunosensing. The innovative 3D-printed cell was applied for multiplex voltammetric detection of three COVID-19 biomarkers as a proof-of-concept. The multiple sensors showed a wide linear range with detection limits of 5, 1 and 1 pg mL-1 for N-protein, SRBD-protein, and anti-SRBD, respectively. The sensor performance enabled the selective sequential detection of N protein, SRBD protein, and anti-SRBD at biological levels in saliva and serum. In summary, the miniaturized six-electrode cell presents an alternative for the low-cost and fast production of customizable devices for multi-target sensing with promising application in the development of point-of-care sensors.