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Female, Humans, Pilot Projects, Endoscopes, Fallopian Tubes, Ovarian Neoplasms diagnostic imaging, and Ovarian Neoplasms pathology

Significance: High grade serous ovarian cancer is the most deadly gynecological cancer, and it is now believed that most cases originate in the fallopian tubes (FTs). Early detection of ovarian cancer could double the 5-year survival rate compared with late-stage diagnosis. Autofluorescence imaging can detect serous-origin precancerous and cancerous lesions in ex vivo FT and ovaries with good sensitivity and specificity. Multispectral fluorescence imaging (MFI) can differentiate healthy, benign, and malignant ovarian and FT tissues. Optical coherence tomography (OCT) reveals subsurface microstructural information and can distinguish normal and cancerous structure in ovaries and FTs.
Aim: We developed an FT endoscope, the falloposcope, as a method for detecting ovarian cancer with MFI and OCT. The falloposcope clinical prototype was tested in a pilot study with 12 volunteers to date to evaluate the safety and feasibility of FT imaging prior to standard of care salpingectomy in normal-risk volunteers. In this manuscript, we describe the multiple modifications made to the falloposcope to enhance robustness, usability, and image quality based on lessons learned in the clinical setting.
Approach: The ∼ 0.8    mm diameter falloposcope was introduced via a minimally invasive approach through a commercially available hysteroscope and introducing a catheter. A navigation video, MFI, and OCT of human FTs were obtained. Feedback from stakeholders on image quality and procedural difficulty was obtained.
Results: The falloposcope successfully obtained images in vivo . Considerable feedback was obtained, motivating iterative improvements, including accommodating the operating room environment, modifying the hysteroscope accessories, decreasing endoscope fragility and fiber breaks, optimizing software, improving fiber bundle images, decreasing gradient-index lens stray light, optimizing the proximal imaging system, and improving the illumination.
Conclusions: The initial clinical prototype falloposcope was able to image the FTs, and iterative prototyping has increased its robustness, functionality, and ease of use for future trials.
(© 2023 The Authors.)

Carrageenan pharmacology, Carrageenan chemistry, Wound Healing, Biocompatible Materials chemistry, Hydrogels pharmacology, Hydrogels chemistry, Gelatin pharmacology, and Gelatin chemistry

Injectable hydrogels based on natural polymers have shown great potential for various tissue engineering applications, such as wound healing. However, poor mechanical properties and weak self-healing ability are still major challenges. In this work, we introduce a host-guest (HG) supramolecular interaction between acrylate-β-cyclodextrin (Ac-β-CD) conjugated on methacrylated kappa-carrageenan (MA-κ-CA) and aromatic residues on gelatin to provide self-healing characteristics. We synthesize an MA-κ-CA to conjugate Ac-β-CD and fabricate dual crosslinked hybrid hydrogels with gelatin to mimic the native extracellular matrix (ECM). The dual crosslinking occurs on the MA-κ-CA backbone through the addition of KCl and photocrosslinking process, which enhances mechanical strength and stability. The hybrid hydrogels exhibit shear-thinning, self-healing, and injectable behavior, which apply easily under a minimally invasive manner and contribute to shear stress during the injection. In-vitro studies indicate enhanced cell viability. Furthermore, scratch assays are performed to examine cell migration and cell-cell interaction. It is envisioned that the combination of self-healing and injectable dual crosslinked hybrid hydrogels with HG interactions display a promising and functional biomaterial platform for wound healing applications.
(© 2023 Wiley Periodicals LLC.)

Synthetic Biology, Biotechnology, Bioengineering, Microalgae genetics, Microalgae metabolism, and Biosensing Techniques

Biosensors are powerful tools to investigate, phenotype, improve and prototype microbial strains, both in fundamental research and in industrial contexts. Genetic and biotechnological developments now allow the implementation of synthetic biology approaches to novel different classes of microbial hosts, for example photosynthetic microalgae, which offer unique opportunities. To date, biosensors have not yet been implemented in phototrophic eukaryotic microorganisms, leaving great potential for novel biological and technological advancements untapped. Here, starting from selected biosensor technologies that have successfully been implemented in heterotrophic organisms, we project and define a roadmap on how these could be applied to microalgae research. We highlight novel opportunities for the development of new biosensors, identify critical challenges, and finally provide a perspective on the impact of their eventual implementation to tackle research questions and bioengineering strategies. From studying metabolism at the single-cell level to genome-wide screen approaches, and assisted laboratory evolution experiments, biosensors will greatly impact the pace of progress in understanding and engineering microalgal metabolism. We envision how this could further advance the possibilities for unraveling their ecological role, evolutionary history and accelerate their domestication, to further drive them as resource-efficient production hosts.
Competing Interests: Declaration of Competing Interest The authors declare no conflicts of interest.
(Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Water Quality

An implementation proposal that seeks to globalize the scope of the sustainable technologies developed in the University laboratories is presented. This approach uses the generation of triple-impact projects placing people at the center of technological development to bring technical and scientific knowledge into a service design oriented to global sustainable solutions. This research is an approach to what a hub for scientific research, technological implementation, and human needs would look like by designing common environments in which to interact and expand knowledge in an iterated way through the experience of all the actors involved in technological implementation. As a control case, a new technology developed at the Universidad de Buenos Aires, consisting of using sustainable materials as tubular reactor fillers for water treatment was chosen. Based on data obtained within the framework of a University extension project, in which the water quality diagnosis for human consumption was carried out and cross-examined with the mathematical analysis of sorption, design parameters of the reactor, participatory design, and open source concepts application, different virtual environments were generated with distinct objectives: i) open design environment: publishing and mapping of installed sorption reactors, reactor model plans, and useful information related to drinking water quality (aimed at contributors of the open source design environment); ii) platform for academic actors linking: connecting data between prototyping lab for participatory design of sorption reactors (aimed at university research users); iii) information disclosure page: space where the implemented technology impact is displayed and shows options to contact researchers and request a reactor design diagnosis for another community (aimed at beneficiary users). A technological service designed to link the University with the community was proposed, by resolving one of the main gaps related to the possibility for communities to access public financing for self-managed improvement projects, increasing the appropriation of the adopted technology and democratizing public investment, making it sustainable over time.
Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
(Copyright © 2023 Elsevier Ltd. All rights reserved.)

Objective: Design thinking is a creative problem-solving process used to better understand users' needs and experiences so that a product or service can be improved. Its emphasis on empathy, iterative prototyping, and participatory collaboration make it an ideal methodology for innovation in medical education. We apply this framework to the virtual rheumatology fellowship interview process so that interviews can become more applicant centered.
Methods: This educational quality improvement project uses a design-thinking framework to identify opportunities and challenges for rheumatology fellowship applicants. The investigators use the 5-step process (Empathize, Define, Ideate, Prototype, Test) and incorporate rapid qualitative analysis of semistructured interviews to innovate the interview experience. The iterative and collaborative nature of this process has empowered participants to codesign an applicant-centered interview experience.
Results: Interviews with fellowship applicants (n = 9), fellow physicians (n = 4), and faculty members (n = 3) identified three major dynamics of the interview process: (1) Is it a safe environment to ask questions? (2) How do I exchange information effectively? and (3) How do I fit all these data into the bigger picture? Creative brainstorming techniques at a series of three workshops yielded four prototypes emphasizing customization, hybridization, facilitation, and preparation. A finalized applicant-centered interview template was devised in preparation for the 2023-2024 application season.
Conclusion: Design thinking has yielded insights into three important dynamics that drive applicant experiences. These insights allow for a redesign of processes so that virtual interviews can be more applicant centered. This framework allows for further iterations and modifications as the needs of applicants and programs evolve over time.
(© 2023 The Authors. ACR Open Rheumatology published by Wiley Periodicals LLC on behalf of American College of Rheumatology.)

Introduction: Additive manufacturing is a tool with potential use in medicine and dentistry. The manufacture of metals and composites is already advanced, however, concerns about titanium hypersensitivity, tissue staining, and corrosion caused by gradual material degradation encourage research into more biocompatible alternatives.
Objective: This systematic scoping review aimed to gather studies that evaluated zirconia implants produced by additive manufacturing to describe the current stage of the printing technique and the final product.
Methods: Searches in Embase, PubMed, SCOPUS, Web of Science, and Google Scholar databases were enriched with manual searches between February and March 2021 and updated in June 2022 using keywords: zirconium implants, zirconium oxide, additive manufacturing, rapid prototyping, 3D printing, selective laser melting, and electron beam melting. The criteria included studies that evaluated or described zirconia implants obtained by 3D printing, with a direct relationship to dentistry or orthopedics.
Results: The database search resulted in 671 articles. Eight articles were selected for full reading and remained in this systematic review.
Conclusion: The printing technique for zirconia implants is promising. However, further studies are required before implants produced by the printing technique can be tested clinically. The literature with results regarding the impression product is still limited.
(Copyright© 2023 Dennis Barber Ltd.)

Magnetically hard materials are widely used to build soft magnetic robots, providing large magnetic force/torque and macrodomain programmability. However, their high magnetic coercivity often presents practical challenges when attempting to reconfigure magnetization patterns, requiring a large magnetic field or heating. In this study, we introduce magnetic putty as a magnetically hard and soft material with large remanence and low coercivity. We show that the magnetization of magnetic putty can be easily reoriented with maximum magnitude using an external field that is only one tenth of its coercivity. Additionally, magnetic putty is a malleable, autonomous self-healing material that can be recycled and repurposed. We anticipate magnetic putty could provide a versatile and accessible tool to various magnetic robotics applications for fast prototyping and explorations for research and educational purposes. This article is protected by copyright. All rights reserved.
(This article is protected by copyright. All rights reserved.)

In a world grappling with environmental challenges and the need for sustainable manufacturing practices, the convergence of 3D printing and recycling emerges as a promising solution. This research paper explores the potential of combining these two technologies and comprehensively analyses their synergistic effects. The study delves into the printability of recycled materials, evaluating their suitability for 3D printing and comparing their performance with conventional materials. The environmental impact of 3D printing with recycled materials is examined through a sustainability analysis and a life cycle assessment of recycled 3D printed objects. The findings reveal significant benefits, including enhanced resource efficiency, waste reduction, and customisation possibilities. The research also identifies challenges and opportunities for scaling up the use of recycled materials in 3D printing, highlighting the importance of collaboration, innovation, and regulations. With potential applications spanning various industries, from prototyping to construction and healthcare, the implications of this research are far-reaching. By embracing sustainable practices, industry collaboration, and innovation, the integration of 3D printing and recycling can pave the way for a more sustainable future, where resource conservation, circularity, and customised production are at the forefront of manufacturing.
(Copyright © 2023. Published by Elsevier B.V.)

Background: Increased levels of physical activity are associated with beneficial health effects for people with type 2 diabetes, cardiovascular disease and/or severe obesity; however, transforming knowledge about these effects into action is challenging. The aim of this paper is to explore lessons learnt from a co-creation process in a partnership project involving local stakeholders, including citizens, and researchers. The purpose of the process was to link a public health care institution with civil society organisations in the local community to make it possible for citizens to continue to be physically active after ending their public rehabilitation. Secondarily, this paper aims to develop a conceptual model of the above process.
Methods: The study constitutes the first part of Project Active Communities and was based on a partnership between three research institutions and a Danish rural municipality, involving municipal and civil society stakeholders and citizens with type 2 diabetes, cardiovascular disease and/or severe obesity in co-creation of concrete interventions for implementation. The co-creation process was divided into two tracks, one involving citizens (two workshops) and one involving municipal and civil society stakeholders (two workshops). The two tracks were concluded with a final workshop involving all stakeholders, including local politicians. Data sources are focus groups and bilateral meetings, workshop observations, and questionnaires.
Results: Lessons learnt include the importance of having a flexible timeframe for the co-creation process; giving room for disagreements and matching of mutual expectations between stakeholders; the value of a coordinator in the municipality to achieve acceptance of the project; and the significance of engaging local politicians in the co-creation process to accommodate internal political agendas. We have developed a conceptual model for a co-creation process, where we outline and explain three distinct phases: stakeholder identification and description, co-creation, and prototyping. The model can be adapted and applied to other sectors and settings.
Conclusions: This study documents lessons learnt in a co-creation process aiming to link a public health care institution with civil society organisations in the local community. Further, this study has specified productive co-creative processes and documented the various phases in a conceptual model.
(© 2023. BioMed Central Ltd., part of Springer Nature.)