Biomedical research today is not only rigorous, innovative and insightful, it also has to be organized and reproducible. With more capacity to create and store data, there is the challenge of making data discoverable, understandable, and reusable. Many funding agencies and journal publishers are requiring publication of relevant data to promote open science and reproducibility of research.

In order to meet to these requirements and evolving trends, researchers and information professionals will need the data management and curation knowledge and skills to support the access, reuse and preservation of data.

This course is designed to address present and future data management needs.

If you’re a coastal engineer, ecologist or planner, then this is the course for you. You already know that engineering and ecological principles are not enough to realize nature-friendly solutions in practice. You need people on your side!

In this course you will learn how to build a relevant coalition of stakeholders to support the design and implementation of ecosystem-based hydraulic infrastructures. After learning basic stakeholder mapping and game theory techniques, you will apply Social Design Principles to a Building with Nature ecosystem-based design case. This will equip you to identify promising collaborative arrangements for your engineering or planning practice.

The course builds on the previous Building with Nature MOOC, which explored the use of natural materials and ecological processes in achieving effective and sustainable hydraulic infrastructure designs, distilling Engineering and Ecological Design Principles. In this course, the missing element of Social Design Principles are developed and taught.

You’ll learn from renowned Dutch engineers and international environmental scientists, who work at the technical- governance interface. Iconic examples such as the Maasvlakte II expansion to Rotterdam Harbor and the Delfland Sand Engine Mega-nourishment serve as study material. The challenges in designing and implementing these nature-friendly hydraulic infrastructures are explored by the eminent professors who were responsible for their genesis.

Join us in becoming one of the new generation of engineers, ecologists and planners who see the Building with Nature integrated design approach as critical to hydraulic engineering, nature and society.

Proceedings of the 2022 Erasmus Staff Training Week at ULiège Library

Short Description:
No library can buy or hold everything its patrons need. At a certain point, librarians need to pool their resources and collaborate to provide access to what they don't have: Collaboration, interlibrary loan, purchase on demand, PDA and EBA are notably key to success.

Long Description:
No library can buy or hold everything its patrons need. At a certain point, librarians need to pool their resources and collaborate to provide access to what they don’t have: Collaboration and partnership, centralized and shared collection storage, digitization projects, interlibrary loan and resource sharing, purchase on demand, PDA and EBA are notably key to success.

The 2022 edition of the Erasmus Mobility Staff Training week organized at the University of Liège Library focused on services, projects and policies that libraries can deploy and promote to increase and ease access to materials that do not belong to their print or electronic holdings.

More than 20 librarians, managers, and researchers in library science share their experiences and visions in this book.

Word Count: 63148

ISBN: 978-2-87019-313-6 (online); 978-2-87019-314-3 (pdf); 978-2-87019-315-0 (epub)

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

While big data infiltrates all walks of life, most firms have not changed sufficiently to meet the challenges that come with it. In this course, you will learn how to develop a big data strategy, transform your business model and your organization.

This course will enable professionals to take their organization and their own career to the next level, regardless of their background and position.

Professionals will learn how to be in charge of big data instead of being subject to it. In particular, they will become familiar with tools to:

assess their current situation regarding potential big data-induced changes of a disruptive nature,
identify their options for successfully integrating big data in their strategy, business model and organization, or if not possible, how to exit quickly with as little loss as possible, and
strengthen their own position and that of their organization in our digitalized knowledge economy
The course will build on the concepts of product life cycles, the business model canvas, organizational theory and digitalized management jobs (such as Chief Digital Officer or Chief Informatics Officer) to help you find the best way to deal with and benefit from big data induced changes.

Using natural sensory system concepts to develop and improve sensory systems will continue to thrive for many years to come. Technology advances rapidly (Moore’s Law) as does our understanding of biological principles and designs. These trends fuel the fertile grounds of bio-inspired sensory systems, a topic that is inherently multidisciplinary. This book will serve well as either an academic text on the subject or an introduction to the variety of proven bio-inspired designs. The focus is on sensory systems that interpret environmental stimuli. It introduces natural photo-, mechano-, and chemo-sensory systems across the animal kingdom and also summarizes various novel engineering ideas that glean ideas from these natural sensory systems.

This course is offered for graduate students who are interested in the interdisciplinary study of bio-inspired structures. The intent is to introduce students to newly inspired modern advanced structures and their applications. It aims to link traditional advanced composites to bio-inspired structures and to discuss their generic properties. A link between materials design, strength and structural behavior at different levels (material, element, structural and system levels) is made. For each level, various concepts will be introduced. The importance of structural, dynamic, thermodynamic and kinetic theories related to such processing is highlighted. The pedagogy is based on active learning and a balance of guest lectures and hands-on activities.

Biomechatronics is a contraction of biomechanics and mechatronics. In this course the function and coordination of the human motion apparatus is the central focus, and the design of assistive devices for the support of the function of the motion apparatus.

This quick tour provides a brief introduction to EMBL-EBI’s resource of mathematical models of biological/biomedical systems.

By the end of the course you will be able to:
Identify how mathematical models are used in investigating the mechanism underlying biological systems and why do we need them.
Explore the content, features, functionality and use of BioModels
Determine where to find out more about BioModels Database

This quick tour provides a brief introduction to BioSamples data resource, the EMBL-EBI resource that stores and supplies descriptions and metadata about biological samples.

By the end of the course you will be able to:
Describe the role of BioSamples
Navigate the BioSamples website
Describe where to find out more about BioSamples

Have you ever asked what “biobased” means or wondered about the key aspects in developing and commercializing biobased products? This course will answer those questions and more; highlighting the opportunities, hurdles, and driving forces of the bioeconomy.

Today’s industries face enormous global challenges when it comes to the fossil-based economy. Fossil resources are no longer a desirable feedstock for many products and governments’ climate goals put various limitations to its usage. Moreover, consumer perception has become an increasingly important factor. With biobased products as an alternative to the fossil-based economy, the bioeconomy can provide viable solutions to these challenges.

The course describes the different types of biomass, the methods of refinery and typical conversion technologies used for biobased products. You’ll also engage in a study of the practical and real-life examples emerging in the market: biopolymers, bioenergy, bioflavours, and biosurfactants.

The course has been developed by a team of experts from seven different institutions and universities in three different countries, all sharing their personal perspectives on the opportunities and challenges faced by the biobased industry. The three top-ranked institutions Delft University of Technology, RWTH Aachen University, and Wageningen University & Research offer additional, more advanced courses to continue your learning journey:

Industrial Biotechnology: a more advanced course that digs deeper into engineering aspects of bio-based products.
MicroMasters Chemistry and Technology for Sustainability: Help drive the transition from fossil sources to renewable energy ones and engineer a biobased future.
Sustainable Development: The Water-Energy-Food Nexus: Introduction to sustainable development and its relation to the Water-Energy-Food Nexus.

This course focuses on the interaction of chemical engineering, biochemistry, and microbiology. Mathematical representations of microbial systems are featured among lecture topics. Kinetics of growth, death, and metabolism are also covered. Continuous fermentation, agitation, mass transfer, and scale-up in fermentation systems, and enzyme technology round out the subject material.

Short Description:
The aim of this book is to build a bridge between conservation theory and practice. The narrative is focused specifically on Canada. This permits an integrated treatment, where conservation theory is presented in the context of the social and institutional framework responsible for its implementation. Special attention is given to topics that are the subject of debate or controversy, as they provide valuable insight into the practical aspects of conservation. The result is a comprehensive synthesis of applied biodiversity conservation, tailored to the needs of conservation students and practitioners in Canada.

Long Description:
Conservation is often portrayed as an applied science—a body of knowledge about how ecological systems function, how they are threatened, and how they can be maintained. Conservation is also a form of management. It entails working with people to achieve desired ecological outcomes, grappling with conflicting land-use objectives, and making optimal use of available conservation resources. The aim of this book is to build a bridge between these two perspectives, linking theory with practice.

Major topic areas include the history of conservation, the social and scientific foundations of conservation, threats to biodiversity, applied conservation methods at both the species and ecosystem levels, the accommodation of climate change, and structured decision making. Special attention is given to topics that are the subject of debate or controversy, as they provide valuable insight into the practical aspects of conservation. The narrative is focused specifically on Canada. This permits an integrated treatment, where conservation theory is presented in the context of the social and institutional framework responsible for its implementation. The result is a comprehensive synthesis of applied conservation, tailored to the needs of conservation students and practitioners in Canada. Learning is supported by an engaging and clear writing style and 196 colour illustrations.

Word Count: 160462

ISBN: 978-1-55195-494-3

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

Each term, the class selects a new set of professional journal articles on bioengineering topics of current research interest. Some papers are chosen because of particular content, others are selected because they illustrate important points of methodology. Each week, one student leads the discussion, evaluating the strengths, weaknesses, and importance of each paper. Subject may be repeated for credit a maximum of four terms. Letter grade given in the last term applies to all accumulated units of 16.459.

This course does not seek to provide answers to ethical questions. Instead, the course hopes to teach students two things. First, how do you recognize ethical or moral problems in science and medicine? When something does not feel right (whether cloning, or failing to clone) — what exactly is the nature of the discomfort? What kind of tensions and conflicts exist within biomedicine? Second, how can you think productively about ethical and moral problems? What processes create them? Why do people disagree about them? How can an understanding of philosophy or history help resolve them? By the end of the course students will hopefully have sophisticated and nuanced ideas about problems in bioethics, even if they do not have comfortable answers.

Long Description:
The Biographical Dictionary of the History of Paleoanthropology is an ongoing digital humanities project by Dr. Matthew Goodrum, a historian of science who teaches in the Department of Science, Technology, and Society at Virginia Tech. The work contains biographies of individual paleoanthropologists, especially those for whom little information exists in English. They are organized in alphabetical order. Each biography is subject to revision as new information comes to light, and new biographies will be added over time.

Word Count: 92962

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

This interdisciplinary course provides a hands-on approach to students in the topics of bioinformatics and proteomics. Lectures and labs cover sequence analysis, microarray expression analysis, Bayesian methods, control theory, scale-free networks, and biotechnology applications. Designed for those with a computational and/or engineering background, it will include current real-world examples, actual implementations, and engineering design issues. Where applicable, engineering issues from signal processing, network theory, machine learning, robotics and other domains will be expounded upon.

What is bioinformatics and where does it fit with bench-based life science research? Find out more about bioinformatics tools and resources that are available and how you can start to apply them in your research.

By the end of the course you will be able to:
Assess the role of bioinformatics in molecular science.
Describe the key features of primary and secondary databases.
List strategies for describing data consistently.
Identify some of the different types of data analysis that can be applied to solving biological problems.

General Microbiology (BIOL 240) Lab Manual, Fall 2019 by Jing Folsom and Elsa Jimenez-Samayoa for Skyline College is adapted from Laboratory Exercises in Microbiology by Peterson & McGlaughlin and Microbiology Laboratory Manual by Nancy Pakpour and is licensed under CC BY-NC-SA 4.0.

This course illustrates how knowledge and principles of biology, biochemistry, and engineering are integrated to create new products for societal benefit. It uses a case study format to examine recently developed products of pharmaceutical and biotechnology industries: how a product evolves from initial idea, through patents, testing, evaluation, production, and marketing. Emphasizes scientific and engineering principles; the responsibility scientists, engineers, and business executives have for the consequences of their technology; and instruction and practice in written and oral communication.
The topic focus of this class will vary from year to year. This version looks at inflammation underlying many diseases, specifically its role in cancer, diabetes, and cardiovascular disease.