scholarly journals The Design-Driven Living Lab: A New Approach to Exploring Solutions to Complex Societal Challenges

2017 ◽  
Vol 7 (1) ◽  
pp. 44-51 ◽  
Author(s):  
Rens Brankaert ◽  
Elke den Ouden
BMC Materials ◽  
2019 ◽  
Vol 1 (1) ◽  
Author(s):  
Pier F. Moretti ◽  
Bartosz A. Grzybowski ◽  
Vasileios Basios ◽  
Elvira Fortunato ◽  
Maria Suarez Diez ◽  
...  

AbstractMaterials are addressed as possible enablers for solutions to many global societal challenges. A foresight exercise has been conducted to identify research paths to design, with a new approach, a generation of materials which can provide multi-functionalities. These material systems have been named “stem”, in analogy to living cells where a base of primitive units can be designed and assembled for self-reacting to external inputs. These materials will embed a concept of “internet in things”, where their processing capacity will enable the systems to interact with the environment and express diverse functionalities. Stem materials do not exist yet, but many clues from different theoretical and experimental results suggest they can be developed, and because living organisms exist. This article aims at launching this new approach and promoting the structuring of a multi-disciplinary community to fill the research gaps.


2021 ◽  
pp. 147612702199270
Author(s):  
Susan Hilbolling ◽  
Fleur Deken ◽  
Hans Berends ◽  
Philipp Tuertscher

Solving complex societal challenges requires innovation processes that involve heterogeneous organizations collaborating for sustained periods of time. These multiparty collaborations are confronted with incongruent temporal structures, creating temporal complexities that hamper joint action. We draw on an in-depth longitudinal field study of a multiparty collaboration in a “living lab” initiative that aimed to develop innovative solutions to enhance a city’s nightlife area’s safety and economic viability. We unpack the process of temporal coordination by identifying three temporal coordination mechanisms that enabled parties to address temporal complexities: leveraging serendipitous alignment, temporary exclusion, and aligning on the future. Whereas, prior research has stressed synchronization as a dominant approach to coordination, rooted in a clock-time orientation, these three mechanisms for temporal coordination are rooted in process-time. With a process-time orientation, temporal coordination becomes inherently partial and transient, meaning that temporal complexities may resurface over time and require re-initiation of joint action, building upon emerging outcomes of previous episodes. We discuss implications for the literature on interorganizational collaboration and temporal coordination.


Info ◽  
2015 ◽  
Vol 17 (4) ◽  
pp. 40-52 ◽  
Author(s):  
Rens Brankaert ◽  
Elke den Ouden ◽  
Aarnout Brombacher

Purpose – The purpose of this paper is to propose a Living Lab protocol to evaluate interventions for people with dementia in context. The number of people with dementia is continuously growing, resulting in all kinds of societal challenges. As there is no cure for the diseases today, there is a need to look at alternative ways to combat these challenges, like the design of suitable interventions. These can support people with dementia to live more independent, with a higher quality of life. The protocol is developed over three Living Lab cases. In this, the authors focus on how to involve people living with dementia and the Living Lab stakeholder network. Design/methodology/approach – Over three Living Lab cases, 26 people with dementia, and their caregivers, participated. In these cases, the authors focussed on three different interventions, namely: a reminder system, a daylight lamp and a mobile interface. Yet, a similar protocol was implemented that was built upon insights from its previous case. Hereby, the authors gathered hands-on insights concerning the design and implementation of a Living Lab protocol. Finally, the authors propose a protocol for those interested in pursuing similar goals. Findings – For the resulting proposal, the authors found that it is important to actively involve the relevant Living Lab stakeholders from the start of the process. Because, first, care stakeholders protect participants as gatekeepers, and have a general interest in the interventions. Second, for industry stakeholders, the in-context Living Lab set-up needs to be aligned with their needs to gather usable insights for their interventions. Finally, the authors propose to keep the users engaged beyond the studies by facilitating a Living Lab community. This leads to a higher user engagement and a wider pool to select from for future Living Lab sessions. Research limitations/implications – However, the authors have to be careful to base conclusions on this protocol, due to the limited number of participants and, therefore, the authors suggest this is investigated further. Additionally, the authors feel the role of stakeholders, and who is in the lead, should be investigated further. Practical implications – By reflecting on three Living Lab cases, the authors propose a ready-to-use Living Lab protocol that can be applied by anybody who is interested to design more suitable interventions for impaired users. Social implications – The building of a community as a basis of a Living Lab provides opportunities for all relevant stakeholders, and could reach beyond the development of interventions. Originality/value – The paper provides hands-on insights on applying and developing a Living Lab protocol. This is done by structurally involving relevant stakeholders, while continuously adapting to the user’s needs. Only by continuing to do so, the societal challenges can successfully be addressed.


Author(s):  
Ryan Plummer ◽  
Samantha Witkowski ◽  
Amanda Smits ◽  
Gillian Dale

AbstractThe enterprise of sustainability science extends beyond the academy to address pressing environmental issues through collaboration. It coincides with trends in higher education institutions (HEIs) towards an expanded mission for addressing societal challenges as well as greater accountability. In this paper, we aim to establish an instrument for assessing the performance of sustainability science initiatives in HEIs. The performance of three HEI–community partnerships for sustainability science in Ontario, Canada (the Brock-Lincoln Living Lab, the Excellence in Environmental Stewardship Initiative, and Niagara Adapts) were examined using the HEI–Community Partnership Performance Index (HCPPI). Our preliminary results suggest that the HCPPI is a reliable, valid, and easy-to-administer tool for accurately assessing the performance of HEI–community partnerships for sustainability science. Incorporating systemic performance assessments into HEI–community partnerships promotes accountability, transparency, and continuous improvement. It also serves as a vital feedback mechanism by fostering reflection, adaptation, and learning—critical components to sustainability science.


2021 ◽  
Vol 13 (2) ◽  
pp. 614
Author(s):  
Indre Kalinauskaite ◽  
Rens Brankaert ◽  
Yuan Lu ◽  
Tilde Bekker ◽  
Aarnout Brombacher ◽  
...  

Living labs are an extremely attractive open innovation landscape for collaborative research and development activities targeting the complexity of today’s societal challenges. However, although there is plenty of support for collaboration, we still lack clear guidelines to direct transdisciplinary stakeholder networks of academics and practitioners through collaboration processes in the living lab ecosystem. In other words, we lack answers to the question of “how to collaborate?” In the present paper we propose a conceptual framework defining relevant stages to initiate and facilitate transdisciplinary collaboration processes. We base our framework on collaboration challenges described in the literature, specifically the need for stakeholder alignment, as well as challenges experienced in practice, which we report through exploratory case studies. In the proposed conceptual framework, we advocate the application of co-creation methods, both at the level of the living lab (macro) and in projects (meso) within the living lab, in order to define, with all involved parties and stakeholders, the scope and strategy of the living lab and to facilitate stakeholder alignment. Additionally, we integrate an iterative approach and a feedback loop in order to account for the dynamic nature of the collaboration process and to enable reflection and evaluation.


1999 ◽  
Vol 173 ◽  
pp. 185-188
Author(s):  
Gy. Szabó ◽  
K. Sárneczky ◽  
L.L. Kiss

AbstractA widely used tool in studying quasi-monoperiodic processes is the O–C diagram. This paper deals with the application of this diagram in minor planet studies. The main difference between our approach and the classical O–C diagram is that we transform the epoch (=time) dependence into the geocentric longitude domain. We outline a rotation modelling using this modified O–C and illustrate the abilities with detailed error analysis. The primary assumption, that the monotonity and the shape of this diagram is (almost) independent of the geometry of the asteroids is discussed and tested. The monotonity enables an unambiguous distinction between the prograde and retrograde rotation, thus the four-fold (or in some cases the two-fold) ambiguities can be avoided. This turned out to be the main advantage of the O–C examination. As an extension to the theoretical work, we present some preliminary results on 1727 Mette based on new CCD observations.


Author(s):  
V. Mizuhira ◽  
Y. Futaesaku

Previously we reported that tannic acid is a very effective fixative for proteins including polypeptides. Especially, in the cross section of microtubules, thirteen submits in A-tubule and eleven in B-tubule could be observed very clearly. An elastic fiber could be demonstrated very clearly, as an electron opaque, homogeneous fiber. However, tannic acid did not penetrate into the deep portion of the tissue-block. So we tried Catechin. This shows almost the same chemical natures as that of proteins, as tannic acid. Moreover, we thought that catechin should have two active-reaction sites, one is phenol,and the other is catechole. Catechole site should react with osmium, to make Os- black. Phenol-site should react with peroxidase existing perhydroxide.


Author(s):  
K. Chien ◽  
R. Van de Velde ◽  
I.P. Shintaku ◽  
A.F. Sassoon

Immunoelectron microscopy of neoplastic lymphoma cells is valuable for precise localization of surface antigens and identification of cell types. We have developed a new approach in which the immunohistochemical staining can be evaluated prior to embedding for EM and desired area subsequently selected for ultrathin sectioning.A freshly prepared lymphoma cell suspension is spun onto polylysine hydrobromide- coated glass slides by cytocentrifugation and immediately fixed without air drying in polylysine paraformaldehyde (PLP) fixative. After rinsing in PBS, slides are stained by a 3-step immunoperoxidase method. Cell monolayer is then fixed in buffered 3% glutaraldehyde prior to DAB reaction. After the DAB reaction step, wet monolayers can be examined under LM for presence of brown reaction product and selected monolayers then processed by routine methods for EM and embedded with the Chien Re-embedding Mold. After the polymerization, the epoxy blocks are easily separated from the glass slides by heatingon a 100°C hot plate for 20 seconds.


Sign in / Sign up

Export Citation Format

Share Document