No abstract
Virtual Reality (VR) is a popular technology to recreate reality-like scenarios, including dangerous ones, in a realistic but safe way. Because of this potential, VR based research has been applied in psychology studies to provide training and education about how to behave in emergencies such as fires, earthquakes, floods, or typhoons. All these different virtual scenarios have been built to observe how people react to emergencies, what behaviors they adopted, what level of stress is generated, and finally, how to increase citizens' safety. However, there is still little research that shows how Virtual Environment (VE) should be designed to convey appropriate social and psychological “cues” to participants. In this work, we present the result of a series of co-design sessions aiming to bring experts to collaborate in setting up virtual scenarios to increase the quality of life, safety perception, and risk awareness in people living in the proximity of a river. Floods are one of the most threatening climate events, and because of climate change, they are expected to become even more frequent. These disasters have a devastating impact on communities, increasing anxiety and stress levels in citizens living close to rivers. We involved relevant stakeholders to design “Safer Water,” an immersive, interactive, virtual experience to support citizens in psychologically and behaviorally managing pre and post riverbank breakdown situations. HCI experts, hydrogeological and hydraulic engineers, psychologists, and VEs designers took part in affinity diagram and brainstorming activities. Results show how the adopted method was able to generate suitable virtual scenarios, to highlight and classify relevant design requirements, and to find strategies that could improve the quality of life and psychological well-being in “risk-exposed citizens.” The discussion includes a set of open-access guidelines derived from the co-design activities, to support the design of VE for the purposes discussed in the paper.
Physical inactivity is a plague for public health, especially in Western Countries. Among the countermeasures, mobile applications promoting physical activity seem particularly promising, thanks to the spread and adoption of mobile devices. However, the dropout rates of users are high, thereby calling for strategies to increase retention rates. Moreover, user testing can be problematic, because it is typically conducted in a laboratory, leading to a limited ecological validity. In the present research, we developed a custom mobile app to promote physical activity. Three versions of the app were implemented, each featuring a different pattern of gamification elements. Moreover, the app was designed to work as a self-managed experimental platform. A remote field study was conducted to investigate the effectiveness of the different versions of the app. Behavioral log data of physical activity and interaction with the app were collected. Our results show the feasibility of using a mobile app running on personal devices as an independently managed experimental platform. Moreover, we found that gamification elements per se do not ensure higher retention rates, rather it emerged that the richer combination of gamified elements was effective.
There has been a fast progress in clinical use of antibody-based immunotherapy, given the superior efficacy commonly achieved in clinic and the limited toxicity. However, personalization of treatment remains of major importance, both to achieve better clinical performance for monotherapy and to identify the best combinations on a patient-by-patient basis. Predicting patient's response is complex due to the need to characterize both tumor response and immunologic mechanisms possibly activated by the therapy, including antibody dependent cellular cytotoxicity (ADCC). We present the Inter-Cell Networking Profiling (ICNP), a novel analytical method enabling a comprehensive and precise characterization of the modulatory effect of immunotherapies on immune-tumor cell interactions. ICNP works on the Open Microwell (OMW) microfluidic system which recreates 20,000 unique cell clusters from ex-vivo patient samples and exposes them to anticancer drugs. We validated the ICNP using multiple myeloma (MM) patient samples to characterize the efficacy of Daratumumab, an anti-CD38 antibody (Ab). Bone marrow samples in EDTA were collected from 11 MM patients. 8 samples were processed by Ficoll-Paque, preserving the original composition of effector (E) and target (T) cells, i.e. NK and plasma cells respectively. 3 samples were processed to obtain co-cultures of WBC depleted of plasma cells (which include NK cells) and U-266 MM cell line. NK and plasma cells were stained with anti-CD16/CD56 and anti-CD138 fluorescently-labeled Abs, respectively. Propidium Iodide (PI) was used as death marker. A statistical model was created to project the optimal experimental setup (E:T ratio, cell concentration) to maximize the co-localization of E/T cells in the 20,000 microwells of the OMW platform. After seeding, cells were incubated with Daratumumab 10µg/mL or no drug and analyzed through fluorescence time lapse microscopy for up to 12 hours. ICNP analysis first separates microwells with both E/T cells in close proximity from those not featuring both cell types (Fig 1A). Then, anti-CD38 efficacy is evaluated in microwells with E/T co-localization, thus implementing a miniaturized ADCC assay (Fig 1B). At the same time, spontaneous NK activity is measured in microwells with E/T co-localization and no drug, while direct effect of the drug on target cells can be measured in microwells with T but not E cells. We first validated our statistical model of co-localization in microwells against the actual number of wells with E/T co-localization (correlation R2: 0.79-0.97, n=5). Then, we characterized the immune composition of 8 MM patients samples with the OMW, finding that E/T cell fractions were in the ranges 5-21% (E) and 1-28% (T). Interestingly, according to our statistical model, co-localization occurs in at least 1% of microwells for all the 8 samples, making ICNP applicable with good statistical significance in the OMW system on ex-vivo clinical samples without any pre-enrichment. Finally, ICNP was evaluated on 4 cases (3 obtained by mixing patient's WBC with U-266 MM cell line and 1 complete MM patient sample). We measured the effect of anti-CD38 Ab using i) the standard approach, considering all microwells regardless of the co-presence of E and T; ii) ICNP approach, considering only microwells featuring E/T co-localization. Results show that drug effect is much evident with ICNP in all the 4 cases with an average increase in target cell death of 40%, indicating a higher sensitivity of this approach than the averaged analysis (Fig 1C, right). Importantly, in one case, the standard analysis did not identify significant differences between anti-CD38 treated and control cells, that could instead be observed with ICNP (p<0.0001, 89% cell death) (Fig 1C, left). These results demonstrate that ICNP can determine the efficacy of the therapy taking into account the fitness of single NK cells that is commonly lost in averaged measurements. ICNP proved to enable a comprehensive profiling of the immune system by evaluating in one test the immune composition and the fitness of immune cells, both native and drug-treated. These results open the opportunity to develop functional precision medicine approaches for predicting patient's response to drugs with immune-mediated mechanisms of action. AB and RR equally contributed Figure 1 Disclosures Bettelli: CellPly.S.r.l.: Employment. Ruggiano:Cellply S.r.l.: Employment. Bocchi:CellPly S.r.l.: Employment. Rocchi:CellPly.S.r.l.: Employment. Faenza:CellPly S.r.l.: Employment. Zamagni:Janssen: Honoraria, Other: Advisory board, Speakers Bureau; Amgen: Honoraria, Other: Advisory board, Speakers Bureau; BMS: Honoraria, Other: Advisory Board, Speakers Bureau; Takeda: Honoraria, Speakers Bureau; Sanofi: Honoraria, Other: Advisory Board, Speakers Bureau; Celgene Corporation: Honoraria, Other: Advisory board, Speakers Bureau. Bettelli:CellPly S.r.l.: Employment. Rambelli:CellPly S.r.l.: Employment. Guadagnuolo:CellPly S.r.l.: Employment. Pecorari:CellPly S.r.l.: Employment. Giulianelli:CellPly S.r.l.: Employment. Pisani:CellPly S.r.l.: Employment. Biscarini:CellPly S.r.l.: Employment. Cavo:amgen: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; bms: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; celgene: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees, Other: travel accommodations, Speakers Bureau; sanofi: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; novartis: Honoraria; takeda: Honoraria, Membership on an entity's Board of Directors or advisory committees, Speakers Bureau; janssen: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees, Other: travel accommodations, Speakers Bureau; AbbVie: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees. Guerrieri:CellPly S.r.l.: Equity Ownership. Bocchi:CellPly S.r.l.: Equity Ownership, Membership on an entity's Board of Directors or advisory committees.
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