The aim of the current study was to evaluate the one- and two-year effectiveness of the KEIGAAF intervention, a school-based mutual adaptation intervention, on the BMI z-score (primary outcome), and energy balance-related behaviors (secondary outcomes) of children aged 7–10 years. A quasi-experimental study was conducted including eight intervention schools and three control schools located in low socioeconomic neighborhoods in the Netherlands. Baseline measurements were conducted in March and April 2017 and repeated after one and 2 years. Data were collected on children’s BMI z-score, sedentary behavior (SB), physical activity (PA) behavior, and nutrition behavior through the use of anthropometric measurements, accelerometers, and questionnaires, respectively. All data were supplemented with demographics, and weather conditions data was added to the PA data. Based on the comprehensiveness of implemented physical activities, intervention schools were divided into schools having a comprehensive PA approach and schools having a less comprehensive approach. Intervention effects on continuous outcomes were analyzed using multiple linear mixed models and on binary outcome measures using generalized estimating equations. Intervention and control schools were compared, as well as comprehensive PA schools, less comprehensive PA schools, and control schools. Effect sizes (Cohen’s d) were calculated. In total, 523 children participated. Children were on average 8.5 years old and 54% were girls. After 2 years, intervention children’s BMI z-score decreased (B = -0.05, 95% CI -0.11;0.01) significantly compared to the control group (B = 0.20, 95% CI 0.09;0.31). Additionally, the intervention prevented an age-related decline in moderate-to-vigorous PA (MVPA) (%MVPA: B = 0.95, 95% CI 0.13;1.76). Negative intervention effects were seen on sugar-sweetened beverages and water consumption at school, due to larger favorable changes in the control group compared to the intervention group. After 2 years, the comprehensive PA schools showed more favorable effects on BMI z-score, SB, and MVPA compared to the other two conditions. This study shows that the KEIGAAF intervention is effective in improving children’s MVPA during school days and BMI z-score, especially in vulnerable children. Additionally, we advocate the implementation of a comprehensive approach to promote a healthy weight status, to stimulate children’s PA levels, and to prevent children from spending excessive time on sedentary behaviors.
BACKGROUND:The Systematic COronary Risk Evaluation - Older Persons (SCORE-OP) algorithm is developed to assess 10-year risk of death due to cardiovascular disease (CVD) in individuals aged ≥65 years. We studied the performance of SCORE-OP in the European Prospective Investigation of Cancer Norfolk (EPIC-Norfolk) prospective population cohort.METHODS:10-year CVD mortality as predicted by SCORE-OP was compared with observed CVD mortality among individuals in the EPIC-Norfolk cohort. Persons aged 65-79 years without known CVD were included in the analysis. CVD mortality was defined as death due to ischemic heart disease, cardiac failure, cerebrovascular disease, peripheral-artery disease or aortic aneurysm. Predicted 10-year CVD mortality was calculated by the SCORE-OP algorithm, and compared to observed mortality rates. The area under the receiver operator characteristics curve (AUROC) was calculated to evaluate discriminative power. Calibration was evaluated by calculating ratios of predicted vs observed mortality and by Hosmer-Lemeshow tests.RESULTS:A total of 6590 individuals (45.8% men), mean age 70.2 years (standard deviation 3.3) were included. The predicted mortality by SCORE-OP was 9.84% (95% confidence interval (CI) 9.76-9.92) and observed mortality was 10.2% (95% CI 9.52-11.04), ratio 0.96. AUROC was 0.63 (95% CI 0.60-0.65), and X2 was 3.3 (p = 0.92).CONCLUSION:SCORE-OP overall accurately estimates the rate of CVD mortality in a general population aged 65-79 years. However, while calibration is excellent, the discriminative power of the SCORE-OP is limited, and as such cannot be readily implemented in clinical practice for this population.
Patiëntdata uit vragenlijsten, fysieke testen en ‘wearables’ hebben veel potentie om fysiotherapie-behandelingen te personaliseren (zogeheten ‘datagedragen’ zorg) en gedeelde besluitvorming tussen fysiotherapeut en patiënt te faciliteren. Hiermee kan fysiotherapie mogelijk doelmatiger en effectiever worden. Veel fysiotherapeuten en hun patiënten zien echter nauwelijks meerwaarde in het verzamelen van patiëntdata, maar vooral toegenomen administratieve last. In de bestaande landelijke databases krijgen fysiotherapeuten en hun patiënten de door hen zelf verzamelde patiëntdata via een online dashboard weliswaar teruggekoppeld, maar op een weinig betekenisvolle manier doordat het dashboard primair gericht is op wensen van externe partijen (zoals zorgverzekeraars). Door gebruik te maken van technologische innovaties zoals gepersonaliseerde datavisualisaties op basis van geavanceerde data science analyses kunnen patiëntdata betekenisvoller teruggekoppeld en ingezet worden. Wij zetten technologie dus in om ‘datagedragen’, gepersonaliseerde zorg, in dit geval binnen de fysiotherapie, een stap dichterbij te brengen. De kennis opgedaan in de project is tevens relevant voor andere zorgberoepen. In dit KIEM-project worden eerst wensen van eindgebruikers, bestaande succesvolle datavisualisaties en de hiervoor vereiste data science analyses geïnventariseerd (werkpakket 1: inventarisatie). Op basis hiervan worden meerdere prototypes van inzichtelijke datavisualisaties ontwikkeld (bijvoorbeeld visualisatie van patiëntscores in vergelijking met (beoogde) normscores, of van voorspelling van verwacht herstel op basis van data van vergelijkbare eerdere patiënten). Middels focusgroepinterviews met fysiotherapeuten en patiënten worden hieruit de meest kansrijke (maximaal 5) prototypes geselecteerd. Voor deze geselecteerde prototypes worden vervolgens de vereiste data-analyses ontwikkeld die de datavisualisaties op de dashboards van de landelijke databases mogelijk maken (werkpakket 2: prototypes en data-analyses). In kleine pilots worden deze datavisualisaties door eindgebruikers toegepast in de praktijk om te bepalen of ze daadwerkelijk aan hun wensen voldoen (werkpakket 3: pilots). Uit dit 1-jarige project kan een groot vervolgonderzoek ‘ontkiemen’ naar het effect van betekenisvolle datavisualisaties op de uitkomsten van zorg.
Nowadays, there is particular attention towards the additive manufacturing of medical devices and instruments. This is because of the unique capability of 3D printing technologies for designing and fabricating complex products like bone implants that can be highly customized for individual patients. NiTi shape memory alloys have gained significant attention in various medical applications due to their exceptional superelastic and shape memory properties, allowing them to recover their original shape after deformation. The integration of additive manufacturing technology has revolutionized the design possibilities for NiTi alloys, enabling the fabrication of intricately designed medical devices with precise geometries and tailored functionalities. The AM-SMART project is focused on exploring the suitability of NiTi architected structures for bone implants fabricated using laser powder bed fusion (LPBF) technology. This is because of the lower stiffness of NiTi alloys compared to Ti alloys, closely aligning with the stiffness of bone. Additionally, their unique functional performance enables them to dissipate energy and recover the original shape, presenting another advantage that makes them well-suited for bone implants. In this investigation, various NiTi-based architected structures will be developed, featuring diverse cellular designs, and their long-term thermo-mechanical performance will be thoroughly evaluated. The findings of this study underscore the significant potential of these structures for application as bone implants, showcasing their adaptability for use also beyond the medical sector.
Digital innovations in the field of immersive Augmented Reality (AR) can be a solution to offer adults who are mentally, physically or financially unable to attend sporting events such as premier league football a stadium and match experience. This allows them to continue to connect with their social networks. In the intended project, AR content will be further developed with the aim of evoking the stadium experience of home matches as much as possible. The extent to which AR enriches the experience is then tested in an experiment, in which the experience of a football match with and without AR enrichment is measured in a stadium setting and in a home setting. The experience is measured with physiological signals. In addition, a subjective experience measure is also being developed and benchmarked (the experience impact score). Societal issueInclusion and health: The joint experience of (top) sports competitions forms a platform for vulnerable adults, with a limited social capital, to build up and maintain the social networks that are so necessary for them. AR to fight against social isolation and loneliness.
