Your search keyword '"Forta, Ng"' showing total 7 results

1. Measures of internal lumbar load in professional drivers – dependence on posture, anthropometry, age, duration of exposure and type of machine

Author

Schust, M, Menzel, G, Hofmann, J, Forta, Ng, Pinto, I, Hinz, B, Bovenzi, Massimo, AMC, Schust, M, Menzel, G, Hofmann, J, Forta, Ng, Pinto, I, Hinz, B, and Bovenzi, Massimo

Subjects

finite element model, risk factor, professional driver, professional drivers, internal spinal forces, daily compressive dose, internal spinal force

Abstract

Introduction In European and International Standards and Directives, external loads in terms of daily vibration exposure A(8) or vibration dose value VDV are used as predictors of adverse health effects. These values only partly reflect the internal load acting on the lumbar spine. Particularly for shock containing acceleration time histories, a method for the calculation of internal spinal forces on the basis of a Finite-Element-Model (FEM) was developed within the EU VIBRISKS project [1]. The model can be adapted to the anthropometry (ten categories) and the sitting posture (six categories) of the driver. The method has been proposed in a working draft of the Standardisation Committee ISO/TC 108/SC 4/WG 15 [2]. It has already been standardised in the German Standard DIN SPEC 45697 [3]. The risk assessment is based on the daily compressive dose Sed (MPa) and the risk factor R (non-dimensional). Both values are determined by the compressive internal forces, by the daily and lifetime exposure duration and by the age at the start of exposure. For a re-analysis of the Italian part of an epidemiological study performed within the VIBRISKS project, the internal forces, Sed and R were calculated for the 537 participants of the study. Methods Typical acceleration time histories for various machine types and working tasks were selected. Impacts due to sitting down or loosing the contact to the seat were eliminated. At the end, 19 checked time histories with a duration of 200 s were available. All signals were shock containing [4]. Beside the calculation of Sed and R factor, r.m.s., r.m.q. and standard deviation of the time histories of the internal forces were assessed in all three axes separately and as a vector sum. Therefore, a modification of the program published on the CD in DIN SPEC 45697 had to be used, because it was necessary to get the interim results of the calculations in terms of internal forces. In the horizontal axes, the daily doses were calculated without relation to the spinal endplate areas. The daily doses for the internal forces acting in anterior and posterior directions were separately computed. In total, 21 different variables were calculated. Results The values of the forces, Sed and R factor varied over the lumbar spine levels from T12/L1 to L5/S1. The shapes of the spine-level dependent curves were determined by the posture and the type of machine (example for posture group1 in Fig. 1). The category of body mass and Body Mass Index (BMI) and the posture - in association with the covariates listed in Table 1 - significantly influenced the maximum R factor (statistical test: ANCOVA). The interaction between the body mass/BMI-category and the posture was not significant (F=1.3, p=0.11). When several machines in identical sitting posture were used, the type of machine showed a significant effect as well (Table 1, last three lines). In these cases, the effect of the yearly exposure duration was not longer calculated due to a lack of variability of the covariate. Instead of that, the last column of Table 1 contains the interaction between the body mass/BMI-category and the type of machine which was significant for all three postures. The p-value was p

Published

2013

2. Berechnung von Intra-spinalen Kräften und Risikomaßen bei Einwirkung von Ganzkörpervibrationen - Abhängigkeit von Körperhaltung, Körperstatur, Alter, Expositionsdauer und Expositionsmuster am Beispiel von 537 Teilnehmern einer epidemiologischen Studie

Author

Schust, M, Menzel, G, Hofmann, J, Pinto, I, Forta, Ng, Hinz, B, Bovenzi, Massimo, VDI-Berichte, Schust, M, Menzel, G, Hofmann, J, Pinto, I, Forta, Ng, Hinz, B, and Bovenzi, Massimo

Subjects

risk factor, lumbar spine, internal spinal forces, daily compressive dose, ISO 2631-part 5, internal spinal force

Abstract

Mit Hilfe einer Re-Analyse der Daten von 537 Teilnehmern an einer epidemiologischen Studie im EU-Projekt VIBRISKS [1] sollte untersucht werden, inwieweit geschätzte Risiken, die auf mit Modellen vorhergesagten intra-spinalen Kräften beruhen [2], das Risiko für Beschwerden und Schmerzen in der Lendenwirbelsäule widerspiegeln. Sämtliche Vibrationsexpositionen waren nach unterschiedlichen Kriterien stoßhaltig [3]. Im vorliegenden Beitrag werden die Ergebnisse ausgewählter Berechnungen dargestellt. Die Verteilung des Risikos über die Lendenwirbelsäule wurde von der Sitzhaltung und von der Art des Fahrzeugs bestimmt. Die Körpermasse / BMI- Kategorie und die Körperhaltung hatten einen signifikanten Einfluss auf den maximalen Risikofaktor. Darüber hinaus war der Risikofaktor war umso höher, je länger die tägliche und die jährliche Expositionszeit und die Lebensexpositionszeit, und je höher das Lebensalter bei Beginn der Exposition waren. Für einige Haltungen und Fahrzeugtypen erreichten die dynamischen Anteile der intra-spinalen Kräfte in x-Richtung Werte, die mit denen in vertikaler Richtung (Kompressionskräfte) vergleichbar waren, obwohl der A(8)-Wert in x-Richtung nur einen Bruchteil desselben in z-Richtung betrug. Für die Entwicklung eines Schädigungsmodells für die Wirbelsäule auf Basis der horizontalen intra-spinalen Kräfte besteht auch international Forschungsbedarf. Die individuelle Abschätzung des Risikos mit Hilfe der DIN SPEC 45697 hat sich auch für größere Exponiertengruppen als praktikabel erwiesen.

Published

2013

3. Measures of internal lumbar load in professional drivers - the use of a whole-body finite-element model for the evaluation of adverse health effects of multi-axis vibration

Author

Marianne Schust, Jörg Hofmann, G. Menzel, B. Hinz, Iole Pinto, Nazim Gizem Forta, Massimo Bovenzi, Schust, M, Menzel, G, Hofmann, J, Forta, Ng, Pinto, I, Hinz, B, and Bovenzi, Massimo

Subjects

Male, Automobile Driving, Time Factors, Acceleration, Finite Element Analysis, Posture, health risks, Physical Therapy, Sports Therapy and Rehabilitation, Human Factors and Ergonomics, medicine.disease_cause, Risk Assessment, Vibration, Weight-bearing, whole body vibration, biodynamic, lumbar spine, Body Mass Index, Weight-Bearing, Risk Factors, Occupational Exposure, Statistics, Medicine, Whole body vibration, Humans, Risk factor, Simulation, health risk, Lumbar Vertebrae, business.industry, Age Factors, Reproducibility of Results, Models, Theoretical, Spinal column, Biomechanical Phenomena, Cohort, business, Risk assessment, Body mass index, Software

Abstract

The present study aimed to (1) employ the method for evaluation of vibration containing multiple shocks according to ISO/CD 2631-5:2014 (Model 1) and DIN SPEC 45697:2012 in a cohort of 537 professional drivers, (2) deliver the results for a re-analysis of epidemiological data obtained in the VIBRISKS study, (3) clarify the extent to which vibration acceleration and individual variables influence risk values, such as the daily compressive dose S(ed) and the risk factor R, and (4) compare the results with in vivo measurements and those obtained in previous studies with similar models. The risk factor R was influenced by the acceleration, lifetime exposure duration, sitting posture, age at the start of exposure and body mass/body mass index in order of decreasing effect. Age and annual and daily exposure duration had only a marginal effect. The daily compressive dose S(ed) and the risk factor R showed weak linear association with the daily vibration exposure A(8) and the vibration dose value VDV. The study revealed high shear forces in the lumbar spine.In a re-analysis of an epidemiological study of professional drivers, a software tool available with standards DIN SPEC 45697:2012 and ISO/CD 2631–5:2014 Model 1 was used to calculate the risk to the lumbar spine in terms of daily compressive dose S(ed) and risk factor R. The tool was found to be suitable for risk assessment in a large cohort.

Published

2014

4. Perception of fore-and-aft whole-body vibration intensity measured by two methods.

Author

Forta NG and Schust M

Subjects

Adult, Female, Humans, Male, Young Adult, Perception, Posture, Vibration

Abstract

This experimental study investigated the perception of fore-and-aft whole-body vibration intensity using cross-modality matching (CM) and magnitude estimation (ME) methods. Thirteen subjects were seated on a rigid seat without a backrest and exposed to sinusoidal stimuli from 0.8 to 12.5 Hz and 0.4 to 1.6 ms(-2) r.m.s. The Stevens exponents did not significantly depend on vibration frequency or the measurement method. The ME frequency weightings depended significantly on vibration frequency, but the CM weightings did not. Using the CM and ME weightings would result in higher weighted exposures than those calculated using the ISO (2631-1, 1997) Wd. Compared with ISO Wk, the CM and ME-weighted exposures would be greater at 1.6 Hz and lesser above that frequency. The CM and ME frequency weightings based on the median ratings for the reference vibration condition did not differ significantly. The lack of a method effect for weightings and for Stevens exponents suggests that the findings from the two methods are comparable., Practitioner Summary: Frequency weighting curves for seated subjects for x-axis whole-body vibration were derived from an experiment using two different measurement methods and were compared with the Wd and Wk weighting curves in ISO 2631-1 (1997).

Published

2015

5. Measures of internal lumbar load in professional drivers - the use of a whole-body finite-element model for the evaluation of adverse health effects of multi-axis vibration.

Author

Schust M, Menzel G, Hofmann J, Forta NG, Pinto I, Hinz B, and Bovenzi M

Subjects

Acceleration adverse effects, Age Factors, Biomechanical Phenomena, Body Mass Index, Finite Element Analysis, Humans, Male, Models, Theoretical, Occupational Exposure adverse effects, Reproducibility of Results, Risk Assessment methods, Risk Factors, Software, Time Factors, Weight-Bearing physiology, Automobile Driving, Lumbar Vertebrae physiology, Occupational Exposure analysis, Posture physiology, Vibration adverse effects

Abstract

The present study aimed to (1) employ the method for evaluation of vibration containing multiple shocks according to ISO/CD 2631-5:2014 (Model 1) and DIN SPEC 45697:2012 in a cohort of 537 professional drivers, (2) deliver the results for a re-analysis of epidemiological data obtained in the VIBRISKS study, (3) clarify the extent to which vibration acceleration and individual variables influence risk values, such as the daily compressive dose S(ed) and the risk factor R, and (4) compare the results with in vivo measurements and those obtained in previous studies with similar models. The risk factor R was influenced by the acceleration, lifetime exposure duration, sitting posture, age at the start of exposure and body mass/body mass index in order of decreasing effect. Age and annual and daily exposure duration had only a marginal effect. The daily compressive dose S(ed) and the risk factor R showed weak linear association with the daily vibration exposure A(8) and the vibration dose value VDV. The study revealed high shear forces in the lumbar spine., Practitioner Summary: In a re-analysis of an epidemiological study of professional drivers, a software tool available with standards DIN SPEC 45697:2012 and ISO/CD 2631–5:2014 Model 1 was used to calculate the risk to the lumbar spine in terms of daily compressive dose S(ed) and risk factor R. The tool was found to be suitable for risk assessment in a large cohort.

Published

2015

6. Vibrotactile difference thresholds: effects of vibration frequency, vibration magnitude, contact area, and body location.

Author

Forta NG, Griffin MJ, and Morioka M

Subjects

Adult, Human Body, Humans, Male, Mechanoreceptors physiology, Physical Stimulation, Posture, Psychophysics, Statistics, Nonparametric, Young Adult, Differential Threshold physiology, Sensory Thresholds physiology, Touch physiology, Vibration

Abstract

It has not been established whether the smallest perceptible change in the intensity of vibrotactile stimuli depends on the somatosensory channel mediating the sensation. This study investigated intensity difference thresholds for vibration using contact conditions (different frequencies, magnitudes, contact areas, body locations) selected so that perception would be mediated by more than one psychophysical channel. It was hypothesized that difference thresholds mediated by the non-Pacinian I (NPI) channel and the Pacinian (P) channel would differ. Using two different contactors (1-mm diameter contactor with 1-mm gap to a fixed surround; 10-mm diameter contactor with 2-mm gap to the surround) vibration was applied to the thenar eminence and the volar forearm at two frequencies (10 and 125 Hz). The up-down-transformed-response method with a three-down-one-up rule provided absolute thresholds and also difference thresholds at various levels above the absolute thresholds of 12 subjects (i.e., sensation levels, SLs) selected to activate preferentially either single channels or multiple channels. Median difference thresholds varied from 0.20 (thenar eminence with 125-Hz vibration at 10 dB SL) to 0.58 (thenar eminence with 10-Hz vibration at 20 dB SL). Median difference thresholds tended to be lower for the P channel than the NPI channel. The NPII channel may have reduced difference thresholds with the smaller contactor at 125 Hz. It is concluded that there are large and systematic variations in difference thresholds associated with the frequency, the magnitude, the area of contact, and the location of contact with vibrotactile stimuli that cannot be explained without increased understanding of the perception of supra-threshold vibrotactile stimuli.

Published

2012

7. Difference thresholds for the perception of whole-body vertical vibration: dependence on the frequency and magnitude of vibration.

Author

Forta NG, Morioka M, and Griffin MJ

Subjects

Adult, Humans, Male, United Kingdom, Young Adult, Perception physiology, Sensory Thresholds physiology, Vibration adverse effects

Abstract

When seeking to reduce vibration in transport it is useful to know how much reduction is needed for the improvement to be noticeable. This experimental study investigated whether relative difference thresholds for the perception of whole-body vertical vibration by seated persons depend on the frequency or magnitude of vibration. Relative difference thresholds for sinusoidal seat vibration were determined for 12 males at three vibration magnitudes and eight frequencies (2.5, 5, 10, 20, 40, 80, 160, 315 Hz) using the three-down-one-up method in conjunction with a two-interval-forced-choice procedure. The median relative difference thresholds were in the range 9.5% to 20.3%. There appeared to be a frequency-dependence at the lowest vibration magnitude, such that higher frequencies had higher difference thresholds. The relative difference thresholds depended on the vibration magnitude only at 2.5 and 315 Hz. The influence of both vibration frequency and vibration magnitude on the measured difference thresholds suggests that vision (at 2.5 Hz) and hearing (at 315 Hz) contributed to the perception of changes in vibration magnitude.

Published

2009