Control of Precision Grip Force in Lifting and Holding of Low-Mass Objects

• Published in: PloS one Vol. 10; no. 9; p. e0138506
• Main Authors: Hiramatsu, Yuichi, Kimura, Daisuke, Kadota, Koji, Ito, Taro, Kinoshita, Hiroshi
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 16.09.2015; Public Library of Science (PLoS)
• Subjects: Adolescent; Adult; Adults; Analysis; Arm; Biomechanical Phenomena; Biomechanics; Cost function; Female; Finger; Fingers - physiology; Friction; Grasping; Grip force; Hand Strength - physiology; Humans; Indentation; Lifting; Male; Medical care; Medicine; Microgravity; Movement - physiology; Neurosciences; Noise; Psychomotor Performance; Rayon; Researchers; Safety margins; Sandpaper; Skin; Ultrasonic testing; United States; Variability; Weight-Bearing - physiology; Young Adult; United States; Japan
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0138506

Few studies have investigated the control of grip force when manipulating an object with an extremely small mass using a precision grip, although some related information has been provided by studies conducted in an unusual microgravity environment. Grip-load force coordination was examined while healthy adults (N = 17) held a moveable instrumented apparatus with its mass changed between 6 g and 200 g in 14 steps, with its grip surface set as either sandpaper or rayon. Additional measurements of grip-force-dependent finger-surface contact area and finger skin indentation, as well as a test of weight discrimination, were also performed. For each surface condition, the static grip force was modulated in parallel with load force while holding the object of a mass above 30 g. For objects with mass smaller than 30 g, on the other hand, the parallel relationship was changed, resulting in a progressive increase in grip-to-load force (GF/LF) ratio. The rayon had a higher GF/LF force ratio across all mass levels. The proportion of safety margin in the static grip force and normalized moment-to-moment variability of the static grip force were also elevated towards the lower end of the object mass for both surfaces. These findings indicate that the strategy of grip force control for holding objects with an extremely small mass differs from that with a mass above 30 g. The data for the contact area, skin indentation, and weight discrimination suggest that a decreased level of cutaneous feedback signals from the finger pads could have played some role in a cost function in efficient grip force control with low-mass objects. The elevated grip force variability associated with signal-dependent and internal noises, and anticipated inertial force on the held object due to acceleration of the arm and hand, could also have contributed to the cost function.