Online citations, reference lists, and bibliographies.
← Back to Search

The Effect Of Measurement Time When Evaluating Static Muscle Endurance During Sustained Static Maximal Gripping.

S. Yamaji, S. Demura, Y. Nagasawa, M. Nakada, T. Kitabayashi
Published 2002 · Medicine

Cite This
Download PDF
Analyze on Scholarcy
Share
The purpose of this study was to examine the useful measurement time when evaluating static muscle endurance by comparing various parameters during sustained static gripping for 1, 3 and 6 min. Fifteen males (mean +/- SD age 20.8 +/- 1.3 yr, height 172.9 +/- 4.6 cm, body mass 67.7 +/- 5.7 kg) and fifteen females [mean +/- SD age 20.2 +/- 0.9 yr, height 158.5 +/- 3.2 cm, body mass 55.9 +/- 4.6 kg] volunteered to participate in this study. The subjects performed the sustained static maximal grip test with a sagittal and horizontal arm position for 1, 3 and 6 min on different days. Eleven force-time parameters were selected to evaluate static muscle endurance. The trial-to-trial reliability of each measurement time of sustained static maximal gripping was very high (rxy = 0.887-0.981 (1 min), 0.912-0.993 (3 min), 0.901-0.965 (6 min)). The errors of exertion values between trials were very small (below 10%). A significant correlation was found in the following parameters: the final strength and the exponential function between 1 min and 3 min, all parameters except for the time required to reach 80% of maximal grip, the regression coefficient at post-inflection between 3 min and 6 min, and the decreasing rate between all measurement times (1 min, 3 min, and 6 min). Significant differences between the measurement times were found in all parameters except for the time to 60, 70, and 80% force decreases, and the regression coefficient of pre-inflection. There was a tendency that the longer the measurement time, the larger the decreasing force. It is suggested that for the 6 min measurement, the subjects unconsciously restrained the maximal gripping force, influenced by a psychological factor as the pain became greater. The 1 min measurement may evaluate only the remarkable decreasing phase of the decreasing force, and not evaluate the phase of an almost steady state.
This paper references
Regulation of oxygen transport system during exercise
M Walamies (1999)
10.1016/0028-3932(71)90067-4
The assessment and analysis of handedness: the Edinburgh inventory.
R. Oldfield (1971)
10.1097/00005768-199601000-00026
Isometric intermittent endurance of four muscle groups in men aged 20-74 yr.
M. Bemben (1996)
10.1080/10671188.1958.10612983
Isometric Fatigue Curves in Human Muscle with Normal and Occluded Circulation
J. Royce (1958)
Strength decrement in repeated maximal voluntary contractions and muscular endurance performance of planter flexions
A Kagaya (1989)
Maximum grip strength and endurance of maximum strength in athletes and non-athletes
M Ishiguro (1985)
10.1007/BF00625069
A comparison of strength and muscle endurance in strength-trained and untrained women
H. A. Huczel (2004)
10.1113/jphysiol.1963.sp007094
The blood flow through active and inactive muscles of the forearm during sustained hand‐grip contractions
P. W. Humphreys (1963)
10.1080/02701367.1992.10608746
Muscular strength and endurance as a function of age and activity level.
D. H. Clarke (1992)
Regulation of oxygen transport system during exercise. In: Human circulation
M Saito (1999)
Intramuscular pressure and contractile strength related to muscle blood flow in man.
B. Nilsson (1967)
10.5432/JJPEHSS.KJ00003397658
Examination of the parameters of static muscle endurance on sustained static maximal hand gripping
S. Yamaji (2000)
Fatigue during sustained maximal voluntary contraction of different muscles in humans: dependence on fiber type and body posture Relative muscle loading and endurance
G Caffier (1963)
10.1007/BF00377710
Assessment of the reproducibility of strength and endurance handgrip parameters using a digital analyser
M. Walamies (2004)
10.1007/BF00626286
Fatigue during sustained maximal voluntary contraction of different muscles in humans: dependence on fibre type and body posture
G. Caffier (2004)
10.7600/JSPFSM1949.49.495
RELATIONSHIP BETWEEN STRENGTH EXERTION AND SUBJECTIVE MUSCLE-FATIGUE SENSATION IN THE RELATIVE SUSTAINED STATIC HAND GRIPPING
Y. Nagasawa (2000)
10.1080/10671188.1972.10615124
Sustanied handgrip in boys and girls: variation and correlation with performance and motivation to train.
W. Bowie (1972)
Relative muscle loading and endurance.
Caldwell Ls (1963)
The assessment and analysis of h a n d e d n e s s : t h e e d i n b u r g h in v e n t o r y
RC Oldfield (1971)
Muscle endurance — evaluating for physical fitness —
A Kagaya (1994)
10.1111/J.1748-1716.1967.TB03719.X
Muscle glycogen during prolonged severe exercise.
L. Hermansen (1967)



This paper is referenced by
ENTRENAMIENTO DE FUERZA DEL MIEMBRO SUPERIOR EN USUARIOS DE SILLA DE RUEDAS RESISTANCE TRAINING PROGRAM OF THE UPPER EXTREMITY IN MANUAL WHEELCHAIR USERS
J. Martin (2007)
10.1080/02701367.2019.1699233
Differences in Handgrip Strength-endurance and Muscle Activation between Young Male Judo Athletes and Untrained Individuals.
Renêe de Caldas Honorato (2020)
Valoración de la fatiga neuromuscular en el antebrazo del motorista de velocidad
Priscila Torrado Pineda (2015)
10.2114/JPA.24.1
Examination of the reproducibility of grip force and muscle oxygenation kinetics on maximal repeated rhythmic grip exertion.
M. Nakada (2005)
10.1519/JSC.0b013e3181d8e6ee
Influence of Instruction Conditions on the Evaluation of Muscular Endurance Based on Muscle Oxygenation
Shinichi Demura (2010)
EFFECT OF UPPER EXTREMITY INJURY ON GRIP STRENGTH EFFORT
B. Sindhu (2007)
10.1016/j.jhsa.2016.12.014
Static and Dynamic Handgrip Strength Endurance: Test-Retest Reproducibility.
Vassilis Gerodimos (2017)
10.1007/s11332-008-0058-2
Influence of grip types and intensities on force-decreasing curves and physiological responses during sustained muscle contractions
S. Demura (2008)
10.1111/j.1440-1630.2010.00888.x
Reliability and validity of indices of hand-grip strength and endurance.
S. Reuter (2011)
10.2114/JPA2.26.15
The properties and interrelationships of various force-time parameters during maximal repeated rhythmic grip.
M. Nakada (2007)
10.4236/HEALTH.2010.211186
Muscle endurance measurement using a progressive workload and a constant workload by maximal voluntary contraction
Shinichi Demura (2010)
TheInfluence of Different Target Values and Measurement Times on Decreasing Force Curve during Sustained Static Gripping Work the
Shunsuke Yimajii (2017)
10.2466/05.25.PMS.112.2.561-572
Different Gripping Intervals in Reproducibility of Force-Decreasing Curve and Muscle Oxygenation Kinetics during Sustained Maximal Gripping
Shinichi Demura (2011)
10.2114/JPA2.25.23
The influence of different target values and measurement times on the decreasing force curve during sustained static gripping work.
S. Yamaji (2006)
10.1080/09638280400020615
Measurement of cervical flexor endurance following whiplash
D. Kumbhare (2005)
10.1620/TJEM.215.287
Gender difference in subjective muscle-fatigue sensation during sustained muscle force exertion.
S. Demura (2008)
10.12691/AJSSM-1-2-3
Comparison of Force Exertion Characteristics of Sustained Hand Grip and Toe Grip
Masakatsu Nakada (2013)
10.1016/j.exger.2017.08.033
Force-time characteristics during sustained maximal handgrip effort according to age and clinical condition
L. D. Dobbeleer (2017)
10.1109/AIM.2013.6584089
Powered finger exoskeleton having partially open fingerpad for flexion force assistance
P. Heo (2013)
10.2466/pms.103.1.29-39
Sex Differences and Properties of the Decreasing Force during Sustained Static Grip at Various Target Forces
S. Yamaji (2006)
10.1109/TBME.2014.2325948
Power-Assistive Finger Exoskeleton With a Palmar Opening at the Fingerpad
P. Heo (2014)
10.2114/JPA2.27.161
Relationships between force-time parameters and muscle oxygenation kinetics during maximal sustained isometric grip and maximal repeated rhythmic grip with different contraction frequencies.
S. Demura (2008)
10.2114/JPA.23.41
Relationships between decreasing force and muscle oxygenation kinetics during sustained static gripping.
S. Yamaji (2004)
10.2114/JPA2.28.109
Relationships between force and muscle oxygenation kinetics during sustained static gripping using a progressive workload.
Shinichi Demura (2009)
10.11183/JHE.38.33
Changes in subjective muscle fatigue sensation and blood lactate and their relationships with decreasing force during sustained handgripping using various target values and its recovery stage.
Sinichi Demura (2009)
10.4236/APE.2014.44021
The Characteristics and Laterality of Explosive Force Exertion of Hand Grip and Toe Grip
Masakatsu Nakada (2014)
Estudo exploratório do comportamento da força de preensão da mão
Ana Rita Moreira Paupério (2017)
10.1136/bjsm.2007.037861
Sports medicine clinical trial research publications in academic medical journals between 1996 and 2005: an audit of the PubMed MEDLINE database
A. Nichols (2007)
10.1111/sms.12220
Force–time course parameters and force fatigue model during an intermittent fatigue protocol in motorcycle race riders
M. Marina (2015)
Semantic Scholar Logo Some data provided by SemanticScholar