The Strength of the Hand
Alfred B. Swanson, M.D.
Ivan B. Matev, M.D.
G. de Groot, M.D.
This article originally appeared in Bulletin of Prosthetics Research, Fall 1970. It is reproduced here by kind permission of the author and publisher.
Although strength is one of the important characteristics of a normal hand, this factor is not given enough attention in reconstructive surgery as compared to other parameters of motion and sensibility. This paper presents the results of a study on strength in functional adaptations of the normal hand. A baseline of normal grip and pinch strength was obtained by testing a group of one hundred healthy persons. As it is necessary to know the normal to appreciate the abnormal, a parallel evaluation of the disabled hand could define the degree of impairment present2,4,8,10,11.
Regnier, 160 years ago, reported the first analysis of strength of the hand measured with a personally designed dynamometer9. More recent studies were made by Lewey, Kuhn, and Juditski5, Bechtol1, and Mannerfelt6. Isometric contractions of the hand muscles were measured with pneumatic7 or hydraulic spring-scale dynamometers. The pinch meter used in our study is an electronic device designed by Kashiwagi's Orthopaedic Department at Kobe University, Kobe, Japan3.
The strength of the normal hand was recorded as applied in basic hand patterns: grip, chuck pinch (three-digit pinch), pulp (fingertip) pinch with separate fingers, and lateral pinch. Measurements are expressed in kilograms of force units.
Method and Materials
The force of grip was recorded with a Jamar hydraulic dynamometer. The strength of chuck, pulp, and lateral pinches was tested with an electronic pinch meter based on the straingage principle. The pinch object was a disk measuring 2.2 cm. diam. and 0.5 cm. thick. Changes in electrical potentials were transmitted by this disk to the recording device (Fig. 1
The study group consisted of 50 males and 50 females (200 hands) ranging from 17 to 60 years of age. They were distributed according to occupation in three main groups: skilled (skilled craftsmen using dexterity without heavy manual labor) 36, sedentary (light clerical occupations) 16, and manual workers (laborers doing unskilled heavy work, such as shoveling snow) 48. All subjects were in good health. The tests were done at various times of the working day at a room temperature of 70 deg. F. Both the major and the minor hand were tested in a comfortable position. Little difference was noted in the strength of the grasp and pinch regardless of whether the test was performed in a standing or sitting position, or the extremity was supported or unsupported, although pinch forces in the supported position were generally somewhat lower. The following standard measurements were taken:
- Strength of grip
- without support of the extremity,
- with support; i.e., with the arm or elbow resting on the table or close to the body.
- Strength of chuck pinch (three-digit pinch).
- Strength of pulp pinch for each separate digit (II, III, IV, V) with thumb.
- Strength of lateral pinch (between digits I and II).
Originally each of the strength tests was given three times. However, the first attempt was usually the strongest, and repeated testing proved to be unnecessary in a cooperative person. This was given consideration in this study. The various measurements were performed at short intervals and a control series was done on the same person several days later.
Strength of Grip
The adjustable handle of the Jamar hydraulic dynamometer was spaced at 2 1/2 in. (Fig. 1
B). Most subjects were comfortable at this breadth of grip and could apply maximal force when tested. The minimal and maximal strengths of grip measured ranged from 30.4 to 70.4 kg. in the male group and 14.0 to 38.6 kg. in the female group. Table 1
shows the average strength of grip for each group studied. The skilled and sedentary males recorded very similar figures and the forces recorded by the manual workers were not significantly higher. Taken separately, manual workers recorded the highest figures, 56.1 kg. for the major and 49.3 kg. for the minor hand. Variations in the force of grip according to age are seen in Table 2
. The male group showed rather constant strength between the ages of 20 and 50 years. In the female group the maximal strength recorded was for subjects between the ages of 30 and 40 years. The grip was found to be weaker when the extremity was supported. The average figure for the supported extremity in the male group was 44.7 kg. for the major and 41.7 kg. for the minor hand. The female group registered 22.3 kg. and 20.1 kg., respectively, for the supported extremities. This reduction could be explained by the fact that part of the strength was lost in stabilizing the extremity.
Several small objects such as coins, screws, buttons, and keys were picked up by any method desired. The type of pinch preferred by each individual to obtain his maximum strength was noted. The grasping patterns employed could be classified into five categories: 1. Pinch with simultaneous action of digits I, II, and III (chuck pinch) was selected by 44 percent of the subjects for the major hand and 49 percent for the minor hand (Table 1
A). 2. Simultaneous action of digits I and II was used in 29 percent of the major hands and 25 percent of the minor ones. 3. Pinch using digits I and II initially and including digit III for support during the last phase of pinch was observed in 19 percent of the subjects for both hands. 4. Another type of two-step pinch using digits I and III first and digit II last was recorded for 7 percent of the major and 4 percent of the minor hands. 5. Pinch between digits I and III was found in 1 percent of the major hands and 3 percent of the minor ones.
shows the average strength of the chuck pinch for the various groups examined. A small difference in strength of pinch was observed between the sedentary and manual workers. The minimal to maximal strength of chuck pinch recorded for the major hand was 6.0 to 14.5 kg. in the male group and 4.0 to 10.0 kg. in the female group. The interphalangeal joint of the thumb was hyperex-tended in most cases when the maximal force of chuck pinch was applied (Table 1
Pinch with Separate Digits
The end device of the electronic pinch meter was squeezed with each separate digit from index to little finger using alternate hands (Fig. 3
A). The interphalan-geal joint of the thumb became hyperextended in 88 percent of the females and 50 percent of the males (Fig. 3
B). This tendency was decreased for pulp pinch with digits IV and V. Table 4
shows the average strength of pinch for each separate finger recorded in kilograms of force. The middle finger (digit III) pinch was the strongest for both hands in males and females (Fig. 3
C and D). Pinch with digit V was half as strong as pinch with digits II or III. The weakest separate pinch observed in the male group was 2.0 kg. for digit V and the strongest was 11.8 kg. for digit III. Amongst the females the weakest value was 1.3 kg. with digit V and the strongest 7 kg. with digit III. A tendency to hyperextend either the proximal interphalangeal (PIP) or the distal interphalangeal (DIP) joints was evident when maximal pinch force was applied (Fig. 3
E and F). For the PIP joint this tendency increased from the radial to the ulnar sides of the hand.
For this test the pinch meter was held between the pulp of the thumb and the lateral aspect of the index finger (Fig. 4
). The manual group recorded the highest figures (Table 5
). The maximal to minimal values of lateral pinch strength with the major hand of males were 14.5 and 6.0 kg. respectively. The female group showed a maximal strength of 9.0 kg. and a minimal of 4.0 kg. for the major hand. As seen in Table 3
and Table 5
little difference was found in average major and minor hand strengths for both chuck and lateral pinches.
This study shows slightly higher strength of grip for the major hand than that reported by Bechtol and significantly stronger pinch forces with the major hand than those presented by Mannerfelt. This latter difference could be explained by the fact that Mannerfelt examined the thumb-to-index pinch with the arm and forearm in a fixed position. The present study demonstrated a strength decrease of 6 percent for the major hand and 7 percent for the minor hand when the extremity examined was supported rather than free. The female group showed a similar relative decrease: 9 percent for the major and 10 percent for the minor hand. In this study an attempt was made to register the true maximal strength of each individual, hence the extremities were tested without support. There were no obvious differences between measurements made in the morning and in the afternoon. The strongest grips recorded for the major hand were 70.4 kg. in a 29-year-old male surgical resident and 38.6 kg. in a 33-year-old female secretary.
Comparisons Between the Major and Minor Hands
The gripping strength of the minor hand was the same as, or higher than, the major one in 29 percent of the individuals examined. However, the major hand grip was always found to be the stronger for heavy manual workers. The chuck pinch of the minor hand was as strong as, or stronger than, that of the major hand in 50 percent of the males and 54 percent of the females tested. This finding was also true of 40 percent of the manual workers examined. The same difference in strength between the major and minor hands was demonstrated for lateral pinch. In 12 percent of the individuals examined the left hand was dominant. Of these 12 persons, 8 or 58 percent had a stronger grip with the minor hand.
On average, grip strength of the minor hand was found to be weaker in 5.4 percent of males and 8.9 percent of females. The strength of pinch in the minor hand was weaker by 4 percent in males and 6 percent in females. The data obtained in this study indicate that there is less difference in strength of the major and minor hands than has generally been thought.
This study surveyed the hand strength of 100 individuals (200 hands). The basic hand patterns evaluated were: grip, three-digit pinch (chuck pinch), pinch with separate fingers (pulp pinch), and lateral pinch. A Jamar hydraulic dynamometer was used to measure grip. The strength of the various pinches was tested with an electronic pinch meter. All values were expressed as kilograms of force.
Orthopaedic Research Department, Blodgett Memorial Hospital, Grand Rapids, Michigan
1. Bechtol, Charles O., The use of a dynamometer with adjustable hand spacings. J. Bone and Joint Surg., 36A:820, 1954.
2. Flatt, A. E., Rheumatoid Hand Research Project (Booklets), Department of Orthopaedics, University of Iowa, 1963.
3. Kashiwagi, Daiji, Personal Communication. Orthopaedic Department, Kobe University, Kobe, Japan, 1967.
4. Kirkpatrick, E. John, Evaluation of grip loss. Calif. Med., 85:314, November 1956.
5. Lewey, F. H., W. G. Kuhn, and J. T. Juditski, A standardized method for assessing the strength of hand and foot muscles. Surg., Gyn. and Obst., 85:785, 1947.
6. Mannerfelt, Lennart, Studies on the hand in ulnar nerve paralysis. Acta Orthop. Scand. (Suppl.), 87:63, 1966.
7. Parry, C. B. Wynn, Rehabilitation of the hand. Ed. 2, Butterworth, London, 1966.
8. Patterson, H. McLeod, Grip measurements as a part of the pre-placement evaluation. Ind. Med. and Surg., p. 555, July 1965.
9. Regnier, J. B., Considerations sur la force musculaire, suivies de la description et de l'exposition chalcographique d'un nouvel instrument pour mesurer cette force. Diss. Paris, 1807.
10. Swanson, A. B., Evaluation of impairment of function in the hand. Surg. Clin. N. Amer., 44:925, 1964.
11. Swanson, A. B., J. D. Mays, and Y. Y. Yamauchi, A rheumatoid arthritis evaluation record for the upper extremity. Surg. Clin. N. Amer., 48:1003, 1968.