J~URNALOF NEUROPHYS~OLOGY Vol. 48, No. 1, July 1982, Printed in U.S.A.

Architectural, Histochemical, and Contractile Characteristics of a Unique Biarticular Muscle: the Cat Semitendinosus

SUE C. BODINE, ROLAND R. ROY, DEBRA A. MEADOWS, RONALD F. ZERNICKE, ROBERT D. SACKS, MARIO FOURNIER, AND

V. REGGIE EDGERTON

Department of Kinesiology, Neuromuscular Research Laboratory, University of Califurnia, Los Angeles, California 90024

SUMMARY AND CONCLUSIONS

I. The semitendinosus (ST) muscle of the cat consists of two anatomically distinct sets of fibers connected in series by a dense con- nective tissue band that divides the “muscle” into a proximal and distal compartment, each having separate innervation.

2. Isometric and isotonic contractile properties of the ST were studied for three stimulation conditions: 1) proximal acti- vated (STp), 2) distal-activated (STd), 3) whole muscle activated (ST). In addition, the architectural and histochemical profiles of each compartment were determined.

3. The fiber type composition was similar in the STp and STd, with the majority of the fibers staining darkly for alkaline myofi- brillar adenosine triphosphatase ( ATPase). The muscle fibers of the STd were twice as long as the fibers of the STp. The cross-sec- tional areas of the two compartments were similar.

4. The in situ maximum isometric tension (P,) was identical for all three stimulation conditions. However, the maximum twitch tension (P,) was greatest when ST was ac- tivated and least when only the STp was activated. The time to peak tension (TPT) and half relaxation times (95 RT) were the same for all three conditions. The absolute maximal shortening velocity (V,,,) revealed an orderly progression of speeds in relation to the fiber length. When the V,,, of the STd (424 t 26 mm/s) and STp (224 t 23

mm/s) were added, the sum was approxi- mately the same as the V,,, obtained for the ST (624 t 30 mm/s). The intrinsic speed of shortening (millimeters per second per 1,000 sarcomeres) recorded at the common tendon of insertion was the same for all three con- ditions.

5. The identical nature of the P, values demonstrated the significance of the archi- tectural design, specifically, the physiologi- cal cross-sectional area, in determining the potential force production of a muscle. In contrast, the P, values were significantly dif- ferent for each stimulation condition. These differences were probably influenced in part by the “stiffness-compliance” properties of the muscle-connective tissue unit, which varied with different activation states of the ST muscle.

6. The similarity in TPT and 1/2 RT values for all three conditions illustrated the inde- pendence of the isometric speed-related pa- rameters from the architecture of the mus- cle. The differences in the absolute V,,, data, however, revealed a positive relation- ship between the maximum speed of short- ening and the fiber length.

7. These data demonstrate the necessity of the neuromotor command being matched with the architectural as well as the bio- chemical properties of each sarcomere (e.g., myosin ATPase and sarcoplasmic reticulum) of the muscles in the control of forces and velocities in vivo.

192 0022-3077/82/0000-0000$01.25 Copyright 0 1982 The American Physiological Society

CHARACTERISTICS OF CAT SEMITENDINOSUS 193

INTRODUCTION

Although a large variety of architectural arrangements of muscle fibers are found in mammalian skeletal muscle ( 1 I, 14, 17), the relative significance of this characteristic in determining the physiological properties and functional mechanics of muscle is not well known. Both theoretical (11, 17) and exper- imental results (33), have emphasized the close relationship belween morphology and function in synergistic muscles as well as within individual muscles. Intrinsic factors, such as sarcoplasmic reticular properties (6) and myosin ATPase (2) can mediate the rate of tension developed in an isometric con- traction. However, during lengthening and shortening contractions, muscle architecture assumes an equivalent if not greater impor- tance than intrinsic fiber properties. From previous studies of force-velocity character- istics of muscle, it is apparent that the num- ber of myofibrillar cross-links aligned in parallel determines the maximum force production, while the maximum velocity of shortening is influenced by the number of sarcomeres arranged in series (8).

In the cat, the semitendinosus (ST) is a biarticular muscle with a parallel fiber ar- rangement. It is located posteriorly in the thigh and is active during knee flexion and hip extension (9, 32). The ST has an inter- esting anatomical adaptation, which com- plicates this otherwise “straightforward” parallel-fibered muscle. A band of dense fi- bruus connective tissue divides the muscle into distinct proximal and distal parts, ar- ranged in series and with each part having a separate innervation (7, 3 1). This unusual architectural design provides an interesting model fur examining the functional signifi- cance of morphology on the contractile dy- namics of skeletal muscle.

The in series design of the ST combined with the dual innervation provides the po- tential for rather complex mechanical func- tion (5). In addition to the compound architecture, complex electromyographic (EMG) activity has been reported for the ST. During unrestrained locomotion, Eng- berg and Lundberg (9) observed a burst of

however, whether a single burst can be as- sociated with one or both compartments of the muscle.

The existence of an endogenous in series muscle arrangement provides an intriguing experimental preparation for examining the passive and dynamic mechanical properties of skeletal muscle. The purpose of this study was to detail the architectural and histo- chemical profiles of the cat semitendinosus and to examine its compound mechanical properties during isometric and isotonic con- tractions. No significant difference exists between the histochemical properties or the cross-sectional areas of the proximal and distal portions of the ST. The contractile experiments nevertheless emphasize the multiple combinations of tensions and veloc- ities that are possible, although not neces- sarily utilized, as a consequence of the serial architecture and separate innervation of the ST. Preliminary results were published else- where (4).

METHODS

Architectural characteristics Six adult cats weighing between 2.0 and 6.0 kg

were used to determine the histochemical, archi- tectural, and contractile properties of the ST. Pre- vious work (33) showed a strong correlation be- tween the right and left architectural profiles of mammalian hindlimb musculature. Thus, the paired hindlimbs were similar and the architec- tural characteristics of the right side could be directly related to the contractile properties of the corresponding left side.

A detailed description of the procedures used to determine muscle architecture has been re- ported (30, 33). Briefly, the lower extremity was skinned and fixed in Formalin with the knee and hip joints positioned at approximately 90°. Gos- low et al. (12) indicated that the average joint angles adapted in quiet standing for the hip (ilio- femoral), knee, and ankle are 95, 100, and 1 loo, respectively, and therefore our method of fixation allowed muscle lengths to be measured at a func- tional standing length. Individual muscles were dissected, removed, and placed in a 15-20% sul- furic acid solution, and subsequently stored in 50% glycerol. By measuring the muscle length before and after fixation, the amount of shrinkage or elongation was found to be less than *5%.

activity in both the swing and stance phase Small bindles of fibers ( lo- 15) were teased out of the cat step cycle in the ST. It is unclear, from each portion of the muscle and measured

194 BODINE ET AL.

with calipers. Samples were taken from several regions along the length of the muscle at varying depths. Average sarcomere lengths were deter- mined from individual fibers under a light micro- scope (x400) using a calibrated eyepiece microm- eter. Sarcomere lengths from different regions within a muscle were within -t5%. Measurements of muscle lengths and sarcomere lengths estab- lished the number of sarcomeres in series. Al- though shrinkage occurs with fixation, there will be proportional changes occurring in both whole muscle and sarcomere lengths. Any length change will not affect the absolute number of sarcomeres in series. Physiological cross-sectional areas were calculated using the following formula: cross sec- tional area = ((muscle mass) (cos@))/((fiber length) (density)). Muscle mass (g) was deter- mined by weighing fresh muscles from cats of sim- ilar weights, 8 was equal to the approximate angle of pinnation, absolute fiber length (cm) was calculated from the architectural data, and den- sity of the muscle was assumed to be 1.0564 g/ cm3 (22).

Histochemistry Fiber-type distributions were determined for

the ST on three adult cats. On the average, 125 fibers were analyzed from serial sections of the superficial and deep portions of both the STp and STd. Fibers were classified as slow oxidative (SO), fast oxidative-glycolytic (FOG), and fast glyco- lytic (FG) using reduced nicotinamide adenine dinucleotide diaphorase, adenosine triphosphatase (acid and base preincubation), and a-glycero- phosphate dehydrogenase activity as described by Peter et al. (26).

Contractile properties The in situ isometric and isotonic contractile

properties of the proximal-activated (STp), distal- activated (STd), and whole muscle-activated (ST) semitendinosus muscle were determined from the contralateral hindlimbs of six adult cats.

Animal preparation Animals were anesthetized with sodium pen-

tobarbital (35 mg/kg ip) and the hindlimb mus- culature was exposed with a posterior sagittal in- cision extending from the ischial tuberosity to just inferior to the knee joint. The ST was carefully isolated with the normal blood supply left intact. The ST was freed from surrounding musculature to allow for the full range of motion and to assure an unrestricted view during filming of some con- tractions. This film data will be used to assess movement within each compartment.

The nerves innervating the ST originate from distinct branches of the sciatic nerve. As the sciatic nerve passes over the obturator internus muscle in the gluteal region, there is a large mus-

cular branch that supplies the ST, semimembra- nosus, and biceps femoris. The nerve branch going to the ST bifurcates and sends one branch to the proximal and the other to the distal compartment of the ST. These two branches were isolated, sep- arated to the point of bifurcation, tied with suture, and cut. Surrounding muscles were denervated and fine-wire electrodes (50 pm in diameter) were placed in the STp and STd to monitor electro- myographic (EMG) activity.

The distal tendon of the ST was detached from its insertion site at the medial side of the tibia1 crest and tied with nylon ligature (2-O) to a steel wire attached directly to an isotonic pneumatic lever (22). The cat was cradled in a frame in a prone position and the hindlimb was rigidly se- cured with metal clamps. A mineral-oil bath was formed using the retracted skin of the hindlimb and maintained at a temperature of 36 ? l°C. The ST goes through rather large displacements when shortening and to insure the optimal line of pull for the muscle and the largest range of mo- tion, the ST was positioned horizontally and sus- pended above, rather than submerged, in the oil pool. Isometric and isotonic contractions for each stimulation condition were filmed. To reduce glare, it was necessary to have the muscle sus- pended above the pool. Due to these experimental restraints, the temperature of the ST was main- tained at 31 k 3OC.

Testing protocol Isometric and isotonic contractions were re-

corded on a modified pneumatic lever system (22) for each of three activation conditions: I) STd stimulated and STp passive, 2) STp stimulated and STd passive, and 3) both STd and STp stim- ulated simultaneously. The order for testing the three activation conditions was alternated to avoid any potential bias. The distal tendon of the ST was attached in situ to a magnesium lever on which force and displacement transducers were mounted. The muscle length (L,) at which max- imum isometric twitch tension could be produced was determined for each of the three activation conditions. The length of the muscle at each L, was measured from film taken during an isometric twitch. All contractions were initiated at the L, appropriate for that activation condition. For iso- tonic contractions, the mechanical restraint was removed and the resistance to shortening was sup- plied with a variable air pressure system in series with the lever arm (33). All force and displace- ment data from the contractions were recorded on a polygraph (Grass Instruments 7B) and FM tape recorder (Hewlett-Packard 3968) and were monitored on a storage oscilloscope.

Muscular contractions were elicited through stimulation of the isolated nerve branches with

CHARACTERISTICS OF CAT SEMITENDINOSUS 195

bipolar silver electrodes. Stimulating electrodes dition (STp, STd, and ST) by averaging Hill’s were placed on each of the branches to permit constants for all muscles tested for each activation activation of each compartment independently or condition. The values listed in the text are means both simultaneously. k SE.

The stimulus delivered was a 0.02-ms square- wave pulse with a strength approximately twice the voltage required to obtain a maximal isometric twitch response. The twitch response for each stimulation condition was obtained at the begin- ning of an experiment prior to testing for the fre- quency-tension and force-velocity properties. Iso- metric twitch data yielded measures of maximum twitch tension (P,), time to peak tension (TPT), and half relaxation time (Y2 RT). Peak isometric tension (P,) was determined from the tension re- sponse to stimulation at frequencies of 5, 10, 15, 20, 25, 30, 40, 50, 75, 100, and 200 Hz for 500 ms duration. Isotonic properties were obtained for 15-20 afterloaded contractions at varying loads less than P, and stimulated at a frequency of 200 Hz for 330 ms. A 2-min interval between each contraction was allowed, during which the muscle was stimulated at 1 Hz. P, values were obtained and compared at several points during each ex- perimental condition. These values deviated less than 8%.

RESULTS

Architecture

Analog FM tape records were digitally sampled ( 1,000 Hz) with a minicomputer (HP 21 MX). Calibrated voltage fluctuations were converted to force, rate of tension development (dP/dr), and velocity (dL/dt) via methods previously described (28). To calculate a maximal velocity of short- ening (V,,,) for each stimulation condition, the linear form of Hill’s equation ((P, - P)/v = m (P) + b) was used (15). For each isotonic con- traction, peak velocity (V) and corresponding force (P) were plotted as ((P, - P)/V) versus P. A linear regression equation was fitted to these data with Hill’s constants a and b corresponding to the slope and the y intercept of the regression line, respectively. An averaged estimated force- velocity curve was derived for each activation con-

Both the STp and STd have a parallel muscle fiber arrangement; the angle of pin- nation was 0’ with respect to the long axis of the muscle-tendon unit (Fig. 1). The STp and STd, respectively, constitute approxi- mately one-third and two-thirds of the total ST length and their muscle fibers are con- tinuous from the respective tendinous inser- tions to the fibrous connective tissue septum. Specifically, the length of the fibers for the STd was 3.93 t 0.1 cm, and the length of the STp was 2.12 t 0.1 cm. The estimated wet weight of the STp was 5.14 t 0.13 g or approximately 40% of the ST wet weight, while the STd was 7.69 k 0.47 g. The wet weights, however, were difficult to determine precisely because of the uneven alignment of the surface of the septum. The physiolog- ical cross-sectional area of the STp (2.29 cm’) was not significantly different from the cross-sectional area of the STd ( 1.85 cm2). The average sarcomere length in both the STp and STd was 2.19 k 0.10 pm.

Histochemistry The muscle fiber type composition is sim-

ilar in both the STp and STd (Table 1). The deep portions of the STp and STd are nearly uniform in composition, with the majority of the muscle fibers being fast twitch. In the superficial portion, the STd has 27% oxi-

Sciatic n.

PST Con&t ive tissue sept urn DST

FIG. I. Schematic drawing of the cat semitendinosus (ST) muscle. A dense connective tissue band divides the ST into a proximal (STp) and distal (STd) end. The muscle fibers of each end are arranged in parallel (0 = O”) and are connected in series at the connective tissue band, with distal fibers being approximately twice as long as the proximal fibers. Each end is innervated by a separate branch from the sciatic nerve.

196 BODINE ET AL.

TABLE 1. Cat semitendinosus muscle fiber type composition

Proximal

FG FOG so

Deep Superficial

Distal

48 zk 1 29 * 2 22 k 2 80 * 3 18 k 3 l&l

Deep 46 k 3 29 -t 2 24 t 2 Superficial 73 -t- 3 24 k 2 3-+2

Values are means k SE, expressed as percentages. II = 3 cats, with an average of 125 fibers per area. Deep, one-fourth the area of the muscle that was closest to the femur; superficial, one-fourth the area of the muscle that was farthest from the femur,

dative fibers (FOG + SO), while the STp has somewhat fewer oxidative fibers (19%) There was no difference in the SO popula- tions of the superficial or the deep portions of either compartment.

Contractile properties

To establish the potential for independent activation, electromyographic (EMG) sig- nals were studied from both the STp and STd in response to stimulation to each of the separate nerve branches. Only the stimu- lated compartment showed an EMG signal suggesting that each compartment could be electrically isolated by the connective tissue septum that separates proximal from distal muscle fibers. Consequently, since differen- tial activation was possible, the separate and compound contractile properties of the ST could be determined.

FORCE RELATED. Isometric and isotonic contractile properties were obtained from the three stimulation conditions: STp, STd, and ST (Table 2). All contractions were elic-

ited at the L, that was appropriate for each stimulation condition. The length of the whole muscle at L, was 142 t 2, 138 t 2, and 134 t 3 mm for STp, STd, and ST, re- spectively. The length-tension relationship of all three conditions revealed that active tension was remarkably constant over a wide range of lengths. A relatively flat length-ten- sion curve would be expected since the ST is a parallel-fibered muscle (11, 12, 27). According to Goslow et al, (12), during lo- comotion, the ST is generally used at lengths shorter than L, (the length associated with quiet standing) and goes through a range of approximately t 10 mm from L,. Within this physiological range, the ST is able to actively produce greater than 90% of its maximum isometric twitch tension. The maximum twitch tension was greatest when STp and STd were stimulated simultaneously and was least when only the STp was stimulated. In contrast, the maximum tetanic tension (P,) was identical across all three conditions. The frequency-tension response revealed a difference in all three stimulation conditions at frequencies lower than 20 Hz; however, at frequencies between 20 and 75 Hz, STp produced less tension than both ST and STd (Fig. 2). The force produced at 20 Hz (PzO) was 40 and 37% of P, for the ST and STd, respectively, but only 24% of P, for STp (Table 2).

SPEED RELATED. The TPT and ‘/2 RT were similar for all three stimulation conditions (Table 2). However, when the maximal ve- locity of shortening (V,,,) was expressed in absolute terms (millimeters per second), there was an orderly V,,, relationship across the three stimulation conditions based on the differences in fiber lengths of the STd and

TABLE 2. Contractile properties of cat semidendinosus

Units Distal (STd) Proximal (STp) Both (ST)

TPT ms 47 k 3 41 t 3 41 * 2 Y2 RT ms 37 k 5 31 t5 37 z?z 5 h 3.53 Ik 0.46? 2.74 4 0.48$ 5.29 & 0.80 P 20 k P, 37 IL 3* 24 t- 4 40 t 65 PO n 20.6 * 2 18.6 k 3 19.6 t 2 V max mm/s 424 k 26” 224 t 23$ 624 do 307 V l max mm s-I/ 1,000 sarcomeres 23.6 t 1.4 23.2 t 2.3 22.6 k 1.1

Values are means k SE. n = 6 cats. Significant differences (P < 0.05) for the following paired comparisons: * STd vs, STp; t STd vs. ST; $ STp vs. ST.

CHARACTERISTICS OF CAT SEMITENDINOSUS 197

t

0 25 50 FREQ"ENCY7~"z )

100 -' 200

FIG, 2, Frequency of stimulation is plotted versus force for each of three stimulation conditions: proximal activated (STp) (A), distal activated (STd) (w), and STp-STd activated simultaneously (ST) (a). Force is expressed as a percent of maximum isometric tension.

STp. Stimulation of the whole muscle (ST) produced the highest absolute V,,,. When the Lx of the STd (424 t 26 mm/s) and the STp (224 & 23 mm/s) were added, the resulting V,,, was similar to that observed for the ST (624 t 30 mm/s). The intrinsic maximum velocities of shortening (milli- meters per second per 1,000 sarcomeres) for the three stimulation conditions were iden- tical (Table 2), reflecting the similarities in fiber type composition. The characteristic force-velocity relationships for the three stimulation conditions are illustrated as a function of absolute velocity (millimeters per second) versus force (% P,) in Fig. 3, and relative velocity (millimeters per second per 1,000 sarcomeres) versus force (% P,) in Fig. 4.

DISCUSSION

Architectural considerations The semitendinosus has an unusual ar-

chitectural design for cat hindlimb muscu- lature. A band of dense fibrous connective tissue divides the muscle into two distinct compartments innervated by separate nerve branches from the sciatic nerve, Glycogen- depletion studies (10) have shown that there are two distinct populations of muscle fibers proximally and distally. However, there is extensive topographical overlap among the motoneurons supplying each end of the mus- cle (5, 19).

The in series fiber arrangement of the ST

600

500 h

0 40 60 FORCE (%Po )

FIG. 3. Force-velocity relationships are plotted for the three stimulation conditions: STp (A), STd (w), and ST (a). Velocities are expressed in absolute units of millimeters per second and forces are expressed as per- cent of maximum isometric tension. These curves ilIus- trate the direct relationship between maximum speed of shortening and fiber length.

is not unique to the cat. It is also found in dogs (20), monkeys ( 1 ), and humans (3,20). It appears that the in series arrangement of the ST is the selected mode of linkage phy- logenetically. In other mammals, this muscle is even more complex structurally. The ST in rats (1, 29), mice (18), rabbits ( I), and guinea pigs ( 1) has two proximal heads of origin with a tendinous inscription at the more distal junction of the two heads. The dorsal head has its origin from the caudal

FIG. 4. Force-velocity relationships of the STp (A), STd (w),. and ST (a). The relative velocities are ex- pressed as millimeters per second per 1,000 sarcomeres and forces are expressed as percent of maximum iso- metric tension. The intrinsic velocities of shortening are not significantly different for the three stimulation con- ditions reflecting the similarity in fiber type composition of the proximal and distal ends.

198 BODINE ET AL.

vertebrae, whereas the ventral head attaches to the ischial tuberosity. According to Ap- pleton (l), the tendinous inscription appears to be a new structure found in mammals. It appears that two heads of origin is an an- cestral condition, whereas the absence of the dorsal head or an ischial head as found in some rodents is a developed state (18).

Although the in series architecture of the ST is unique in the hindlimb, there are other muscles with a similar design. The human rectus abdominus ( 13), human digastric ( 13), and rat plantaris-flexor digitorum brevis complex (29) are some examples that dem- onstrate sets of fibers attached in series. However, each of these examples have an in series arrangement that differs with respect to the force vectors and/or probably the stiffness of the connecting elements.

Mechanical properties

The maximum isometric tension (P,) that can be produced by a muscle is proportional to the number of contractile elements or myofibrillar cross-links in parallel ( 14). The fact that the PO’s of the STp, STd, and ST were identical further demonstrates the sig- nificance of the architectural design, i.e., the importance of the physiological cross-sec- tional area in determining the potential P, of a muscle. When the STp and STd are stimulated simultaneously, the P, should be proportional to the smallest total cross-sec- tional area of all the muscle fibers along the proximodistal axis. Since the physiological cross-sectional areas of both compartments were similar, the number of myofibrillar cross-links in parallel would be expected to be similar in each end, and consequently the P, of all three conditions would also be ex- pected to be similar.

The maximum values of twitch tension, in contrast to the PO values, were signifi- cantly different. Stimulation of the STp or STd produced P, values which, when summed, approximated the P, value for si- multaneous stimulation of the ST. The stiff- ness-compliance properties of the muscle- connective tissue unit undoubtedly influ- enced the values measured for P, conditions. When only one compartment was stimu- lated, the compliance occurred primarily in the passive compartment of the muscle. As

demonstrated by Hill (16), the maximum twitch tension decreased as the series com- pliance increased.

Because of the differences in lengths (STp/ STd = 2.12/3.93 cm) there will be a sub- stantial difference in the stiffness when one is stimulated independently of the other. The combined stiffness of the STd and STp would be expected to be the same as if the semitendinosus were a single muscle with muscle fibers equal to 6.05 cm (assuming similar material composition and cross-sec- tional area). It would seem that the me- chanical significance of the in series fiber arrangement in the ST would be important only if each compartment were activated in- dependently in situ.

The frequency-tension relationships (Fig. 2) indicated that the compliance effects of a passive coupled with an active contractile compartment were most evident at frequen- cies at 20 Hz or less. The STp had the lowest PzO (Table 2), the STd was next in order of increased tension output, and the ST was highest in tension. At frequencies between 20 and 75 Hz, only STp differed in its ten- sion response. The order effect was consis- tent with the compliance characteristics of the ST components, but a more detailed in- tracontraction assessment of the force-de- formation characteristics of the STd, STp, and full muscle is needed before the defin- itive mechanics of the in series arrangement can be elucidated.

The absolute velocity of shortening is de- termined by the biochemical properties (2) and the length of the fibers (17). Hence, the V,,, (millimeters per second) was lowest for the STp at a value approximately one-third the speed of the ST, with the STd at ap- proximately two-thirds the ST V,,,. These differences were simply a function of the differences in fiber lengths, since with a nor- malization of V,,, values as a function of the number of sarcomeres in series (milli- meters per second per 1,000 sarcomeres) there was no difference between the three conditions. The normalized V,,, values were consistent with the histochemical findings that showed each compartment to have iden- tical “slow-fast” fiber proportions.

The data from these experiments empha- size the importance of architectural design in determining functional force and velocity

CHARACTERl:STICS OF CAT SEMITENDINOSUS 199

characteristics of skeletal muscle. The rela- tionship between fiber length and V,,, in- dicates that the longer the fiber, the faster the absolute speed of shortening, i.e., speed is a function of the number of sarcomeres in series. For this and other parallel fibers in general, this arrangement allows the max- imum possible displacement with the least loss of force during the contraction (11, 27). The parallel arrangement may permit the muscle to operate at lengths close to L, with only small fractions of sarcomere length changes to maintain force production at ef- fective levels.

The P, values from the three conditions of stimulation reinforce the known relation- ship between cross-sectional area and force production in muscle. For an in series ar- rangement of two muscles, or parts of the same muscle, force is not additive but is de- pendent on cross-sectional area and will be a reflection of the weakest link in the series. Unlike the isotonic contractions, these data further illustrate that isometric speed-re- lated parameters (TPT and ‘/2 RT) are in- dependent of muscle architecture (30).

Implications for motor control The ST is a biarticular muscle attaching

proximally on the ischial tuberosity and disl tally on the medial side of the tibia1 crest. Because of its attachments, the ST functions as both a hip extensor and knee flexor. Stud- ies (9,24,25,34) have shown the ST to have a double burst of EMG activity during each locomotor step cycle. During the step cycle, the initial burst of activity occurred during the E3 and F phases (28), while the second burst occurred after a brief pause in the El and E2 phases. Perret and Cabelguen (24, 25) have also shown a double burst in the decorticate preparation in cats. However, “burst 2” could be completely eliminated during free locomotion after complete deaf- ferentation of the ST. Nevertheless, if the limb was fixed to counteract flexion or given constant tactile stimulation, burst 2 occurred alone during the locomotor cycle. This sug- gests that some constant inflow of afferent information from the limb is needed to bring about the second burst of activity in the ST. In fictive locomotion (34) the ST can also display two bursts of activity in each step cycle, one during the flexor activity and one

during the extensor activity. Various dis- charge patterns can be seen with different “excitation levels” and afferent input (34).

During locomotion, the length changes in the ST are markedly influenced by the rel- ative movements of the hip and knee joints (12). The ST, according to Goslow et al. (12) is generally used in stepping at muscle lengths shorter than a length (L,) that refers to a hindlimb configuration associated with a quiet standing posture: hip (iliofemoral), knee, and ankle angles at 95, 100, and 1 lo”, respectively. Time of the “active” (EMG activity present) phases of the ST during lo- comotion was determined (12) with a com- parison of kinematic data with previously reported EMG data (9). In the F phase (28) of the step cycle, Goslow et al. ( 12) reported that in walking (0.67 m/s) the ST undergoes active shortening then lengthening, while in the F phase of the trot (1.61 m/s) and gallop (7.29 m/s), the ST only undergoes active shortening contraction. From the data pre- sented on the average contraction velocities of the ST during locomotion (Table 5 in Ref. 12), the highest average shortening velocity (154 mm/s) of the ST occurred during the F phase of the trot. Because the velocity of 154 mm/s was an average over the complete F phase, it is likely that instantaneous active velocity may be higher during portions of the F phase (e.g., see their Fig. 12). It is appro- priate to consider this in vivo average veloc- ity in light of the range of differences in the in situ force-velocity characteristics of the three stimulation conditions: STp, STd, and ST. For example, if only the STp was re- cruited with a velocity of shortening of 154 mm/s, the maximum force potential would be about 14% of P, (Fig. 3). If, however, the STd was recruited at the same speed of shortening, the potential force would now be approximately 29% of PO. In comparison, if the ST was active during a shortening ve- locity of 154 mm/s, the potential force pro- duction would be 4 1% of P,. From Fig. 3, it is evident that at any given velocity of shortening at the ST tendon, the amount of force that can be produced is greatest when the ST is activated. Our results to date (2 1) have shown that a double burst of activity occurs in the STp and STd and that they can occur simultaneously during treadmill locomotion. This might suggest that al-

though anatomically the STp and STd could separate innervations coupled with the com- function independently, they in fact are pound muscle arrangement in the cat ST closely coordinated during locomotion. In- provides the central nervous system with a terestingly, both have the same number of significantly greater number of potential muscle spindle capsules (7). Nelson and combinations of forces and velocities than Mendell (23) have also indicated that single if it were a single muscle structure. Whether Ia-fibers from the STp and STd project sim- all of these combinations are used in normal ilarly to motoneurons of both compartments. movement remain to be determined, but re- These results are consistent with the hy- gardless, the means of neurally controlling pothesis that the spinal cord is organized to these “added” variables seem to exist. treat the ST as a single muscle and that the afferent systems of both have similar prop- ACKNOWLEDGMENTS

erties. Even though the in situ preparation dem-

We thank Doug Stuart for bringing to our attention

onstrates the possibility of independently the unusual arrangement of the semitendinosus muscle and for his critical review of the manuscript. We also

activating the STp and STd, these data show thank Tom Hamm and Ziaul Hasan for their helpful

that the effectiveness of the system to pro- criticism of the manuscript.

duce tension and velocity may be compro- This study was supported by National Institutes of

mised if one is activated independently of Health Grant N516333.

the other, particularly at frequencies of 20 Hz or less. However, the existence of the

Received 8 September 198 1; accepted in final form 17 February 1982.

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