Physiological cross sectional area
Encyclopedia
In pennate muscle
s, the physiological cross-sectional area (PCSA), as opposed to the anatomical one (ACSA), is the total area of the cross-sections perpendicular to the muscle fibers.
The muscle cross-sectional area (blue line in figure 1, also known as anatomical cross-section area, or ACSA) does not accurately represent the number of muscle fibers in the muscle. A better estimate is provided by the total area of the cross-sections perpendicular to the muscle fibers (green lines in figure 1). This measure is known as the physiological cross-sectional area (PCSA), and is commonly calculated and defined by the following formula, developed in 1975 by Alexander and Vernon:
PCSA increases with pennation angle, and with muscle length. In a pennate muscle, PCSA is always larger than ACSA. In a non-pennate muscle, it coincides with ACSA.
However, only a component of that force can be used to pull the tendon in the desired direction. This component, which is the true muscle force (also called tendon force), is exerted along the direction of action of the muscle:
The other component, orthogonal to the direction of action of the muscle (Orthogonal force = Total force × sinΦ) is not exerted on the tendon, but simply squeezes the muscle, by pulling its aponeuroses toward each other.
Notice that, although it is practically convenient to compute PCSA based on volume or mass and fiber length, PCSA (and therefore the total fiber force, which is proportional to PCSA) is not proportional to muscle mass or fiber length alone. Namely, the maximum (tetanic
) force of a muscle fiber simply depends on its thickness (cross-section area) and type. By no means it depends on its mass or length alone. For instance, when muscle mass increases due to physical development
during childhood, this may be only due to an increase in length of the muscle fibers, with no change in fiber thickness (PCSA) or fiber type. In this case, an increase in mass does not produce an increase in force.
Sometimes, the increase in mass is associated with an increase in thickness. Only in this case it will have some effect on fiber force, but this effect will be proportional to the increase in thickness, not to the increase in mass. For instance, in some stages of physical development, the increase in mass may be due to both an increase in PCSA and in fiber length. Even in this case, muscle force does not increase as much as muscle mass does, because the mass increase is partly produced by a variation in fiber length, and fiber length has no effect on muscle force.
The comparison shows that
in a pennate muscle, since cosΦ is always smaller than 1, PCSA2 is always smaller than PCSA. Hence, it cannot be described as the total area of the cross-sections perpendicular to the muscle fibers (green lines in figure 1). It can be interpreted two ways:
This implies that, in a muscle such as that in figure 1A, PCSA2 coincides with ACSA. The disadvantage of this definition is its more complex interpretation, its advantage is that muscle force can be computed more directly:
Currently, some authors keep using the original definition of PCSA, probably because of its intuitively appealing geometrical interpretation (figure 1).
Pennate muscle
A pennate or pinnate muscle is a muscle with fascicles that attach obliquely to its tendon...
s, the physiological cross-sectional area (PCSA), as opposed to the anatomical one (ACSA), is the total area of the cross-sections perpendicular to the muscle fibers.
Definition
One advantage of pennate muscles is that more muscle fibers can be packed in parallel, thus allowing the muscle to produce more force, although the fiber angle to the direction of action means that the maximum force in that direction is somewhat less than the maximum force in the fiber direction.The muscle cross-sectional area (blue line in figure 1, also known as anatomical cross-section area, or ACSA) does not accurately represent the number of muscle fibers in the muscle. A better estimate is provided by the total area of the cross-sections perpendicular to the muscle fibers (green lines in figure 1). This measure is known as the physiological cross-sectional area (PCSA), and is commonly calculated and defined by the following formula, developed in 1975 by Alexander and Vernon:
PCSA increases with pennation angle, and with muscle length. In a pennate muscle, PCSA is always larger than ACSA. In a non-pennate muscle, it coincides with ACSA.
Estimating muscle force from PCSA
The total force exerted by the fibers in their oblique direction is proportional to PCSA. If the specific tension of the muscle fibers is known (force exerted by the fibers per unit of PCSA), it can be computed as follows:However, only a component of that force can be used to pull the tendon in the desired direction. This component, which is the true muscle force (also called tendon force), is exerted along the direction of action of the muscle:
The other component, orthogonal to the direction of action of the muscle (Orthogonal force = Total force × sinΦ) is not exerted on the tendon, but simply squeezes the muscle, by pulling its aponeuroses toward each other.
Notice that, although it is practically convenient to compute PCSA based on volume or mass and fiber length, PCSA (and therefore the total fiber force, which is proportional to PCSA) is not proportional to muscle mass or fiber length alone. Namely, the maximum (tetanic
Tetanic contraction
A tetanic contraction occurs when a motor unit has been maximally stimulated by its motor neuron. This occurs when a muscle's motor unit is stimulated at a sufficiently high frequency of multiple impulses. Each stimulus causes a twitch. If stimuli are delivered slow enough, the tension in the...
) force of a muscle fiber simply depends on its thickness (cross-section area) and type. By no means it depends on its mass or length alone. For instance, when muscle mass increases due to physical development
Human development (biology)
Human development is the process of growing to maturity. In biological terms, this entails growth from a one-celled zygote to an adult human being.- Biological development:...
during childhood, this may be only due to an increase in length of the muscle fibers, with no change in fiber thickness (PCSA) or fiber type. In this case, an increase in mass does not produce an increase in force.
Sometimes, the increase in mass is associated with an increase in thickness. Only in this case it will have some effect on fiber force, but this effect will be proportional to the increase in thickness, not to the increase in mass. For instance, in some stages of physical development, the increase in mass may be due to both an increase in PCSA and in fiber length. Even in this case, muscle force does not increase as much as muscle mass does, because the mass increase is partly produced by a variation in fiber length, and fiber length has no effect on muscle force.
Alternative definition
In 1987 a different definition of PCSA, herein denoted PCSA2, to facilitate comparison with the previous definition, was introduced by Sacks & Roy:The comparison shows that
in a pennate muscle, since cosΦ is always smaller than 1, PCSA2 is always smaller than PCSA. Hence, it cannot be described as the total area of the cross-sections perpendicular to the muscle fibers (green lines in figure 1). It can be interpreted two ways:
- Projection of PCSA (green line in figure 1) on the anatomical cross-section plane (blue line).
- ACSA of a non-pennate muscle with the same force as the pennate muscle.
This implies that, in a muscle such as that in figure 1A, PCSA2 coincides with ACSA. The disadvantage of this definition is its more complex interpretation, its advantage is that muscle force can be computed more directly:
Currently, some authors keep using the original definition of PCSA, probably because of its intuitively appealing geometrical interpretation (figure 1).