Microscopic Components of Muscles

myofibril

sarcomere

myosin

actin

troponin and tropomyosin

collagen and elastin

hemoglobin and myoglobin

actin and myosin

Sarcomeres are organized in a spiral pattern within a muscle fiber.

Sarcomeres are only found at the ends of a muscle fiber.

Sarcomeres are organized in a repeating pattern along the length of the muscle fiber.

Sarcomeres are randomly distributed within a muscle fiber.

The sliding filament theory explains how muscles contract by the sliding of actin and myosin filaments.

The sliding filament theory explains how muscles contract by the sliding of actin and tropomyosin filaments.

The sliding filament theory explains how muscles contract by the sliding of myosin and troponin filaments.

The sliding filament theory explains how muscles contract by the sliding of actin and troponin filaments.

Muscle contraction is the process in which muscle fibers generate tension and shorten in length.

Muscle contraction is the process in which muscle fibers relax and lengthen.

Muscle contraction is the process in which muscle fibers do not generate tension.

Muscle contraction is the process in which muscle fibers only generate tension but do not shorten in length.

actin and myosin

actin and ATP

myosin and myosin

actin and actin

The sliding filament theory explains muscle contraction by stating that during contraction, the thin actin filaments slide over the thick myosin filaments, causing the sarcomeres to shorten.

The sliding filament theory explains muscle contraction by stating that the thin actin filaments remain stationary while the thick myosin filaments contract, causing the sarcomeres to lengthen.

The sliding filament theory explains muscle contraction by stating that the thin actin filaments detach from the thick myosin filaments, causing the sarcomeres to lengthen.

The sliding filament theory explains muscle contraction by stating that the thin actin filaments push the thick myosin filaments, causing the sarcomeres to lengthen.