Muscles are fascinating. Did you know there are many different types of muscles in the body? Did you also know that most muscles work in pairs? They carry out different types of contractions to generate movement.
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Jetzt kostenlos anmeldenMuscles are fascinating. Did you know there are many different types of muscles in the body? Did you also know that most muscles work in pairs? They carry out different types of contractions to generate movement.
Muscle cells are classified into two categories based on their appearance: striated and non-striated (Figure 1).
Striated muscles are further broken down into two types, skeletal and cardiac muscles. One important feature that is common among striated muscles is that they contain myoglobin (a binding protein for oxygen and iron found in the cardiac and skeletal muscle tissues of vertebrates).
Skeletal muscle: (also known as voluntary muscle). These muscles are:
The most common type of muscles in our body.
Under conscious control.
Attached to bones via tendons. They allow voluntary movement of limbs and the skeleton.
Examples:
Bicep muscles
Tricep muscles
Quadricep muscles
Cardiac muscle: (also known as myocardium).
This muscle is only found in the heart.
Its function is to contract and pump blood throughout the body.
Controlled involuntarily.
Non-striated muscles: (also known as smooth muscle). These muscles are different from skeletal muscles.
They do not contain any myoglobin.
They are controlled involuntarily.
They have various roles and functions in the body:
Myoglobin is a red protein that is structurally similar to a single subunit of haemoglobin.
While myoglobin and haemoglobin are both oxygen-storing molecules, myoglobin has a higher affinity for oxygen than haemoglobin (Figure 2). As a result, haemoglobin gives up oxygen to myoglobin, especially at low pH.
This behaviour is particularly important during an intense muscular activity where there will be a shortage of oxygen, and muscles will undergo anaerobic respiration.
A by-product produced during anaerobic respiration is lactic acid which lowers the pH in the muscles. Hence, during intense muscular activity, haemoglobin gives up oxygen more readily in the muscles to myoglobin. This oxygen is used in aerobic respiration to generate the ATP needed for muscle contraction.
Affinity level of a molecule refers to how well it can interact and bind with another. This is reported by the equilibium dissociation constant ().
Figure 2 shows the ability of myoglobin and haemoglobin to bind oxygen. "" refers to partial pressure of oxygen, and " saturation" refers to how saturated myglobin and haemoglobin are with oxygen. As the partial pressure of oxygen gas increases, the oxygen saturation also increases until haemoglobin/myoglobin are saturated. Myoglobin has a higher affinity for oxygen and, therefore, it will become saturated with oxygen at lower pressures.
Skeletal muscle contractions are classified into two types based on the length of the muscle during contraction. These two types are isometric and isotonic.
Isometric contractions generate force and tension while the muscle length stays relatively constant.
For example, muscles in the hand and forearm undergo isometric contraction when you make a tight grip. Another example would be during a biceps curl when you are holding a dumbbell in a static position instead of actively raising or lowering it (Figure 3).
As opposed to isometric contractions, the tension remains constant during isotonic contractions while the muscle length changes. Depending on the change in the muscle length, isotonic contractions can be either concentric or eccentric.
Concentric contraction is a type of muscle activity that generates tension and force to move an object as the muscle shortens. Cross-bridge cycling between actin and myosin myofilaments and shortening of sarcomeres occur in concentric contraction.
This is the most common type of muscle contraction in our body.
For example, while lifting a dumbbell during a biceps curl, a concentric contraction causes the arm to bend at the elbow and lift the weight towards the shoulder (Figure 4).
During an eccentric contraction, the muscle elongates while still generating force. In other words, the resistance against the muscle is greater than the force generated, resulting in muscle elongation. Eccentric contraction is the strongest type of contraction which is mainly used for controlled weight movements.
Eccentric contractions can be either voluntary or involuntary. For instance, voluntary eccentric contraction allows the controlled lowering of a heavyweight object raised by a concentric contraction. An example of an involuntary eccentric contraction would be the involuntary lowering of a too-heavy object that slowly lowers under tension.
Cross-bridge cycles between actin and myosin filaments still occur in eccentric contraction, but the sarcomere and muscle length are elongated.
Muscle cells (myofibers) contain contractile proteins such as actin and myosin filaments, collectively called myofilaments.
In skeletal muscles, these myofilaments are arranged into groups called sarcomeres which cause the myofibers to have a striated appearance (Figure 6).
Following nervous stimulation and release of calcium ions into the muscle fibre’s cytoplasm, the thin actin and thick myosin filaments slide past each other in a process called the sliding filament theory. Briefly, this process is driven by cross-bridges that extend from myosin filaments and recurrently interact with the actin filaments (Figure 7).
Muscle contraction is high energy-demanding activity. This energy is supplied via ATP hydrolysis at myosin heads. As a result of these fibres sliding over one another, the sarcomeres and muscle fibres shorten, leading to muscle contraction.
Muscles only produce tension which does not lead to effective movement unless it is being acted upon a structure that does not change shape, i.e., bone. Therefore, the movement of limbs requires both muscles and a firm skeleton.
Skeletal muscles are the most common type of muscles in the human body, with over 600 of them crossing over each other in multiple directions.
Muscles are usually attached to bones via lengths of very strong connective tissue called tendons. One of the many important properties of tendons is that despite their high flexibility, they do not stretch when the muscle contracts and pulls on them. Hence, they transmit all the generated force onto the bone. Some muscles have very long tendons, and others directly attach to bones.
Not all tendons are attached to bones, though. Some tendons connect muscles to the tendons of other muscles, such as the lumbrical muscles in the hand, which are connected to the FDP tendons.
Muscles are only capable of producing tension by pulling or contracting. Hence, they are unable to push or compress. Because of this limitation, muscles have to work in pairs to generate movements in different directions.
When two different muscles pull at a joint in opposite directions, they are acting antagonistically to each other. An example of antagonistic muscle action can be seen in the quadriceps and hamstring muscles of the thigh when we flex and extend our leg at the knee joint (Figure 8).
To extend the knee: the quadriceps muscles contract and the hamstrings relax.
To bend the knee: the hamstring muscles contract and the quadriceps relax.
Again, it is important to point out that this antagonistic action results in movement due to the incompressible bones.
One of the main functions of muscles is to maintain posture. This is achieved when pairs of antagonistic muscles contract isometrically at joints to keep the joint angle constant.
In most cases, lifting heavy objects requires a more complicated contraction process with more muscles involved. For example, the biceps brachii muscles are the prime flexors of the elbow. In addition to biceps brachii, brachialis and brachioradialis muscles also flex the elbow when they contract (Figure 9). Therefore, these muscles are said to act synergistically, meaning that they assist each other during contraction.
Muscle contraction is stimulated when an action potential from a motor neuron reaches the muscle. The action potential triggers an increase in the calcium ion concentration in the sarcoplasm. Calcium ions play a key role in cross-bridge formation between actin and myosin filaments. The energy released from ATP hydrolysis is utilised for the sliding of actin and myosin filaments over each other in a process called the sliding filament theory. As a result, the sarcomeres and muscle fibres shorten, causing muscle contraction.
During muscle contraction, the actin and myosin filaments slide past each other. Therefore, the sarcomeres and muscle fibres shorten in length. Skeletal muscles are attached to bones either directly or via tendons or by aponeuroses. The force created by the sliding of myofilaments during muscle contraction is transmitted to bones. Due to the rigid nature of bones, this force results in a change of angle at the joints and brings about movement.
Action potential received from a motor neuron triggers the release of calcium ions from the sarcoplasmic reticulum. Calcium ions bind to troponin C and cause movement of tropomyosin away from actin-binding sites. Hence, allowing myosin and actin cross-bridge formation. The repeating cycle of actin and myosin cross-bridge formations, driven by ATP hydrolysis, results in the shortening of the sarcomeres’ length and causing muscle contraction.
When stimulated by a motor neuron, a skeletal muscle fibre contracts as the thin actin filaments are pulled and then slide past the thick myosin filaments within the myofiber's sarcomeres. This process generates tension and force, which are transferred to the skeletal system either directly or via tendons.
The plank, holding the dumbbell during a biceps curl, sitting stationary.
Name the three types of muscle in the body and give one example of each.
1. Cardiac muscle found exclusively in the heart (myocardium)
2. Smooth muscle, found in the walls of blood vessels and the gut.
3. Skeletal muscle, Biceps brachii
What is the role of myoglobin in striated muscles?
Myoglobin has a higher affinity for oxygen than haemoglobin. Therefore, it assists in unloading oxygen from haemoglobin and delivering it to muscles during intense activity.
Define the terms isometric and isotonic contraction.
Isometric contraction: Generation of tension in the muscle while its length remains constant.
Isotonic contraction: Tension remains constant, but muscle length changes.
Name the three types of muscle contraction.
Isometric, concentric isotonic, and eccentric isotonic contractions
Why do sarcomeres shorten in length during muscle contraction?
Due to actin and myosin filaments sliding over one another.
What is the source of energy for muscle contraction?
ATP hydrolysis by the myosin head.
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