Muscle weakness pathophysiology

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1] Associate Editor(s)-in-Chief: Vishnu Vardhan Serla M.B.B.S. [2]

Pathophysiology

Central

The central component to muscle fatigue is generally described in terms of a reduction in the neural drive or nerve-based motor command to working muscles that results in a decline in the force output.^[1]^[2]^[3] It has been suggested that the reduced neural drive during exercise may be a protective mechanism to prevent organ failure if the work was continued at the same intensity.^[4]^[5] The exact mechanisms of central fatigue are unknown although there has been a great deal of interest in the role of serotonergic pathways.^[6]^[7]^[8]

Neural

Nerves are responsible for controlling the contraction of muscles, determining the number, sequence and force of muscular contraction. Most movements require a force far below what a muscle could in potential generate, and barring pathology nervous fatigue is seldom an issue. For extremely powerful contractions that are close to the upper limit of a muscle's ability to generate force, nervous fatigue can be a limiting factor in untrained individuals. In novice strength trainers, the muscle's ability to generate force is most strongly limited by nerve’s ability to sustain a high-frequency signal. After a period of maximum contraction, the nerve’s signal reduces in frequency and the force generated by the contraction diminishes. There is no sensation of pain or discomfort, the muscle appears to simply ‘stop listening’ and gradually cease to move, often going backwards. As there is insufficient stress on the muscles and tendons, there will often be no delayed onset muscle soreness following the workout. Part of the process of strength training is increasing the nerve's ability to generate sustained, high frequency signals which allow a muscle to contract with their greatest force. It is this neural training that causes several weeks worth of rapid gains in strength, which level off once the nerve is generating maximum contractions and the muscle reaches its physiological limit. Past this point, training effects increase muscular strength through myofibrilar or sarcoplasmic hypertrophy and metabolic fatigue becomes the factor limiting contractile force.

Peripheral

Peripheral muscle fatigue during physical work is considered an inability for the body to supply sufficient energy or other metabolites to the contracting muscles to meet the increased energy demand. This is the most common case of physical fatigue--affecting a national average of 72% of adults in the work force in 2002. This causes contractile dysfunction that is manifested in the eventual reduction or lack of ability of a single muscle or local group of muscles to do work. The insufficiency of energy, i.e. sub-optimal aerobic metabolism, generally results in the accumulation of lactic acid and other acidic anaerobic metabolic by-products in the muscle, causing the stereotypical burning sensation of local muscle fatigue.

The fundamental difference between the peripheral and central theories of muscle fatigue is that the peripheral model of muscle fatigue assumes failure at one or more sites in the chain that initiates muscle contraction. Peripheral regulation is therefore dependent on the localized metabolic chemical conditions of the local muscle affected, whereas the central model of muscle fatigue is an integrated mechanism that works to preserve the integrity of the system by initiating muscle fatigue through muscle derecruitment, based on collective feedback from the periphery, before cellular or organ failure occurs. Therefore the feedback that is read by this central regulator could include chemical and mechanical as well as cognitive cues. The significance of each of these factors will depend on the nature of the fatigue-inducing work that is being performed.

Though not universally used, ‘metabolic fatigue’ is a common alternative term for peripheral muscle weakness, because of the reduction in contractile force due to the direct or indirect effects of the reduction of substrates or accumulation of metabolites within the muscle fiber. This can occur through a simple lack of energy to fuel contraction, or interference with the ability of Ca²⁺ to stimulate actin and myosin to contract.

Substrates

Substrates within the muscle generally serve to power muscular contractions. They include molecules such as adenosine triphosphate (ATP), glycogen and creatine phosphate. ATP binds to the myosin head and causes the ‘ratchetting’ that results in contraction according to the sliding filament model. Creatine phosphate stores energy so ATP can be rapidly regenerated within the muscle cells from adenosine diphosphate (ADP) and inorganic phosphate ions, allowing for sustained powerful contractions that last between 5-7 seconds. Glycogen is the intramuscular storage form of glucose, used to generate energy quickly once intramuscular creatine stores are exhausted, producing lactic acid as a metabolic byproduct.

Substrates produce metabolic fatigue by being depleted during exercise, resulting in a lack of intracellular energy sources to fuel contractions. In essence, the muscle stops contracting because it lacks the energy to do so.

Metabolites

Metabolites are the substances (generally waste products) produced as a result of muscular contraction. They include ADP, Mg²⁺, reactive oxygen species and inorganic phosphate. Accumulation of metabolites can directly or indirectly produce metabolic fatigue within muscle fibers through interference with the release of calcium from the sarcoplasmic reticulum or reduction of the sensitivity of contractile molecules actin and myosin to calcium.

Chloride

Intracellular chloride inhibits the contraction of muscles, preventing them from contracting due to "false alarms", small stimuli which may cause them to contract (akin to myoclonus). This natural brake helps muscles respond solely to the conscious control or spinal reflexes but also has the effect of reducing the force of conscious contractions.

Potassium

High concentrations of potassium also causes the muscle cells to decrease in efficiency, causing cramping and fatigue. Potassium builds up in the t-tubule system and around the muscle fiber in general. This has the effect of depolarizing the muscle fiber, preventing the sodium-potassium pump from moving Na⁺ out of the cell. This reduces the amplitude of action potentials, or stops them entirely, resulting in neurological fatigue.

Lactic Acid

It was once believed that lactic acid build-up was the cause of muscle fatigue.^[9] The assumption was lactic acid had a "pickling" effect on muscles, inhibiting their ability to contract. The impact of lactic acid on performance is now uncertain, it may assist or hinder muscle fatigue.

Produced as a by-product of fermentation, lactic acid can increase intracellular acidity of muscles. This can lower the sensitivity of contractile apparatus to Ca²⁺ but also has the effect of increasing cytoplasmic Ca²⁺ concentration through an inhibition of the chemical pump that actively transports calcium out of the cell. This counters inhibiting effects of K⁺ on muscular action potentials. Lactic acid also has a negating effect on the chloride ions in the muscles, reducing their inhibition of contraction and leaving potassium ions as the only restricting influence on muscle contractions, though the effects of potassium are much less than if there were no lactic acid to remove the chloride ions. Ultimately, it is uncertain if lactic acid reduces fatigue through increased intracellular calcium or increases fatigue through reduced sensitivity of contractile proteins to Ca²⁺.

Associated Conditions

Muscle weakness may be due to problems with the nerve supply, neuromuscular disease such as myasthenia gravis or problems with muscle itself. The latter category includes polymyositis and other muscle disorders.

References

↑ Gandevia SC (2001). "Spinal and supraspinal factors in human muscle fatigue". Physiol. Rev. 81 (4): 1725–89. PMID 11581501.
↑ Kay D, Marino FE, Cannon J, St Clair Gibson A, Lambert MI, Noakes TD (2001). "Evidence for neuromuscular fatigue during high-intensity cycling in warm, humid conditions". Eur. J. Appl. Physiol. 84 (1–2): 115–21. PMID 11394239.
↑ Vandewalle H, Maton B, Le Bozec S, Guerenbourg G (1991). "An electromyographic study of an all-out exercise on a cycle ergometer". Archives internationales de physiologie, de biochimie et de biophysique. 99 (1): 89–93. PMID 1713492.
↑ Bigland-Ritchie B, Woods JJ (1984). "Changes in muscle contractile properties and neural control during human muscular fatigue". Muscle Nerve. 7 (9): 691–9. doi:10.1002/mus.880070902. PMID 6100456.
↑ Noakes TD (2000). "Physiological models to understand exercise fatigue and the adaptations that predict or enhance athletic performance". Scandinavian journal of medicine & science in sports. 10 (3): 123–45. PMID 10843507.
↑ Davis JM (1995). "Carbohydrates, branched-chain amino acids, and endurance: the central fatigue hypothesis". International journal of sport nutrition. 5 Suppl: S29–38. PMID 7550256.
↑ Newsholme, E. A., Acworth, I. N., & Blomstrand, E. 1987, 'Amino acids, brain neurotransmitters and a functional link between muscle and brain that is important in sustained exercise', in G Benzi (ed.), Advances in Myochemistry, Libbey Eurotext, London, pp. 127-133.
↑ Newsholme EA, Blomstrand E (1995). "Tryptophan, 5-hydroxytryptamine and a possible explanation for central fatigue". Adv. Exp. Med. Biol. 384: 315–20. PMID 8585461.
↑ Muscle fatigue and lactic acid accumulation. abstract

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[1] Gandevia SC (2001). "Spinal and supraspinal factors in human muscle fatigue". Physiol. Rev. 81 (4): 1725–89. PMID 11581501.

[2] Kay D, Marino FE, Cannon J, St Clair Gibson A, Lambert MI, Noakes TD (2001). "Evidence for neuromuscular fatigue during high-intensity cycling in warm, humid conditions". Eur. J. Appl. Physiol. 84 (1–2): 115–21. PMID 11394239.

[3] Vandewalle H, Maton B, Le Bozec S, Guerenbourg G (1991). "An electromyographic study of an all-out exercise on a cycle ergometer". Archives internationales de physiologie, de biochimie et de biophysique. 99 (1): 89–93. PMID 1713492.

[4] Bigland-Ritchie B, Woods JJ (1984). "Changes in muscle contractile properties and neural control during human muscular fatigue". Muscle Nerve. 7 (9): 691–9. doi:10.1002/mus.880070902. PMID 6100456.

[5] Noakes TD (2000). "Physiological models to understand exercise fatigue and the adaptations that predict or enhance athletic performance". Scandinavian journal of medicine & science in sports. 10 (3): 123–45. PMID 10843507.

[6] Davis JM (1995). "Carbohydrates, branched-chain amino acids, and endurance: the central fatigue hypothesis". International journal of sport nutrition. 5 Suppl: S29–38. PMID 7550256.

[7] Newsholme, E. A., Acworth, I. N., & Blomstrand, E. 1987, 'Amino acids, brain neurotransmitters and a functional link between muscle and brain that is important in sustained exercise', in G Benzi (ed.), Advances in Myochemistry, Libbey Eurotext, London, pp. 127-133.

[8] Newsholme EA, Blomstrand E (1995). "Tryptophan, 5-hydroxytryptamine and a possible explanation for central fatigue". Adv. Exp. Med. Biol. 384: 315–20. PMID 8585461.

[9] Muscle fatigue and lactic acid accumulation. abstract

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