Stikkordarkiv: Betennelser

Ukjent sin avatar

Magnesium: Novel Applications in Cardiovascular Disease – A Review of the Literature

av

En review studie fra 2012 som inneholder det meste om Magnesium, spesielt rettet mot betennelser i hjerte/kar og nervesystemet.

http://www.karger.com/Article/FullText/339380

Magnesium L-lactate and L-aspartate are the oral magnesium compounds that have the greatest bioavailability, are the most water-soluble and have the greatest serum and plasma concentrations [8].

After a mean follow-up of 9.8 years and adjusting for confounders, the authors concluded that women in the highest quintile (an intake of 400 mg/day of magnesium) had a decreased HTN (hypertension) risk (p < 0.0001) versus those in the lowest quintile (approx. 200 mg/day of magnesium) [20].

Because of magnesium’s anti-inflammatory, statin-like and anti-mineralizing effects, a role for it is emerging in cardiovascular and neurological medicine.

The potential impact of magnesium in cardiovascular and neurological health, the abundance and low cost of the supplement, the relatively low side effect profile and the paucity of information in the literature about this common mineral suggest that more studies should be conducted to determine its safety and efficacy. The majority of human trials with magnesium thus far have not been interventional, but based on food questionnaires which may not be accurate and are subject to a recall bias. Further work is also needed to determine the mechanism of action by which magnesium modulates the mineralization and inflammation of the cardiovascular and nervous systems.

Ukjent sin avatar

Co-administration of the health food supplement, bovine colostrum, reduces the acute non-steroidal anti-inflammatory drug-induced increase in intestinal permeability

av

Nevner at Colostrum reduserer problemer med lekk tarm fra overforbruk av betennelsesdempende medikamenter som NSAIDS. 5 dager med betennelsesdempende 3x daglig ga 3 ganger så mye lekk tarm. De sammenlignet Colostrum med Whey Protein for fant at colostrum gan ingen økning i lekk tarm selv om de gikk på betennelsesdempende.

http://www.clinsci.org/cs/100/0627/cs1000627.htm

Non-steroidal anti-inflammatory drugs (NSAIDs) are effective analgesics but cause gastrointestinal injury. Present prophylactic measures are suboptimal and novel therapies are required. Bovine colostrum is a cheap, readily available source of growth factors, which reduces gastrointestinal injury in rats and mice. We therefore examined whether spray-dried, defatted colostrum could reduce the rise in gut permeability (a non-invasive marker of intestinal injury) caused by NSAIDs in volunteers and patients taking NSAIDs for clinical reasons. Healthy male volunteers (n = 7) participated in a randomized crossover trial comparing changes in gut permeability (lactulose/rhamnose ratios) before and after 5 days of 50 mg of indomethacin three times daily (tds) per oral with colostrum (125 ml, tds) or whey protein (control) co-administration. A second study examined the effect of colostral and control solutions (125 ml, tds for 7 days) on gut permeability in patients (n = 15) taking a substantial, regular dose of an NSAID for clinical reasons. For both studies, there was a 2 week washout period between treatment arms. In volunteers, indomethacin caused a 3-fold increase in gut permeability in the control arm (lactulose/rhamnose ratio 0.36±0.07 prior to indomethacin and 1.17±0.25 on day 5, P < 0.01), whereas no significant increase in permeability was seen when colostrum was co-administered. In patients taking long-term NSAID treatment, initial permeability ratios were low (0.13±0.02), despite continuing on the drug, and permeability was not influenced by co-administration of test solutions. These studies provide preliminary evidence that bovine colostrum, which is already currently available as an over-the-counter preparation, may provide a novel approach to the prevention of NSAID-induced gastrointestinal damage in humans.

Ukjent sin avatar

The nutriceutical bovine colostrum truncates the increase in gut permeability caused by heavy exercise in athletes

av

Studie som nevner at hard trening gir lekk tarm, og at Colostrum (hoppemelk) lukker tarmen. Dette kan forklare hvorfor så mange vektløftere og toppidrettsutøver har problemer med tarm og immunsystem. I studien brukte de 20g colostrum daglig, som er ganske mye.

http://ajpgi.physiology.org/content/300/3/G477

Heavy exercise causes gut symptoms and, in extreme cases, “heat stroke” partially due to increased intestinal permeability of luminal toxins. We examined bovine colostrum, a natural source of growth factors, as a potential moderator of such effects. Twelve volunteers completed a double-blind, placebo-controlled, crossover protocol (14 days colostrum/placebo) prior to standardized exercise. Gut permeability utilized 5 h urinary lactulose-to-rhamnose ratios. In vitro studies (T84, HT29, NCM460 human colon cell lines) examined colostrum effects on temperature-induced apoptosis (active caspase-3 and 9, Baxα, Bcl-2), heat shock protein 70 (HSP70) expression and epithelial electrical resistance. In both study arms, exercise increased blood lactate, heart rate, core temperature (mean 1.4°C rise) by similar amounts. Gut hormone profiles were similar in both arms although GLP-1 levels rose following exercise in the placebo but not the colostrum arm (P = 0.026). Intestinal permeability in the placebo arm increased 2.5-fold following exercise (0.38 ± 0.012 baseline, to 0.92 ± 0.014, P < 0.01), whereas colostrum truncated rise by 80% (0.38 ± 0.012 baseline to 0.49 ± 0.017) following exercise. In vitro apoptosis increased by 47–65% in response to increasing temperature by 2°C. This effect was truncated by 60% if colostrum was present (all P < 0.01). Similar results were obtained examining epithelial resistance (colostrum truncated temperature-induced fall in resistance by 64%, P < 0.01). Colostrum increased HSP70 expression at both 37 and 39°C (P < 0.001) and was truncated by addition of an EGF receptor-neutralizing antibody. Temperature-induced increase in Baxα and reduction in Bcl-2 was partially reversed by presence of colostrum. Colostrum may have value in enhancing athletic performance and preventing heat stroke.

SEVERAL STRESSES AFFECT the integrity of the intestinal barrier. These include prolonged strenuous exercise (10), heat stress (11), and drugs such as nonsteroidal anti-inflammatory agents. Loss of intestinal barrier integrity leading to increased intestinal permeability may result in passage of luminal endotoxins into the circulation. This, in turn, results in an inflammatory cascade, exacerbating the loss of barrier function and, in severe cases, resulting in severe systemic effects.

Gastrointestinal symptoms including cramps, diarrhea, nausea, and bleeding are commonly reported by long-distance runners (16). These symptoms are likely to be due to a combination of reduced splanchnic blood flow, hormonal changes, altered gut permeability, and increased body temperature.

Colostrum is the first milk produced after birth and is particularly rich in immunoglobulins, antimicrobial peptides (e.g., lactoferrin, lactoperoxidase), and other bioactive molecules including growth factors (20).

We have previously shown, using a combination of in vitro and in vivo studies, that a commercially available defatted bovine colostral preparation can reduce NSAID-induced upper intestinal gut injury in rats, mice, and humans (19, 21).

The total protein content of the colostrum was 80%. The concentrations of the various growth factors present in the colostrum preparation are incompletely defined but include IGF-I at 213 ng/g, TGF-β1 at 113 ng/g, and TGF-β2 at 441 ng/g.

In a double-blind crossover design, subjects received oral supplementation with 20 g/day bovine colostrum or the isoenergetic and isomacronutrient placebo.

Ukjent sin avatar

Neurogenic neuroinflammation: inflammatory CNS reactions in response to neuronal activity

av

Omfattende gjennomgang om hvordan nevrogene betennelser fungerer fysiologisk. Nevner at betennelser ikke er problemet, men en funksjon kroppen benytter seg av for å håndtere problemer som giftstoffer og metabolsk problemer. Derfor nytter det ikke å dempe betennelsen. Man MÅ fjerne årsaken til betennelsen…

http://www.ncbi.nlm.nih.gov/pubmed/24281245

http://www.nature.com/nrn/journal/vaop/ncurrent/full/nrn3617.html

The CNS is endowed with an elaborated response repertoire termed ‘neuroinflammation’, which enables it to cope with pathogens, toxins, traumata and degeneration. On the basis of recent publications, we deduce that orchestrated actions of immune cells, vascular cells and neurons that constitute neuroinflammation are not only provoked by pathological conditions but can also be induced by increased neuronal activity. We suggest that the technical term ‘neurogenic neuroinflammation’ should be used for inflammatory reactions in the CNS in response to neuronal activity. We believe that neurogenic neuro-inflammation maintains homeostasis to enable the CNS to cope with enhanced metabolic demands and increases the computational power and plasticity of CNS neuronal networks. However, neurogenic neuroinflammation may also become maladaptive and aggravate the outcomes of pain, stress and epilepsy.

Ukjent sin avatar

Carbon dioxide and the critically ill—too little of a good thing?

av

Omfattende studie av alle de gode egenskapene ved hyperkapni – høyt CO2 nivå. Nevner mange interessante ting, bl.a. at CO2 indusert acidose gir mye mindre fire radikaler enn om pH senkes av andre faktorer. Bekrefter også at oksygen blir sittende fast på blodcellene ved hypokapni, og at melkesyreproduksjonen begrensens når acidosen er pga CO2 men ikke når den er av andre faktorer.

Spesielt med denne artikkelen er at den beskriver forskjellene på en hyperkapni acidose og acidose av andre faktorer. Hyperkapnisk acidose har beskyttende egenskaper.
http://www.thelancet.com/journals/lancet/article/PIIS0140-6736(99)02388-0/fulltext

Permissive hypercapnia (acceptance of raised concentrations of carbon dioxide in mechanically ventilated patients) may be associated with increased survival as a result of less ventilator-associated lung injury.
Accumulating clinical and basic scientific evidence points to an active role for carbon dioxide in organ injury, in which raised concentrations of carbon dioxide are protective, and low concentrations are injurious.
Although hypercapnic acidosis may indicate tissue dysoxia and predict adverse outcome, it is not necessarily harmful per se. In fact, it may be beneficial. There is increasing evidence that respiratory (and metabolic) acidosis can exert protective effects on tissue injury, and furthermore, that hypocapnia may be deleterious.
If hypoventilation is allowed in an effort to limit lung stretch, carbon dioxide tension increases. Such “permissive hypercapnia” may be associated with increased survival in acute respiratory distress syndrome (ARDS);2 this association is supported by outcome data from a 10-year study.3
Furthermore, hypocapnia shifts the oxyhaemoglobin dissociation curve leftwards, restricting oxygen off-loading at the tissue level; local oxygen delivery may be further impaired by hypocapnia-induced vasoconstriction.
Brain homogenates develop far fewer free radicals and less lipid peroxidation when pH is lowered by carbon dioxide than when it is lowered by hydrochloric acid.19
Finally, greater inhibition of tissue lactate production occurs when lowered pH is due to carbon dioxide than when it is due to hydrochloric acid.20
An association between hypoventilation, hypercapnia, and improved outcome has been established in human beings.2521 In lambs, ischaemic myocardium recovers better in the presence of hypercapnic acidosis than metabolic acidosis.22 Hypercapnic acidosis has also been shown to protect ferret hearts against ischaemia,23 rat brain against ischaemic stroke,16 and rabbit lung against ischaemia-reperfusion injury.24 Hypercapnia attenuates oxygen-induced retinal vascularisation,25 and improves retinal cellular oxygenation in rats.26 “pH-stat” management of blood gases during cardiopulmonary bypass, involving administration of large amounts of additional carbon dioxide for maintenance of temperature-corrected PaCO2, results in better neurological and cardiac outcome.27
Hypercapnia results in a complex interaction between altered cardiac output, hypoxic pulmonary vasoconstriction, and intrapulmonary shunt, with a net increase in PaO2 (figure).28 Because hypercapnia increases cardiac output, oxygen delivery is increased throughout the body.28 Regional, including mesenteric, blood flow is also increased,29 thereby increasing oxygen delivery to organs. Because hypercapnia (and acidosis) shifts the haemoglobin-oxygen dissociation curve rightwards, and may increase packed-cell volume,30 oxygen delivery to tissues is further increased. Acidosis may reduce cellular respiration and oxygen consumption,31 which may further benefit an imbalance between supply and demand, in addition to greater oxygen delivery. One hypothesis32 is that acidosis protects against continued production of further organic acids (by a negative feedback loop) in tissues, providing a mechanism of cellular metabolic shutdown at times of nutrient shortage—eg, ischaemia.
Acidosis attenuates the following inflammatory processes (figure): leucocyte superoxide formation,33 neuronal apoptosis,34phospholipase A2 activity,35 expression of cell adhesion molecules,36 and neutrophil Na+/H+ exchange.37 In addition, xanthine oxidase (which has a key role in reperfusion injury) is inhibited by hypercapnic acidosis.24 Furthermore, hypercapnia upregulates pulmonary nitric oxide38 and neuronal cyclic nucleotide production,39 both of which are protective in organ injury. Oxygen-derived free radicals are central to the pathogenesis of many types of acute lung injury, and in tissue homogenates, hypercapnia attenuates production of free radicals and decreases lipid peroxidation.19 Thus, during inflammatory responses, hypercapnia or acidosis may tilt the balance towards cell salvage at the tissue level.
However, we know from several case series that human beings, and animals, can tolerate exceptionally high concentrations of carbon dioxide, and when adequately ventilated, can recover rapidly and completely. Therefore, high concentrations (if tolerated) may not necessarily cause harm.
From the published studies reviewed, and from the pathological mechanisms assessed, we postulate that changes in carbon dioxide concentration might affect acute inflammation,33—36 tissue ischaemia,16 ischaemia-reperfusion,2024 and other metabolic,1221,32 or developmental14 processes.
We argue that the recent shift in thinking about hypercapnia must now be extended to therapeutic use of carbon dioxide. Our understanding of the biology of disorders in which hypocapnia is a cardinal element would require fundamental reappraisal if hypocapnia is shown to be independently harmful.
In summary, in critically ill patients, future therapeutic goals involving PaCO2 might be expressed as:“keep the PaCO2 high; if necessary, make it high; and above all, prevent it from being low”.
Ukjent sin avatar

Stress and the inflammatory response: a review of neurogenic inflammation.

av

Betennelser kan både skapes og opprettholdes av nervesystemet.

Det er velkjent av betennelser økes av stresshormonet kortisol når vi stresser fordi kortisol senker immunfunksjon og dermed øker betennelsestilstander.

Men denne studien beskriver hvordan stress øker nevrogen betennelse (betennelse i nervesystemet), som kan forklare årsaken til at alt som vanligvis bare er litt ukomfortabelt blåses opp og blir vondere når vi er i langvarig stress.

Man tenker vanligvis på sansenerver som noe som sender signaler fra kroppen, gjennom ryggraden og opp til hjernen. Men molekyler kan faktisk gå andre veien i nervetrådene også. Fra ryggraden og UT i kroppen. Når vi stresser sender nervecellene ut et stoff som kalles Substans P, sammen med andre betennelsesøkende stoffer. Der hvor nervetrådene ender (i ledd, i huden eller i organer) blir det en lokal betennelsesreaksjon som bidrar til smerte. Substans P er spesielt assosisert med smertetilstander.

Forskeren konkluderer også med at dette er en viktig årsak til hvordan kronisk stress kan bidra til kroniske betennelsessykdommer som arterosklreose i blodårene eller betennelser i organene.

Beste måten å roe ned et stresset nervesystem er meditasjon med Autonom pust (5-6 pust i minuttet).

http://www.ncbi.nlm.nih.gov/pubmed/12480495

The subject of neuroinflammation is reviewed. In response to psychological stress or certain physical stressors, an inflammatory process may occur by release of neuropeptides, especially Substance P (SP), or other inflammatory mediators, from sensory nerves and the activation of mast cells or other inflammatory cells.

Central neuropeptides, particularly corticosteroid releasing factor (CRF), and perhaps SP as well, initiate a systemic stress response by activation of neuroendocrinological pathways such as the sympathetic nervous system, hypothalamic pituitary axis, and the renin angiotensin system, with the release of the stress hormones (i.e., catecholamines, corticosteroids, growth hormone, glucagons, and renin). These, together with cytokines induced by stress, initiate the acute phase response (APR) and the induction of acute phase proteins, essential mediators of inflammation. Central nervous system norepinephrine may also induce the APR perhaps by macrophage activation and cytokine release. The increase in lipids with stress may also be a factor in macrophage activation, as may lipopolysaccharide which, I postulate, induces cytokines from hepatic Kupffer cells, subsequent to an enhanced absorption from the gastrointestinal tract during psychologic stress.

The brain may initiate or inhibit the inflammatory process.

The inflammatory response is contained within the psychological stress response which evolved later. Moreover, the same neuropeptides (i.e., CRF and possibly SP as well) mediate both stress and inflammation.

Cytokines evoked by either a stress or inflammatory response may utilize similar somatosensory pathways to signal the brain. Other instances whereby stress may induce inflammatory changes are reviewed.

I postulate that repeated episodes of acute or chronic psychogenic stress may produce chronic inflammatory changes which may result in atherosclerosis in the arteries or chronic inflammatory changes in other organs as well.

Ukjent sin avatar

Hypercapnic Acidosis Attenuates Endotoxin-Induced Nuclear Factor-κB Activation

av

En studie til som nevner at økt CO2 i blodet (hypercapni) virker beskyttende fordi det demper betennelser, spesielt betennelsesfaktoren IL-8.

I denen Studien er pH helt nede på 7,0 og CO2 oppe i 75mmHg.

http://www.atsjournals.org/doi/full/10.1165/rcmb.2002-0126OC#.Un3l55Ez448

Although the protective effects of the hypoventilation technique for treating ARDS patients have been considered to be the consequence of a low tidal volume decreasing excessive mechanical stretch of lung tissue (45), the findings of the present study indicate that the benefits are provided not only by decreased stretch, but also by coexisting hypercapnic acidosis having anti-inflammatory effects. These facts suggest that the protective effects of the hypoventilation technique during treatment of ARDS patients may be enhanced when coexisting hypercapnic acidosis is not corrected either by increasing respiratory frequency or by adding sodium bicarbonate.

Ukjent sin avatar

Muscle Pain: Mechanisms and Clinical Significance

av

En studie til fra Siegfried Mense, om muskelsmerter. Han har ikke fått med seg at trykksensitive nerver kun finnes i huden. Og han har misforstått litt i forskjellene mellom hud-smerter og muskel-smerter siden han sier at hud-smerter ikke kan ha utstrålende effekt. Han har tydeligvis ikke ikke inkludert subcutane nerver i sin vurdering.

Men mye interessant i denne studien likevel. Spesielt vektleggingen av at lav pH er den viktigste bidragsyteren til muskelsmerter.

Han nevner at input fra muskel-nociceptorer har større relevans i ryggmargen enn input fra huden. Derfor er betennelser og lav pH de viktigste drivkreftene i kroniske smerter.

Nevner også at smerter henger sammen, f.eks. at trapezius kan stramme seg for å beskytte brachialis, slik at smerten kjennes i trapezius, mens problemet egentlig sitter i brachialis.

Beskriver også triggerpunkter, men sier at det foreløpig er veldig mange ubesvarte spørsmål om denne teorien.

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2696782

Muscle pain is a major medical problem: in, the majority (60% to 85%) of the population has had (nonspecific) back pain of muscular origin at some time or other (lifetime prevalence) (1). Pain evoked by myofascial trigger points has a point prevalence of approximately 30% (2). More than 7% of all women aged 70 to 80 years suffer from the fibromyalgia syndrome (e1). In an Italian study, musculoskeletal pain was found to be the most common reason that patients consulted a doctor (3). Thus, treating physicians should be aware of the mechanisms of muscle pain, insofar as they are currently understood.

Subjective differences between muscle pain and cutaneous pain

Muscle pain Cutaneous pain
Electrical nerve stimulation induces only one pain Electrical nerve stimulation induces a first pain and a second pain
Poorly localizable Well-localized
Tearing, cramping, pressing quality Stabbing, burning, cutting quality
Marked tendency toward referral of pain No tendency toward referral of pain
Affective aspect: difficult to tolerate Affective aspect: easier to tolerate

Muscle pain is produced by the activation of specific receptors (so-called nociceptors): these receptors are specialized for the detection of stimuli that are objectively capable of damaging tissue and that are subjectively perceived as painful. They consist of free nerve endings and are connected to the central nervous system (CNS) by way of unmyelinated (group IV) or thinly myelinated (group III) fibers. They can be sensitized and activated by strong mechanical stimuli, such as trauma or mechanical overloading, as well as by endogenous inflammatory mediators including bradykinin (BK), serotonin, and prostaglandin E2 (PGE2).

Two activating chemical substances are particularly important for the generation of muscle pain: adenosine triphosphate (ATP) and protons (H+ ions).

ATP activates muscle nociceptors mainly by binding to the P2X3 receptor molecule, H+ mainly by binding to the receptor molecules TRPV1 (transient receptor potential vanilloid 1) and ASICs (acid-sensing ion channels) (4).

ATP is found in all cells of the body and is released whenever bodily tissues of any type are injured.

A drop in pH is probably one of the main activators of peripheral nociceptors, as many painful disturbances of muscle are associated with low pH in muscle tissue.

Nerve growth factor (NGF) also has a connection to muscle pain: NGF is synthesized in muscle and activates muscle nociceptors (e2). NGF synthesis is increased when a muscle is inflamed (e3).

Acidic tissue pH is one of the main activating factors leading to muscle pain. Practically all pathological and pathophysiological changes of skeletal muscle are accompanied by a drop in pH, among them

  • chronic ischemic states,
  • tonic contractions or spasms,
  • myofascial trigger points,
  • (occupationally induced) postural abnormalities, and
  • myositides.

The neuropeptides stored in muscle nociceptors are released not only when peripheral stimuli activate the nerve endings, but also when spinal nerves are compressed. In this type of neuropathic pain, action potentials are generated at the site of compression and spread not only centripetally, i.e., toward the central nervous system, but also centrifugally, i.e., toward the nociceptive endings, where they induce the release of vasoactive neuropeptides. In this way, neurogenic inflammation comes about, characterized by hyperemia, edema, and the release of inflammatory mediators (8). The inflammatory mediators sensitize the muscle nociceptors and thereby increase neuropathic pain.

The sensitization of the muscle nociceptors by endogenous mediators such as BK and PGE2 is one of the reasons why patients with muscle lesions suffer from tenderness to pressure on the muscle, and from pain on movement or exercise. It is also the reason why many types of muscle pain respond well to the administration of non-steroidal anti-inflammatory drugs (NSAID), which block prostaglandin synthesis.

An influx of nervous impulses from muscle nociceptors into the spinal cord increases the excitability of posterior horn neurons to a greater extent than one from cutaneous nociceptors (9).

Two main mechanisms underlie the overexcitability of spinal nociceptive neurons:

A structural change of ion channels, rendering them more permeable to Na+ and Ca2+, is the short-term result of an influx of nociceptive impulses into the spinal cord. Among other effects, this causes originally ineffective («silent» or «dormant») synapses to become effective.

A change of gene transcription in the neuronal nucleus, leading to a modification of synthetic processes, causes new ion channels to be synthesized and incorporated into the nerve cell membrane. The long-term result of central sensitization is a nociceptive cell whose membrane contains a higher density of ion channels that are also more permeable to ions. This explains the hyperexcitability of the cell. Glial cells, too, particularly microglia, can contribute to the sensitization of central neurons by secreting substances such as tumor necrosis factor a (TNF-a) (8).

The increased excitability of spinal neurons and the spread of excitation within the CNS are the first steps in the process of chronification of muscle pain. The endpoint of chronification consists of structural remodeling processes in the CNS that open up new pathways for nociceptive information and cause pain to persist over the long term. Patients with chronic muscle pain are difficult to treat, because the functional and structural changes in the CNS need time to regress. The fact that not all muscle pain becomes chronic implies that chronification requires not only the mechanisms just discussed, but also other ones, e.g., a genetic predisposition.

Pain arising in muscle is more likely to be referred pain than pain arising in the skin. Referred pain is pain that is felt not (only) at its site of origin, but at another site some distance away. A possible mechanism of referred pain is the spread, within the spinal cord, of excitation due to the muscle lesion (9) (figures 2 and ​and3).3). As soon as the excitation reaches sensory posterior horn neurons that innervate an area beyond the site of the original muscle lesion, the patient feels referred pain in that area, even though none of the nociceptors in it are activated (13).


An example is shown in figure 3: a stimulus delivered to the myofascial trigger point (MTrP) in the soleus muscle causes only mild local pain, while the patient feels more severe (referred) pain in the sacroiliac joint. No conclusive answers are yet available to the questions of why muscle pain is more likely than cutaneous pain to be referred, why it is usually not referred to both proximal and distal sites, and why pain referral is often discontinuous. There is, however, a well-known discontinuity of spinal topography between the C4 and T2 dermatomes.

The main reason why pain arises in muscle spasm is muscle ischemia, which leads to a drop in pH and the release of pain-producing substances such as bradykinin, ATP, and H+.

The vicious-circle concept of muscle spasm – muscle pain causes spasm, which causes more pain, etc. – should now be considered obsolete. Most studies have shown that muscle pain lowers the excitability of the α-motor neurons innervating the painful muscle (14) (a «pain adaptation» model) (15).

Muscle spasm can be precipitated by, among other things, pain in another muscle. Thus, a spasm-like increase EMG activity in the trapezius muscle has been described in response to painful stimulation of the biceps brachii muscle (16). Another source of muscle spasms is pathological changes in a neighboring joint. These sources of pain must be deliberately sought.

In a widespread hypothesis on the origin of MTrP’s (19), it is supposed that a muscular lesion damages the neuromuscular endplate so that it secretes an excessive amount of acetylcholine. The ensuing depolarization of the muscle cell membrane produces a contraction knot that compresses the neighboring capillaries, causing local ischemia. Ischemia, in turn, leads to the release of substances into the tissue that sensitize nociceptors, accounting for the tenderness of MTrP’s to pressure. Substances of this type have been found to be present within the MTrP’s of these patients (20). This supposed mechanism leaves many questions unanswered but is currently the only comprehensive hypothesis on the origin of MTrP’s.

Patients with MTrP’s often have pain in three locations:

  • at the site of the MTrP itself,
  • at the origin or insertion of the affected muscle, because of pulling by the muscle fibers that have been stretched by the contraction knots,
  • and referred pain outside the MTrP (figure 3).

Because the MTrP is cut off from its blood supply by compression of the local microcirculation, oral NSAID’s are not very effective against TrP pain.

Ukjent sin avatar

Functional Anatomy of Muscle – Muscle, Nociceptors and Afferent Fibers

av

Svært mye interessant om nervesystemets rolle i muskler og smerte.

Spesielt at det er ingen frie nerveender i muskelcellene, men bare i blodkarene i musklene. Derfor reagerer vi med smerte på betennelser og lav pH i blodet, mens trykksensitiviteten kun sitter i huden.

Den nevner at pH sensibiliteten er den viktigste smertebidraget fordi pH synker i de fleste patologiske tilstander, f.eks. hard trening eller skade.

Den nevner at det er mer SP (Substans P, som er relatert til smerte) i huden enn i muskler.

Nevner at frie nerveender ikke går til kapillærer eller muskelceller, bare til arterioler og venuler.

Nevner også innervering av bindevev, og at dette feltet foreløpig er lite studert og oversett. Spesielt viser de til at Toracolumbar Facia (i korsryggen) har størst innervasjon av C-fiber nociceptorer(som inneholder SP) under huden, og litt i multifidene.

En nociceptor er ikke bare en passiv mottaker av impulser, men er også en aktiv deltaker i vevets tilstand når det gjelder betennelser og blodsirkulasjon for de sender nevropetider ut fra doresalhornet til vevet (antidromiske impulser). Altså motsatt vei av reseptor-signalretningen.

CGRP virker vasodilerende, mens SP gjør at blodkarveggenes permeabilitet øker. Når permeabiliteten øker siver det ut proteiner og stoffer som egentlig ikke skal være i vevet, og da økes betennelser og immunsystemets aktivitet. Så det er SP vi ønsker å dempe først og fremst.

http://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=1&cad=rja&ved=0CCsQFjAA&url=http%3A%2F%2Fwww.springer.com%2Fcda%2Fcontent%2Fdocument%2Fcda_downloaddocument%2F9783540850205-c1.pdf%3FSGWID%3D0-0-45-935848-p173845615&ei=_GJEUqyUOevn4QSBl4HQDg&usg=AFQjCNEpyWrolHywvUNyw_Cwa8yWTiEUnw&sig2=OJLZ3XrnTalCUUqE-uhCeQ&bvm=bv.53217764,d.bGE

The predominant location of free nerve endings supplied by group IV fibers was the adventitia of arterioles and venules. Surprisingly, muscle fibers themselves did not receive direct innervation by free nerve endings. Group III afferents generated not only free nerve endings but also paciniform corpuscles, whereas group IV fibers terminated exclusively in free nerve endings.The high sensitivity of the free nerve endings to chemical stimuli, particularly to those accompanying inflammatory lesions or disturbances of the microcirculation, may be related to their location on or in the walls of the blood vessels. The finding that the muscle fibers proper are not supplied by free nerve endings (Reinert et al. 1998) may relate to the clinical experience that muscle cell death is usually not painful, at least not if it occurs slowly, as for instance during muscular dystrophy, polymyositis, or dermatomyositis. A different situation is tearing of a muscle fiber bundle, which can be extremely painful. In this condi- tion, many muscle cells are destroyed simultaneously and release their contents (e.g., K+ ions and ATP) in the interstitial space, from where they can diffuse to the next nociceptive endings.
In skeletal muscle, the free nerve endings appear to be distributed quite evenly in the proximodistal direction. At least, in a quantitative evaluation of the inner- vation density by neuropeptide-(SP- and CGRP-) containing fibers, no difference between the proximal and distal portions of the rat gastrocnemius–soleus (GS) muscle was found (Reinert et al. 1998). Therefore, a higher innervation density at the transition zone between muscle and tendon is not a probable explanation for the frequent pain in this region.

However, in the same study the nerve fiber density in the peritendineum (the connective tissue around a tendon) of the rat calcaneal tendon was found to be several times higher than that in the GS muscle. In contrast, the collagen fiber bundles of the tendon tissue proper were almost free of free nerve endings. The high fiber density in the peritendineum may explain the high prevalence of tenderness or pain in the tissue around the tendon and the insertion site. The scarcity of nerve endings in the center of the tendon may relate to the clinical observation that (incomplete) ruptures of the tendon may occur without pain.

Judging from their respon- siveness to pain-producing agents, the following receptor molecules are likely to be relevant for muscle pain and tenderness (Mense and Meyer 1985; Caterina and David 1999; McCleskey and Gold 1999; Mense 2007):

  • Bradykinin (BKN) receptors (B1 and B2). BKN is cleaved from blood plasma proteins when a blood vessel breaks or increases its permeability so that plasma proteins enter the interstitial space. In intact tissue, BKN excites nerve endings by the activation of the BKN receptor molecule B2, whereas under pathological conditions (e.g., inflammation) the receptor B1 is the predominant one (Perkins and Kelly 1993; for a review of receptor molecules mediating the effects of classic inflammatory (pain-producing or algesic) substances, see Kumazawa 1996).
  • Serotonin receptors (particularly 5-HT3). Serotonin (5-hydroxytryptamin, 5-HT) is released from blood platelets during blood clotting. The stimulating effects of serotonin on nociceptive terminals in the body periphery are predomi- nantly mediated by the 5-HT3 receptor (at present, more than 15 different 5-HT receptors are known in the CNS). The serotonin concentrations released in the tissue are usually not sufficient to excite nociceptors directly, but they can sen- sitize them, i.e., make them more sensitive to other pain-producing agents such as BKN.
  • Prostaglandins, particularly prostaglandin E2 (PGE2). Prostaglandins (PGs) are released in a pathologically altered muscle by the enzymatic action of cycloox- igenases. PGE2 binds to a G protein-coupled prostanoid receptor (EP2) in the membrane of the nociceptive ending. Similarly to serotonin, PGE2 sensitizes nociceptors rather than exciting them under (patho)physiological circumstances (Mense 1981).
  • Acid-sensing ion channels (ASICs). ASICs constitute a family of receptor molecules that are sensitive to a drop in pH and open at various pH values. The channel proteins react already to small pH changes, for instance from pH 7.4 to 7.1. This receptor family (for instance ASIC1 and ASIC3) is particularly impor- tant for muscle pain, because almost all pathologic changes in muscle are accom- panied by a drop in tissue pH, e.g., exhausting exercise, ischemia, and inflammation (Immke and McCleskey 2003). In these conditions, the pH of the muscle tissue can drop to 5–6. The proton-sensitive nociceptors may also be of importance for the induction of chronic muscle pain. Repeated intramuscular injections of acidic solutions have been reported to induce a long-lasting hyper- algesia (Sluka et al. 2001).
  • P2X3 receptors. This receptor is a subtype of the purinergic receptors that are activated by ATP and its derivatives (Burnstock 2007; Ding et al. 2000). ATP is the energy-carrying molecule in all cells of the body; accordingly, it is present in every tissue cell. It is released from all tissues during trauma and other pathologic changes that are associated with cell death. For this reason, ATP has been considered a general signal substance for tissue trauma and pain (Cook and McCleskey 2002). ATP is particularly important for muscle pain, because it is present in muscle cells in high concentration (Stewart et al. 1994). When injected into human muscle, ATP causes pain (Mo ̈rk et al. 2003).
  • Transient receptor potential receptor subtype 1 (TRPV1) formerly called VR1. This receptor is one of the most important molecules for the induction of pain. The natural stimulant for the TRPV1 receptor is Capsaicin, the active ingredient of chilli peppers (Caterina and Julius 2001). The receptor is also sensitive to an increase in H+-concentration and to heat, with a threshold of approximately 39C. Its endoge- nous ligands are H+-ions.
  • Other TRP receptors. TRPV4 is a mechanosensitive ion channel that is sensitive to both weak and strong (noxious) intensities of local pressure (Liedtke 2005). It may be the receptor for mediating pain evoked by pinching and squeezing.
  • Tyrosine kinase A (TrkA) receptor. The ligand of this receptor is NGF (Caterina and David 1999). NGF is well-known for its sensitizing action on nociceptors in the body periphery and neurons in the CNS; it is synthesized in muscle, and its synthesis is increased during pathophysiological changes of the muscle (e.g., inflammation, Menetrey et al. 2000; Pezet and McMahon 2006).
  • Glutamate receptors. There is evidence indicating that the NMDA receptor (one of the receptors for glutamate) is present on nociceptive endings in masticatory muscles. Injections of glutamate into the masseter muscle in human subjects induced a reduction in pressure pain threshold which was attenuated by coinjection with ketamine, an NMDA receptor antagonist (Cairns et al. 2006).
Substances exciting muscle nociceptors independent of membrane receptors.
  • Hypertonic saline: injections of NaCl solutions (4.5–6.0%) have long been and still are used to elicit pain from deep somatic tissues (Kellgren 1938; for review, see Graven-Nielsen 2006).
  • Potassium ions: The most likely explanation for the excitatory action of high concentrations of extracellular potassium ions is a depolarization of the membrane potential due to a reduction of the inside–outside potassium gradient (usually the potassium concentration inside the axon is much higher).

DRG cells projecting in a cutaneous nerve have been reported to contain SP, CGRP, and somatostatin (SOM).

In comparison to skin nerves, muscle nerves appear to contain less SP. This finding makes sense, because the vasodilatation and plasma extrava- sation caused by the release of SP and CGRP from free nerve endings (see below) would be dangerous for skeletal muscles, since many of them are surrounded by a tight fascia. Therefore, an SP-induced muscle edema would result in a high increase in interstitial pressure, and could cause muscle necrosis.

In a study on functionally identified DRG cells employing a combination of electrophysiological and immunohistochemical techniques, Lawson et al.(1997) reported that cells terminating in cutaneous nociceptive endings showed a strong tendency to express SP, particularly if they had a slow conduction velocity or a small soma in the DRG. 

The peptides are synthesized in the somas of the DRG or in ganglion cells of cranial nerves. They are transported to both the central and the peripheral terminal of the primary afferent unit.

In a quantitative evaluation of neuropeptide-containing free nerve endings and preterminal axons (both characterized by varicosities) in the GS muscle of the rat, most endings were found around small blood vessels (arterioles or venules), whereas capillaries and the muscle cells proper were not contacted by these end- ings.

Efferent or motor fibers conduct action potentials from the CNS to the periphery; their soma is located in the spinal cord or brainstem and the fibers leave the CNS via the ventral root or cranial nerve motor roots. An exception are postganglionic sympathetic fibers whose cell bodies are mostly located in the sympathetic trunk (e.g., vasomotor fibers that constrict blood vessels).

The nerve to a locomotor muscle in the cat (the lateral GS) is composed of approximately one-third myelinated (720) and two-thirds unmyelinated (2,480) fibers (Table 2.2; Mitchell and Schmidt 1983; Stacey 1969). Nearly one quarter of the myelinated (group III) fibers had nociceptive properties in neurophysio- logical experiments (Mense and Meyer 1985). Of the unmyelinated fibers, 50% are sensory (group IV), and of these, approximately 55% have been found to be nociceptive in the rat (Hoheisel et al. 2005).

Data obtained from one muscle nerve cannot be transferred directly to other muscle nerves, because considerable differences exist between different muscles. For instance, neck muscle nerves of the cat contain unusually high numbers of sensory group III receptors (Abrahams et al. 1984). One possible explanation for these differences is that the muscles have different functions and environmental conditions: in contrast to the neck muscles, which must register the orientation of the head in relation to the body in fine detail, the locomotor hindlimb muscles often have to contract with maximal strength and under ischemic conditions.

In addition to nociceptors, there are other muscle receptors whose function is essential for the understanding of muscle pain:

  • Muscle spindles are complex receptive structures that consist of several specialized muscle fibers (the so-called intrafusal muscle fibers; the name is derived from their location inside the spindle-shaped connective tissue sheath. Accordingly, all the “normal” muscle fibers outside the spindle are “extrafusal” fibers). Muscle spindles measure the length and the rate of length changes of the muscle, i.e., their discharge rate increases with increasing muscle length and with increasing velocity of the length change.
  • Golgi (tendon) organs measure the tension of the muscle. They are arranged in series with the extrafusal muscle fibers; their location is the transition zone between muscle and tendon. The supplying fiber is the Ib afferent, whose structure is identical to the Ia fiber (thick myelin sheath and high conduction velocity). The receptor has a much simpler structure than the muscle spindle; it consists of receptive endings that are interwoven between the collagen fiber bundles of the tendon.
  • Muscle spindles and Golgi organs are proprioceptors, i.e., they measure the internal state of the body.
  • Pacinian corpuscles (PC) and paciniform corpuscles. These receptors do not respond to static pressure; they require dynamically changing mechanical stimuli, and are best excited by vibrations of relatively high frequency (close to 300 Hz; Kandel et al. 2000). The receptive ending is formed like a rod, and covered by several concentric membranes which give the receptor an onion-like appearance in cross-sections.

At present, little information is available about the innervation of fascia. This is an important gap in our knowledge, because fascia is an important component of the musculoskeletal system and likely to contribute to many forms of pain that are subsumed under the label “muscle” pain. One example is low back pain: The thoracolumbar fascia (TF) plays an essential role in body posture and trunk move- ments (Bogduk and Macintosh 1984). It is not only a passive transmitter of mechanical forces of the low back and abdominal muscles but also contractile by itself (Schleip et al. 2005).

In the connective tissue around the superficial lamina of the TF we found many CGRP- and SP-containing free nerve endings. The majority of the fibers were located in the subcutaneous layer, as well as between the fascia and the surface of the multifidus muscle (Fig. 2.8). The SP-positive endings are of particular interest, because they are thought to be nociceptors.
The loose connective tissue around the TF is probably deformed during any trunk movement, and therefore the free nerve endings are strategically situated to sense any disorders in these movements. It is conceivable that overload of the fascia puts mechanical stress and irritation on the endings, and thus may contribute to low back pain.
SP then releases histamine from mast cells, and together with CGRP these agents cause vasodilatation and an increase in vascular permeability of the blood vessels around the active ending. The result is a shift of blood plasma from the intravascular to the interstitial space. Outside the blood vessel, BKN is cleaved from the plasma protein kallidin, serotonin (5-HT) is set free from platelets, and PGs (particularly PGE2) from endothelial and other tissue cells. All these substances sensitize nociceptors. Thus, the main tissue alteration induced by a nondestructive noxious mechanical stimulus is a localized region of vasodilatation, edema, and sensitized nociceptors.
A nociceptor is not a passive sensor of tissue-threatening stimuli; it actively influences the microcirculation and chemical composition of the intersti- tial space around it.
If a noxious stimulus activates only one part of the ending, the action potentials originating in that region of the ending can invade antidromically (against the normal direction of propagation) those branches of the ending that were not excited by the stimulus. These antidromic action potentials release neuropeptides from the unstimulated branches. The whole process is called the axon reflex.  It is assumed to be the reason for the visible wheal and flare around a cutaneous lesion.

The vascular permeability is increased mainly by SP (and by the neurokinins A and B; Gamse and Saria 1985), whereas CGRP is assumed to act primarily as a vasodilator. There is evidence showing that CGRP enhances the plasma extravasation induced by SP and neurokinins A and B, but reduces the vasodilatory action of SP by desensitizing muscle arterioles to the peptide (O ̈ hle ́n et al. 1988).

The area of wheal and flare after a localized damage to the skin – for instance around a needle prick – could be an indicator of the extent of the excited nocicep- tive ending.

The size of the receptive fields (RFs) of cutaneous polymodal nociceptors was found to be less than 2 mm in cat (Bessou and Perl 1969) and 6–32 mm in rabbit (Kenins 1988). A receptive field is that region of the body from which a receptive ending (or a central sensory neuron) can be excited. The above figures are larger than the reported length of the branches of a nociceptor ending (a few hundred mm; Stacey 1969).

The release of SP, CGRP, neurokinin A, and other agents from nociceptors is the central factor in the cascade of events that lead to neurogenic inflammation in the periphery (Lembeck and Holzer 1979). Neurogenic inflammation is characterized by tissue edema and infiltration by immune cells, i.e., it exhibits the major histo- logical signs of a (sterile) inflammation. It develops whenever action potentials are generated not at the receptive ending but somewhere along the course of primary afferent units (spinal nerve or dorsal root). The action potentials propagate both to the CNS (causing pain) and to the peripheral ending (causing release of neuropep- tides and neurogenic inflammation). The published data indicate that vasodilatation can be elicited by antidromic stimulation of both Ad- and C fibers, but increase in vascular permeability and plasma extravasation by stimulation of C fibers only.

Neuropathies and radiculopathies and other pathological conditions that are asso- ciated with antidromic activity in sensory nerve fibers are examples of such events (Marchand et al. 2005). Neurogenic inflammation is likely to increase the dysesthe- sia and pain of patients suffering from neuropathies.

Inflammatory disorders are usually accompanied by sensitization of peri- pheral nociceptors, which is one source of inflammatory pain (for details, see Chap. 3).