Fibromyalgia is caused by a mycoplasmal infection in the neuroendocrine system.
http://www.raintree-health.co.uk/cgi-bin/getpage.pl?/ailments/indicateA.html
Hypothesis:
Fibromyalgia is caused by a mycoplasmal infection in the neuroendocrine system.
Justification:
The advances in research on Fibromyalgia Syndrome (FMS) over the last 5 years has targeted specific links and correlations which might indicate a dysregulation or imbalance of the neuroendocrine system, especially the HPA axis, which may well explain many of the seemingly unrelated symptoms presented by FMS patients. Research supports that various components of the central nervous system appear to be involved, including the hypothalamic pituitary axes, pain-processing pathways, and autonomic nervous system. The advances in gene research during this same time peroid has provided new evidence in the identification and pathogenesis of specific species of mycoplasmas which might have the ability to cause a dysregulation of the neuroendocrine system. To learn more about mycoplasmas, how they deregulate cellular functions and cause a wide rang of diseases and syndromes in the body. In this section we are going to try to answer:-
What is a Mycoplasma?
What diseases can they cause?
Treatment Options
Nutritional Protocols
Laboratory Testing for Mycoplasmas
Medical Research and Studies on Mycoplasmas
(There are more in-depth links on Mycoplasmas at the
end of this page)
Fibromyalgia is an extremely common chronic condition that can be challenging
to manage. Although the etiology remains unclear, characteristic alterations in
the pattern of sleep and changes in neuroendocrine transmitters such as
serotonin, substance P, growth hormone, thyroid hormones, estrogen and cortisol
suggest that dysregulation of the autonomic and neuroendocrine system now
appears to be the basis of the syndrome.
Evidence of neuroendocrine system dysfunction in Fibromyalgia:
Thyroid
Virtually every feature of fibromyalgia corresponds to signs or symptoms
associated with failed transcription regulation by thyroid hormone.(See Table)
In the late 1980's to early 1990's some diagnoses of fibromyalgia and rheumatic
diseases were subsequently changed to a hypothyroidism diagnosis after thyroid
testing was performed.(4, 6, 7) In a 1992 german study thyroid
function was tested in 13 female patients with primary fibromyalgia syndrome
(FMS) 10 healthy age matched controls by intravenous injection of 400
micrograms thyrotropin-releasing hormone (TRH). Basal thyroid hormone levels of
both groups were in the normal range. However, patients with primary FMS
responded with a significantly lower secretion of thyrotropin and thyroid
hormones to TRH, within an observation period of 2 h, and reacted with a
significantly higher increase of prolactin. Total and free serum calcium and
calcitonin levels were significantly lower in patients with primary FMS, while
both groups exhibited parathyroid hormone levels in the normal range. This
phenomenon would not be discovered in a doctor's routine thyroid tests of
measuring T3, T4, and TSH since it is indicative of secondary hypothyroidism
(Euthyroid) rather than primary hypothyroidism. Recent research suggests the
cause of this phenomenon to be a newly discovered gene mutation reporting:
"in hypothyroid fibromyalgia, failed transcription regulation would result
from thyroid-hormone deficiency. In euthyroid fibromyalgia, failed
transcription regulation may result from low-affinity thyroid hormone receptors
coded by a mutated c-erbA beta 1 gene, yielding partial peripheral resistance
to thyroid hormone. The result would be tissue-specific hypothyroid-like symptoms
despite normal circulating thyroid-hormone levels."(1)
In clinical practice is has been demonstrated that a significant percentage of
FMS patients are tested with secondary hypothyroidism (euthyroid). This is
missed by many health practitioners who routinely test thyroid function by
measuring common thyroid hormones T3, T4, and TSH (Thyroid stimulating
hormone). The majority of FMS patients will test in normal ranges. However,
thyroid dysfunction is often revealed in FMS patients when a TRH stimulus test
(Thyrotropin-releasing hormone) is administered. Medical practitioners have
been able to manage symptoms of FMS patients with some degree of success by
administering thryoid homone replacement therapy for several years now.(2)
Other researchers suggest that FMS patients may have a form of thryoid
autoimmunity, reporting the prevalence of thyroid microsomal antibodies were
significantly higher in persons with than without chronic widespread
musculoskeletal complaints. (3)
The thyroid produces hormones that increase oxygen use in cells and stimulate
vital processes in every part of the body. These thyroid hormones have a major
impact on growth, use of energy, heat production, and infertility. They affect
the use of vitamins, proteins, carbohydrates, fats, electrolytes, and water,
and regulate the immune response in the intestine. They can also alter the
actions of other hormones and drugs. The two key thyroid hormones are thyroxine
(T4) and L-triiodothyronine (T3). Iodine is the raw material used in the manufacture
of these hormones; it is extracted from the blood and trapped by the thyroid
gland where 80% of the body's iodine is stored. The thyroid mostly produces
thyroxine, which in turn, is converted into T3, the more biologically active
thyroid hormone. Only about 20% of T3 is actually formed in the thyroid gland,
however; the rest is manufactured from circulating thyroxine in tissues outside
the thyroid. The whole process of iodine trapping and thyroid hormone
production is directly influenced by another important hormone,
thyroid-stimulating hormone (TSH or thyrotropin). This hormone is secreted by
the pituitary gland and monitored by thyrotropin-releasing hormone (TRH), which
is produced in the hypothalamus gland. Both glands are located in the brain. Any
abnormality in this intricate system of glands and hormone synthesis and
production can have far-reaching consequences.
In autoimmune diseases, the body's immune system
attacks its own cells; in the case of autoimmune thyroiditis, the cells under
attack are in the thyroid gland. Experts do not know why the immune system
starts to injure the thyroid. One theory is that a virus or bacteria with a
protein resembling a thyroid protein might trigger the response. This theory is
backed up to some extent by the presence of recent infections in people with
autoimmune disease.
Footnotes:
(1) Lowe JC, Mutations in the c-erbA beta 1 gene: do they underlie euthyroid
fibromyalgia? Med Hypotheses. 1997 Feb;48(2):125-35. [MEDLINE]
(2) Dr. John C. Lowe, The Metabolic Treatment of Fibromyalgia.
(3) Aarflot T, et.al., Association between chronic widespread musculoskeletal
complaints and thyroid autoimmunity. Results from a community survey. Scand J
Prim Health Care. 1996 Jun;14(2):111-5. [MEDLINE]
(4) Keenan GF, et.al., Rheumatic symptoms associated with hypothyroidism in
children. J Pediatr. 1993 Oct;123(4):586-8.[MEDLINE]
(5) Neeck G, Thyroid function in patients with fibromyalgia syndrome. J
Rheumatol. 1992 Jul;19(7):1120-2.
(6) Carette S,et.al., Fibrositis and primary hypothyroidism. J Rheumatol. 1988
Sep;15(9):1418-21. MEDLINE
(7) Wilke WS, et.al., Hypothyroidism with presenting symptoms of fibrositis. J
Rheumatol. 1981 Jul-Aug;8(4):626-31. [MEDLINE]
TABLE 1
Symptoms of Hypothyroidism Symptoms of Fibromyalgia
Chronic fatigue Chronic fatigue
Muscle and joint aches Muscle and joint aches
Muscle cramps Muscle cramps
Muscle weakness Muscle weakness
Concentration and memory problems Concentration and memory problems
Depression and mood swings Depression and mood swings
Weight gain Weight gain
Constipation Irritable bowel including constipation
Obstructive sleep apnea Sleep disorders and insomnia
Heavy menstruation
Dry skin
Dry coarse hair
Flaky or split fingernails
Hair loss
Myxedema (round puffy face, swelling in hands and feet )
Husky voice
Numbness of arms and legs
Sensitivity to cold
Impaired sex drive
Infertility
Low blood pressure
Headaches
Visual disturbance
High cholesterol
The hypothalamic pituitary adrenal
axis
The brain and the immune system are the two major adaptive systems of the body.
During an immune response the brain and the immune system "talk to each
other" and this process is essential for maintaining homeostasis. Two
major pathway systems are involved in this cross-talk: the
hypothalamic-pituitary-adrenal (HPA) axis and the sympathetic nervous system
(SNS).(6) Living organisms survive by maintaining an immensely complex dynamic
equilibrium of the internal milieu or homeostasis. The systemic sympathetic and
adrenomedullary (sympathetic) system (SNS) and the HPA axis are the peripheral
limbs of the stress system, whose main function is to maintain both basal and
stress-related homeostasis. At rest catecholamines (CA) maintain homeostasis as
major regulators of fuel metabolism, heart rate, blood vessel tone, and
thermogenesis. When homeostasis is disturbed or threatened by internal or
external challenges, both the SNS and HPA axis become activated, resulting in
increased peripheral levels of CAs and glucocorticoids that act in concert to
keep the steady state of the internal milieu.
Researchers around the world have published articles and research which
indicate "defects in the hypothalamus-pituitary-adrenal axis have been
observed in autoimmune and rheumatic diseases, chronic inflammatory disease,
chronic fatigue syndrome and fibromyalgia."(3) Research as early as 1989
indicated data suggesting alteration in the pituitary hypothalamic axis with
respect to cortisol secretion in fibromyalgia syndrome.(4) A1998 German study
discovered: "We found in FMS patients elevated basal values of ACTH and
cortisol, lowered basal values of insulin-like growth factor I (IGF-I) and of
triiodothyronine (T3), elevated basal values of follicle-stimulating hormone
(FSH) and lowered basal values of estrogen. Following injection of the four
releasing-hormones, we found in FMS patients an augmented response of ACTH, a
blunted response of TSH, while the prolactin response was exaggerated. The
effects of LHRH stimulation were investigated in six FMS patients and six
controls and disclosed a significantly blunted response of LH in FMS. We
explain the deviations of hormonal secretion in FMS patients as being caused by
chronic stress, which, after being perceived and processed by the central
nervous system (CNS), activates hypothalamic CRH neurons. CRH, on the one hand,
activates the pituitary-adrenal axis, but also stimulates at the hypothalamic
level somatostatin secretion which, in turn, causes inhibition of GH and TSH at
the pituitary level."(1) In several studies, histologic muscle
abnormalities of membranes, mitochondria, and fiber type have been well
described at both the light microscopic and ultrastructural levels. These abnormalties
found in muscle tissues of FM patients have been reported to be
"consistent with neurologic findings and disturbances in the
hypothalamic-pituitary-adrenal axis" and suggests, "muscle
abnormalities may be elicited by intrinsic changes within the muscle tissue
itself and/or extrinsic neurologic and endocrine factors.(5) Another research
group found "The influence of maximum exercise has been studied in 10
patients with primary fibromyalgia syndrome (PFS) and 10 healthy sedentary
control persons. The exercise consisted of a bicycle ergometertest and a
steptest, both till exhaustion. In both tests, the mean maximum workload of the
PFS patients was lower than that of the controls. Significantly lower values of
serum creatinekinase, myoglobin, cortisol, epinephrine and norepinephrine were
found in PFS patients. A striking finding was a lower heart rate in PFS
patients compared to the controls under the same workload. The lower
(nor)epinephrine concentration together with the lower heart rate suggests a
disturbance of the sympathetic activity in PFS patients. The preliminary
conclusion is that there is a disturbed reactivity of the sympathetic system as
well as of the HPA axis in PFS."(7)
(1) Riedel W, et.al., Secretory pattern of GH, TSH, thyroid hormones, ACTH,
cortisol, FSH, and LH in patients with fibromyalgia syndrome following systemic
injection of the relevant hypothalamic-releasing hormones. Z Rheumatol. 1998;57
Suppl 2:81-7. [MEDLINE]
(2) Clauw DJ, et.al., Chronic pain and fatigue syndromes: overlapping clinical
and neuroendocrine features and potential pathogenic
mechanisms.euroimmunomodulation. 1997 May-Jun;4(3):134-53. [MEDLINE]
(3) Anisman H, et.al., Neuroimmune mechanisms in health and disease: 2. Disease.
CMAJ. 1996 Oct 15;155(8):1075-82. [MEDLINE]
(4) McCain GA, Diurnal hormone variation in fibromyalgia syndrome: a comparison
with rheumatoid arthritis. J Rheumatol Suppl. 1989 Nov;19:154-7. [MEDLINE]
(5) Park JH, et.al., Evidence for Metabolic Abnormalities in the Muscles of
Patients with Fibromyalgia. Curr Rheumatol Rep. 2000 Apr;2(2):131-140.
[MEDLINE]
(6) Elenkov IJ, et al., The sympathetic nerve-An integrative interface between
two supersystems:
the brain and the immune system. Pharmacol Rev 2000 Dec;52(4):595-638 [MEDLINE]
(7) van Denderen JC, et al., Physiological effects of exhaustive physical
exercise in primary fibromyalgia syndrome (PFS): is PFS a disorder of
neuroendocrine reactivity? Scand J Rheumatol 1992;21(1):35-7
Elenkov IJ, et al., The sympathetic nerve-An integrative interface between two
supersystems: the brain and the immune system. Pharmacol Rev 2000
Dec;52(4):595-638
Elam M, Johansson G and Wallin BG (1992) Do patients with primary fibromyalgia
have an altered muscle sympathetic nerve activity? Pain 48: 371-375 [Medline].
Qiao ZG, Vaeroy H and Morkrid L (1991) Electrodermal and microcirculatory
activity in patients with fibromyalgia during baseline, acoustic stimulation
and cold pressor tests. J Rheumatol 18: 1383-1389 [Medline].
Clauw DJ and Chrousos GP (1997) Chronic pain and fatigue syndromes: Overlapping
clinical and neuroendocrine features and potential pathogenic mechanisms. Neuroimmunomodulation
4: 134-153 [Medline].
Clauw DJ, Radulovic D, Antonetti D, Bagati R, Baraniuk J and Barbey JT (1996a)
Tilt table tasting in fibromyalgia. Arthritis Rheum 39 (9S): S276.
Clauw DJ, Radulovic D, Heshmat Y and Barbey JT (1996b) Heart rate variability
as a measure of autonomic dysfunction in patients with fibromyalgia. Arthritis
Rheum 39 (9S): S276.
van Denderen JC, Boersma JW, Zeinstra P, Hollander P and van Neerbos BR (1992)
Physiologic effects of exhaustive physical exercise in primary fibromyalgia
syndrome (PFS): Is PFS a disorder of neuroendocrine reactivity? Scand J
Rheumatol 21: 35-37 Medline.
Rowe PC, Bou-Holaigah I, Kan JS and Calkins H (1995) Is neurally mediated
hypotension an unrecognized cause of chronic fatigue? Lancet 345: 623-624
Medline.
Hasko G, Elenkov IJ, Kvetan V and Vizi ES (1995a) Differential effect of
selective block of alpha 2-adrenoreceptors on plasma levels of tumour necrosis
factor-alpha, interleukin-6 and corticosterone induced by bacterial
lipopolysaccharide in mice. J Endocrinol 144: 457-462 [Medline].
Elenkov IJ, Papanicolaou DA, Wilder RL and Chrousos GP (1996) Modulatory
effects of glucocorticoids and catecholamines on human interleukin-12 and
interleukin-10 production: Clinical implications. Proc Assoc Am Physicians108:
374-381 [Medline].
Hypothalmus
Recent research this year has demonstrated FMS patients have a decrease in GH
(growth hormone) over healthy subjects suggesting "Severe GH deficiency is
not a significant pathogenic factor in most patients with FMS. We observed an
impaired reactivity of the somatotropic axis in one-third of patients with FM,
in keeping with a functional alteration of the hypothalamus."(1)
"Patients with fibromyalgia were found to have an impaired ability to
activate the hypothalamic pituitary portion of the hypothalamic pituitary
adrenal axis as well as the sympathoadrenal system, leading to reduced corticotropin
and epinephrine response to hypoglycemia." (2) In fact, FMS patients
complaining of "fibro-fog" have later been diagnosed with intermitent
hypoglycemia which is causing sort term memory loss, periods of confusion or
"fog" and even stupor-like states as blood sugar levels drop
unexpectedly. This intermittent hypoglycemia may result from this impaired
hypothalamic pituitary function.
(1) Dinser R, et.al., Stringent endocrinological testing reveals subnormal
growth hormone secretion in some patients with fibromyalgia syndrome but rarely
severe growth hormone deficiency. J Rheumatol. 2000 Oct;27(10):2482-8.
[Medline]
(2) Buskila D. Fibromyalgia, chronic fatigue syndrome, and myofascial pain
syndrome. Curr Opin Rheumatol. 2000 Mar;12(2):113-23. Review. [Medline]
Clinical Research supporting Neuroendocrine factors in Fibromyalgia
Dysregulation and/or significant
abnormalties of the neuroendocrine system
Millea PJ, et.al., Treating fibromyalgia. Am Fam Physician. 2000 Oct
1;62(7):1575-82, 1587.
Bradley LA, et.al., Pain Complaints in Patients with Fibromyalgia Versus
Chronic Fatigue Syndrome. Curr Rev Pain. 2000;4(2):148-157.
Klimas N. Pathogenesis of chronic fatigue syndrome and fibromyalgia. Growth
Horm IGF Res. 1998 Apr;8 Suppl B:123-6.
Korszun A, et.al., Follicular phase hypothalamic-pituitary-gonadal axis
function in women with fibromyalgia and chronic fatigue syndrome. J Rheumatol.
2000 Jun;27(6):1526-30.
Dessein PH, et.al., Neuroendocrine deficiency-mediated development and
persistence of pain in fibromyalgia: a promising paradigm? Pain. 2000
Jun;86(3):213-5.
Crofford LJ. Neuroendocrine abnormalities in fibromyalgia and related
disorders. Am J Med Sci. 1998 Jun;315(6):359-66.
Morand EF, et.al., Advances in the understanding of neuroendocrine function in
rheumatic disease. Aust N Z J Med. 1996 Aug;26(4):543-51.
Moldofsky H. Sleep, neuroimmune and neuroendocrine functions in fibromyalgia
and chronic fatigue syndrome. Adv Neuroimmunol. 1995;5(1):39-56. Review.
van Denderen JC, et.al., Physiological effects of exhaustive physical exercise
in primary fibromyalgia syndrome (PFS): is PFS a disorder of neuroendocrine
reactivity? Scand J Rheumatol. 1992;21(1):35-7.
Torpy DJ, et.al., The three-way interactions between the
hypothalamic-pituitary-adrenal and
gonadal axes and the immune system Baillieres Clin Rheumatol 1996
May;10(2):181-98
HPA axis dysfunction/dysregulation
Neeck G, et.al., Neuroendocrine perturbations in fibromyalgia and chronic
fatigue syndrome. Rheum Dis Clin North Am. 2000 Nov;26(4):989-1002.
Crofford LJ. The hypothalamic-pituitary-adrenal stress axis in fibromyalgia and
chronic fatigue syndrome. Z Rheumatol. 1998;57 Suppl 2:67-71.
Crofford LJ, et.al., Neurohormonal perturbations in fibromyalgia. Baillieres
Clin Rheumatol 1996 May;10(2):365-78
Clauw DJ, et.al., Chronic pain and fatigue syndromes: overlapping clinical and
neuroendocrine
features and potential pathogenic mechanisms. Neuroimmunomodulation 1997
May-Jun;4(3):134-53
Griep EN, et.al., Function of the hypothalamic-pituitary-adrenal axis in
patients with fibromyalgia and low back pain. J Rheumatol. 1998
Jul;25(7):1374-81.
McCain GA, et.al., Diurnal hormone variation in fibromyalgia syndrome: a
comparison with rheumatoid arthritis. J Rheumatol Suppl 1989 Nov;19:154-7
Demitrack MA, Evidence for and pathophysiologic implications of
hypothalamic-pituitary- adrenal axis dysregulation in fibromyalgia and chronic
fatigue syndrome. Ann N Y Acad Sci. 1998 May 1;840:684-97.
Bellometti S, et.al., Function of the hypothalamic adrenal axis in patients
with fibromyalgia syndrome undergoing mud-pack treatment. Int J Clin Pharmacol
Res. 1999;19(1):27-33.
Scott LV, et.al., The neuroendocrinology of chronic fatigue syndrome: focus on
the hypothalamic-pituitary-adrenal axis. Funct Neurol. 1999 Jan-Mar;14(1):3-11.
Adler GK, et.al., Reduced hypothalamic-pituitary and sympathoadrenal responses
to hypoglycemia in women with fibromyalgia syndrome. Am J Med. 1999
May;106(5):534-43.
Torpy DJ, et.al., The three-way interactions between the hypothalamic-pituitary-adrenal
and gonadal axes and the immune system. Baillieres Clin Rheumatol. 1996
May;10(2):181-98.
Schneider MJ. Et.al., Tender points/fibromyalgia vs. trigger points/myofascial
pain syndrome: a need for clarity in terminology and differential diagnosis. J
Manipulative Physiol Ther. 1995 Jul-Aug;18(6):398-406. Review.
Griep EN, Altered reactivity of the hypothalamic-pituitary-adrenal axis in the
primary fibromyalgia syndrome. J Rheumatol. 1993 Mar;20(3):469-74.
van Denderen JC, et.al., Physiological effects of exhaustive physical exercise
in primary fibromyalgia syndrome (PFS): is PFS a disorder of neuroendocrine
reactivity? Scand J Rheumatol. 1992;21(1):35-7.
Hypothalamus dysregulation
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in
patients with fibromyalgia syndrome following systemic injection of the
relevant
hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Neeck G. et.al., Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl.
2000;113:8-12.
Neeck G, et.al., Hormonal pertubations in fibromyalgia syndrome. Ann N Y Acad
Sci. 1999 Jun 22;876:325-38;
Adrenal insufficiency
Griep EN, Altered reactivity of the hypothalamic-pituitary-adrenal axis in the
primary fibromyalgia syndrome. J Rheumatol. 1993 Mar;20(3):469-74.
Growth Hormone secretion deficiency:
Bennett RM, A randomized, double-blind, placebo-controlled study of growth
hormone in the treatment of fibromyalgia. Am J Med 1998 Mar;104(3):227-31
Bennett RM, Disordered growth hormone secretion in fibromyalgia: a review of
recent findings and a hypothesized etiology. Z Rheumatol 1998;57 Suppl 2:72-6
Schlienger JL, [Growth hormone: a magical potion]? Rev Med Interne 1998
Apr;19(4):279-85
Bennett R, Fibromyalgia, chronic fatigue syndrome, and myofascial pain. Curr
Opin Rheumatol 1998 Mar;10(2):95-103
Bennett RM, Hypothalamic-pituitary-insulin-like growth factor-I axis
dysfunction in patients with fibromyalgia. J Rheumatol 1997 Jul;24(7):1384-9
Dinser R, et.al., Stringent endocrinological testing reveals subnormal growth
hormone secretion in some patients with fibromyalgia syndrome but rarely severe
growth hormone deficiency. J Rheumatol. 2000 Oct;27(10):2482-8.
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Bagge E, et.al., Low growth hormone secretion in patients with fibromyalgia--a
preliminary report on 10 patients and 10 controls. J Rheumatol 1998
Jan;25(1):145-8
Crofford LJ, et.al., Neurohormonal perturbations in fibromyalgia. Baillieres
Clin Rheumatol 1996 May;10(2):365-78
Griep EN, et.al., Pituitary release of growth hormone and prolactin in the
primary fibromyalgia syndrome. J Rheumatol. 1994 Nov;21(11):2125-30.
Lowered basal values of insulin-like
growth factor 1 (IGF-1)
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Berwaerts J, et.al., Secretion of growth hormone in patients with chronic
fatigue syndrome. Growth Horm IGF Res 1998 Apr;8 Suppl B:127-9
Leal-Cerro A, et.al, The growth hormone (GH)-releasing hormone-GH-insulin-like
growth factor-1 axis in patients with fibromyalgia syndrome. J Clin Endocrinol
Metab 1999 Sep;84(9):3378-81
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Bennett RM, A randomized, double-blind, placebo-controlled study of growth
hormone in the treatment of fibromyalgia. Am J Med 1998 Mar;104(3):227-31
Bagge E, et.al., Low growth hormone secretion in patients with fibromyalgia--a
preliminary report on 10 patients and 10 controls. J Rheumatol 1998
Jan;25(1):145-8
Bennett RM, Hypothalamic-pituitary-insulin-like growth factor-I axis
dysfunction in patients with fibromyalgia. J Rheumatol 1997 Jul;24(7):1384-9
Griep EN, et.al., Pituitary release of growth hormone and prolactin in the
primary fibromyalgia syndrome. J Rheumatol. 1994 Nov;21(11):2125-30.
Inverse correlation between low
density lipoprotein levels and maximal GH concentration
Dinser R, et.al., Stringent endocrinological testing reveals subnormal growth
hormone secretion in some patients with fibromyalgia syndrome but rarely severe
growth hormone deficiency. J Rheumatol. 2000 Oct;27(10):2482-8.
Alteration at the hypothalamic level
in the neuroendocrine control and release of GH
Leal-Cerro A, et.al, The growth hormone (GH)-releasing hormone-GH-insulin-like
growth factor-1 axis in patients with fibromyalgia syndrome. J Clin Endocrinol
Metab 1999 Sep;84(9):3378-81
Lowered basal values and/or secretion
of Somatomedin C
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Bennett AL, et.al., Somatomedin C (insulin-like growth factor I) levels in
patients with chronic fatigue syndrome. J Psychiatr Res. 1997
Jan-Feb;31(1):91-6.
Griep EN, et.al., Pituitary release of growth hormone and prolactin in the
primary fibromyalgia syndrome. J Rheumatol. 1994 Nov;21(11):2125-30.
Bennett RM, Low levels of somatomedin C in patients with the fibromyalgia
syndrome. A possible link between sleep and muscle pain. Arthritis Rheum. 1992
Oct;35(10):1113-6.
Elevated basal values and/or
activation of ACTH
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Griep EN, et.al., Pituitary release of growth hormone and prolactin in the
primary fibromyalgia syndrome. J Rheumatol. 1994 Nov;21(11):2125-30.
Griep EN, Altered reactivity of the hypothalamic-pituitary-adrenal axis in the
primary fibromyalgia syndrome. J Rheumatol. 1993 Mar;20(3):469-74.
Griep EN, et.al., Function of the hypothalamic-pituitary-adrenal axis in
patients with fibromyalgia and low back pain. J Rheumatol. 1998
Jul;25(7):1374-81.
Lentjes EG, et.al., Glucocorticoid receptors, fibromyalgia and low back pain. Psychoneuroendocrinology.
1997 Nov;22(8):603-14.
Elevated basal values of
follicle-stimulating hormone (FSH),
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Lowered basal values of cortisol
Crofford LJ, et.al., Neurohormonal perturbations in fibromyalgia. Baillieres
Clin Rheumatol 1996 May;10(2):365-78
McCain GA, et.al., Diurnal hormone variation in fibromyalgia syndrome: a
comparison with rheumatoid arthritis. J Rheumatol Suppl 1989 Nov;19:154-7
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Heim C, et.al., The potential role of hypocortisolism in the pathophysiology of
stress-related bodily disorders. Psychoneuroendocrinology. 2000 Jan;25(1):1-35.
van Denderen JC, et.al., Physiological effects of exhaustive physical exercise
in primary fibromyalgia syndrome (PFS): is PFS a disorder of neuroendocrine
reactivity? Scand J Rheumatol. 1992;21(1):35-7.
Hyposecretion of adrenal androgens
(DHEAS and Testosterone)
Dessein PH, et.al., Hyposecretion of adrenal androgens and the relation of
serum adrenal steroids, serotonin andinsulin-like growth factor-1 to clinical
features in women with fibromyalgia. Pain. 1999 Nov;83(2):313-9.
Abnormal dexamethasone suppression
McCain GA, et.al., Diurnal hormone variation in fibromyalgia syndrome: a
comparison with rheumatoid arthritis. J Rheumatol Suppl 1989 Nov;19:154-7
Lowered basal values of norepinephrine
Crofford LJ, et.al., Neurohormonal perturbations in fibromyalgia. Baillieres
Clin Rheumatol 1996 May;10(2):365-78
van Denderen JC, et.al., Physiological effects of exhaustive physical exercise
in primary fibromyalgia syndrome (PFS): is PFS a disorder of neuroendocrine
reactivity? Scand J Rheumatol. 1992;21(1):35-7.
Decreased serotonergic activity
Crofford LJ, et.al., Neurohormonal perturbations in fibromyalgia. Baillieres
Clin Rheumatol 1996 May;10(2):365-78
Decreased thyroid homone production in
reponse to thyrotropin-releasing hormone (TRH)
Neeck G, Thyroid function in patients with fibromyalgia syndrome. J Rheumatol 1992 Jul;19(7):1120-2
Failed transcription regulation by
thyroid hormone
Lowe JC, et.al., Mutations in the c-erbA beta 1 gene: do they underlie
euthyroid fibromyalgia? Med Hypotheses 1997 Feb;48(2):125-35
Thyroid autoimmunity relating to
dysregulation of thyrotropin releasing hormone.(TRH)
Aarflot T, Association between chronic widespread musculoskeletal complaints
and thyroid autoimmunity. Results from a community survey. Scand J Prim Health
Care 1996 Jun;14(2):111-5
Lowered basal values of seratonin
Lowe JC, et.al., Mutations in the c-erbA beta 1 gene: do they underlie
euthyroid fibromyalgia? Med Hypotheses 1997 Feb;48(2):125-35
Lowered basal values of free
triiodothyronine (FT3)
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Lowered basal values of oestrogen.
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl 2000;113:8-12
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Increased secretion of ACTH and
prolactin
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Neeck G, Thyroid function in patients with fibromyalgia syndrome. J Rheumatol 1992 Jul;19(7):1120-2
Griep EN, et.al., Pituitary release of growth hormone and prolactin in the
primary fibromyalgia syndrome. J Rheumatol. 1994 Nov;21(11):2125-30.
Blunted response of TSH
Riedel W, Secretory pattern of GH, TSH, thyroid hormones, ACTH, cortisol, FSH,
and LH in patients with fibromyalgia syndrome following systemic injection of
the relevant hypothalamic-releasing hormones. Z Rheumatol 1998;57 Suppl 2:81-7
Lowered hypothalmic function
Neeck G, Neuroendocrine and hormonal perturbations and relations to the
serotonergic system in fibromyalgia patients. Scand J Rheumatol Suppl
2000;113:8-12
Elevated activity of Hypothalamic CRH
neurons (corticotropin-releasing hormone)
Neeck G, Hormonal pertubations in fibromyalgia syndrome. Ann N Y Acad Sci 1999
Jun 22;876:325-38;
The Correlation between Fibromyalgia and Mycoplasmas
<ALIGN="LEFT" Mycoplasmas require a large amount of cholesterol and other sterols for growth and reproduction. If mycoplasmas are present and are competing for these sterols intracellularly, less is available to the body and especially the neuroendocrine system for the sythesis and manufacture of steroids like estrogens, growth hormones and cortisols which many FMS patients have been found to be deficent in.
Mycoplasmas also need and utilize proteins derived from amino acids. Amino acids are the core building blocks in the neuroendocrine system for the synthesis of most chemicals produced and used in the complex intricate pathways of the neuroendocrine system including thyroid hormone production and other chemicals taken up and used in the HPA. This may cause the deregulation of the neuroendocrine system thru the loss of vital nutrients required to maintain regulation.
Mycoplasma maintains a defense mechanism which encodes tryptophan to hide from normal immune responses. If enough tryptophan was utilized from host cells in the neuroendocrine system for this purpose, less would be available to the body for the normal synthesis of tryptophan to seratonin, thus possibly deregulating or lowering seratonin levels and causing depression and sleep disorders most FMS patients present.
Mycoplasmas have the ability to attached to any cell in the body and cause that cell to malfunction, acting differently, thereby causing different interactions with other cells. If mycoplasmas invaded and attached to various cells in endocrine organs, it could cause the widespread deregulation of the entire endocrine system described in the previous research shown above, because of the complex interactions between these organs and the chemicals they produce and utilize.
For more information on how mycoplasmas cause disease and deregulation of systems, organs and cells, see the Simple File on Mycoplasmas which also includes treatment protocols or the more Technical file on Mycoplasmas which provides more links to clinical research published about their actions and pathogenisis.