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Role of increased cerebrospinal fluid pressure

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Plain Language Summary

The cause of fibromyalgia (FM) and chronic fatigue syndrome (CFS) is not yet elucidated. Disturbances in the interactions between the hypothalamus, pituitary gland, and adrenal glands (the hypothalamo-pituitary-adrenal (HPA) axis) in FM and CFS may result in abnormal hormone production. However, a novel hypothesis proposes that moderate increases in cerebral and spinal fluid pressure may underlie both FM and CFS. Increased cerebral pressure may impede blood flow in the pituitary gland, resulting in hormonal disturbances. Indeed, it is well known that severely increased cerebral pressure can cause compression and flattening of the pituitary gland, potentially leading to pituitary hormone deficiency, termed empty sella syndrome. The sella (turcica) is a saddle-shaped notch in the bone at the base of the skull where the pituitary gland is located.

A search of the scientific literature revealed that increased cerebrospinal fluid pressure, obesity, female sex, headache and migraine, fatigue, visual disturbances, vertigo, hearing loss, and widespread pain were all more prevalent in empty sella, FM and CFS patients than in healthy individuals. Furthermore, it was demonstrated that the injection of substances to stimulate pituitary hormone production resulted in similar responses, including reduced cortisol, growth hormone, luteinizing hormone, and thyroid-stimulating hormone production and increased prolactin production, in all three conditions compared to healthy individuals. The findings of this review provide further support for the hypothesis that moderate or intermittent increases in cerebrospinal fluid pressure are involved in the pathogenesis of FM and CFS and should stimulate further research into the causes of these conditions.

Introduction

Fibromyalgia (FM) and chronic fatigue syndrome (CFS) are overlapping pain conditions whose etiopathogenesis is not yet elucidated. Hypothalamo-pituitary-adrenal (HPA) axis dysfunction is reflected in the hormonal disturbances found in FM and CFS.1–3 Several study groups have previously proposed that mild or intermittent forms of intracranial hypertension or cerebrospinal fluid pressure dysregulation may be involved in the etiopathogenesis of FM/CFS.4–8 Indeed, idiopathic intracranial hypertension and FM/CFS have several clinical characteristic symptoms in common, such as fatigue, widespread pain and paraesthesia, headaches, cognitive dysfunction, and brain fog.5

More severe cases of intracranial hypertension may cause significant compression of the pituitary gland, eventually leading to empty sella (ES) on brain magnetic resonance imaging (MRI). ES involves the herniation of the subarachnoid space within the sella turcica, associated with an elongated pituitary stalk and a flattening of the pituitary gland to less than 2 mm. Partial ES is diagnosed when < 50% of the sella is filled with cerebrospinal fluid, and total ES is diagnosed when >50% is filled with cerebrospinal fluid.

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Primary ES is diagnosed in cases with unknown etiology when all secondary causes of ES are excluded, such as previous surgical, pharmacological or radiotherapy treatment of the pituitary gland.9

Primary ES is not just a neuroradiological finding without clinical implications. Indeed, one or more pituitary hormone deficiencies may be present in a significant proportion of patients with total and partial ES.10–14 We hypothesize that hormonal disturbances in FM/CFS can be the result of pituitary gland compression owing to intermittently or moderately increased cerebrospinal fluid pressure, which impedes the blood flow in the pituitary gland and stalk.

The aim of this narrative review was to explore the similarities in clinical characteristics between primary ES and FM/CFS.

Materials and Methods

PubMed and Web of Science (WOS) databases and the reference lists of the included studies were searched for English language articles published from 1985 until 2022 using the terms empty sella, FM and CFS in combination with the terms pituitary gland, increased cerebral pressure, growth hormone (GH), prolactin (PRL), cortisol, adrenocorticotropic hormone (ACTH), thyroid hormones, and gonadal hormones. Data regarding symptoms and hormonal levels in patients with primary ES, FM and CFS were compared and evaluated in reference to the hypothesis of a shared mechanism of underlying increased or dysregulated cerebrospinal fluid pressure.

A Discussion of the Similarities Between Primary ES and FM/CFS

The similarities between primary ES and FM/CFS are listed in Table 1.

Table 1 Similar Characteristics of Primary ES, FM and CFS

Cerebrospinal Fluid Pressure Dysregulation

In patients with intracranial hypertension, insufficient hormone secretion from the pituitary gland is caused by the compression of the pituitary gland against the sella turcica and the compression and eventual stretching of the pituitary stalk by the downward compression of the pituitary gland.9,11,26 Thus, similar to pituitary compression by an adenoma (secondary ES), increased cerebrospinal fluid pressure may hamper hormone production.13

Primary ES is almost always secondary to dysregulation of intracranial pressure even when incidentally found in asymptomatic cases. Idiopathic intracranial hypertension without papilledema is currently severely underestimated or misdiagnosed because the upper limit of the current normal range is set too high and because of a largely unrecognized high prevalence of asymptomatic cases. It has been suggested that the prevalence of idiopathic intracranial hypertension without papilledema might be up to three times higher than that of idiopathic intracranial hypertension.93 A possible mechanism that has been proposed is reduced intracranial compliance that precedes the increase in intracranial pressure and that may already be pathologic in cases lacking a detectable increase in intracranial pressure at lumbar puncture. Hence, opening pressure values greater than 25 cm H2O are not required (and potentially misleading) in diagnosis of idiopathic intracranial hypertension without papilledema.94

Intracranial hypertension involves a spectrum that begins with milder and intermittent forms that progress into ES and ends with more severe forms of idiopathic intracranial hypertension, presenting with papilledema, severe headache and visual field defects. Indeed, only 8 to 15% of patients with ES progress to develop these severe idiopathic intracranial hypertension symptoms, but in contrast, up to 94% of patients with severe idiopathic intracranial hypertension already show ES.9

Using a lumbar constant-rate infusion test, pressure anomalies were revealed in 109 (77%) of 142 primary ES patients: pathological resting intracranial pressure (range 19–35 cm H2O) in 88 patients (62%) and a reduction in the cerebrospinal fluid absorption rate despite normal basal intracranial pressure in 21 patients (15%).10

In patients with FM/CFS, moderately high cerebrospinal fluid pressures were found during lumbar puncture. In 30 patients with chronic widespread pain or FM, the mean cerebrospinal opening pressure was 19.7 cm H2O (range 11–32 cm H2O). Sixteen patients (53%) exhibited a pressure ≥19 cm H2O. Moreover, spinal fluid evacuation temporarily improved bodily pain in 21 of 30 patients (70%).4

Similar results were seen in patients with CFS. A lumbar puncture in 20 patients revealed a mean cerebrospinal fluid pressure of 19 cmH2O (range 12–41 cmH2O). Ten patients (50%) exhibited a pressure >19 cm H2O. Spinal fluid evacuation temporarily improved headaches in 17 CFS patients (85%).95 Additionally, brain MRI in 205 patients with CFS revealed an increased optic nerve sheath diameter as a sign of intracranial hypertension in 55%.7

Hormonal Anomalies in Primary ES and FM/CFS

The anterior lobe of the pituitary gland releases PRL, GH, ACTH, follicle-stimulating hormone (FSH), luteinizing hormone (LH) and thyroid-stimulating hormone (TSH) (Table 2). The posterior lobe of the pituitary gland stores and releases the hormones produced by the hypothalamus—antidiuretic hormone (ADH) and oxytocin. The pituitary stalk contains the vascular connections between the hypothalamus and the pituitary gland and the neuronal connections between the pituitary gland and the brain. A disruption of the blood flow in the pituitary gland or of the connections in the stalk due to compression from increased cerebrospinal fluid pressure may result in a disturbance of pituitary hormone secretion. Moreover, increased pressure on the pituitary tissue may also lead to functional insufficiency of the pituitary cells.42

Table 2 Overview of the Hypothalamic and Pituitary Hormones

An examination to evaluate pituitary function includes blood tests of hormone levels. However, stimulation tests are required for a more comprehensive examination of the adrenocortical axis and somatotropic axis.9,11,96 Some degree of hypopituitarism (one or more hormone deficiencies) is present in two-thirds of patients with total primary ES and is present in an important number of patients with partial primary ES.12,14

The Hypothalamo-Pituitary Adrenocortical Axis (HPA Axis)

Corticotropin releasing hormone (CRH) from the hypothalamus stimulates the secretion of ACTH, which in turn leads to the adrenal secretion of cortisol and aldosterone. ACTH deficiency in association with primary ES has been reported in several case studies. Low ACTH levels in primary ES were found to be associated with low cortisol levels.9,13,15,16 Low cortisol levels were found in up to 62% of patients with primary ES.14,17

In CFS/FM, reduced ACTH and cortisol levels are found during the morning physiological peak ACTH secretion.18,19 A meta-analysis of 85 studies found a significant reduction in basal cortisol levels in male and female patients with CFS and in female patients with FM compared to healthy controls.1

A pituitary challenge test in FM using a CRH injection demonstrated a blunted ACTH response.20 Additionally, a significant 30% reduction in the ACTH responses to hypoglycemia was observed in women with FM.21

Globally, a pituitary challenge test in CFS patients using low-dose dexamethasone and CRH combined reduced cortisol responses.22 Conversely, another study using a challenge test with CRH or naloxone detected no difference with respect to the ACTH and cortisol response in CFS patients and healthy individuals.23

Furthermore, two studies also found significantly lower aldosterone levels in patients with CFS than in controls.24,25

In a narrative review, Cleare41 found no changes in HPA axis function during the onset and early stages of CFS. According to our hypothesis, this late effect on the HPA axis may be due to the limited effect of the moderately increased cerebrospinal fluid pressure in the early stages, whereas longstanding increased cerebrospinal fluid pressure is more likely to affect pituitary function.

The Hypothalamo-Pituitary Somatotropic Axis

GH stimulates the liver to secrete insulin-like growth factor-1 (IGF-1). Therefore, IGF-1 levels are a surrogate marker for GH secretion. IGF-1 mediates the anabolic and growth-promoting effects of GH. It has been postulated that GH deficiency is an early event in patients with primary ES and that this deficiency could be related to the anatomical disposition of the cells within the anterior pituitary that produce GH, which could make these cells more vulnerable to increased pressure. However, some authors suggest that obesity might play a role because of its action in decreasing GH secretion.11

GH deficiency is one of the most common pituitary disorders associated with primary ES.9,96 When the GH levels of patients with primary ES were compared with those of healthy individuals, most studies reported decreased levels in up to 60% of patients.11,14,26,27

The stimulation of the pituitary gland using growth hormone-releasing hormone (GHRH) + arginine elicited a lower GH response in 40% of primary ES patients than in controls. In this study, BMI-related cutoff limits were used; thus, weight did not play a role.42 GHRH + arginine injection also revealed GH/IGF-I axis dysfunction in 39% of adults with primary ES.27 Serum IGF-1 levels in primary ES patients were positively correlated with pituitary volume.16

In FM, approximately 30–34% of patients present lower levels of basal GH or IGF-1 than healthy individuals.28–34 In a review of 26 studies, overall, low levels of IGF-1 and often a suboptimal response to GH stimulation tests were documented in patients with FM.20,31,32 Two studies did not find any differences in IGF-1 levels between patients with FM and healthy controls.35,36

In patients with CFS, lower nocturnal levels of GH37–39 or lower levels of IGF-1 than in controls were documented.37,40 Other studies found no differences in basal IGF-1 levels.35,38,41 However, challenge tests in CFS patients revealed a reduced peak value GH response to insulin-induced hypoglycemia versus controls40 and in nonobese CFS patients versus nonobese controls.38 Thus, in the latter study, obesity did not interfere with the results.

Prolactin (PRL)

Dopamine, produced in the hypothalamus, is an inhibitor of pituitary PRL secretion, whereas thyrotropin releasing hormone (TRH) is a stimulator. Hyperprolactinemia, usually mild (less than 50 ng/mL), is probably the most common endocrine disturbance in patients with primary ES, with an incidence from 10 to 37.5%. The proposed mechanism is pituitary stalk compression due to increased cerebrospinal fluid pressure, with a subsequent decrease in dopamine.11,26,42

In FM, the PRL serum levels vary across studies. Compared to controls, lower28,43 or similar18 or slightly higher PRL levels29,33,44,45 have been documented. On the other hand, aFM diagnosis was highly prevalent in patients with high PRL serum levels. In a study of women with hyperprolactinemia, 71% were diagnosed with FM versus only 4.5% in women with normal PRL levels.46

When challenging the pituitary gland in FM patients using an injection of a cocktail of hypothalamic releasing hormones or an injection of buspirone, a higher PRL response was elicited in FM patients than in controls.20,49,50 Similar to ES, the PRL response to buspirone in FM has been suggested to be mediated through the antagonistic effects of dopamine.50 During a hypoglycemia challenge test in FM patients, the PRL response showed wide interindividual variation and did not differ between patients and controls.44

In CFS patients, PRL serum levels also vary across studies. Compared to controls, similar39,44,47 or significantly higher levels have been reported.38,48 Similar to FM, stimulating the pituitary gland with buspirone significantly increased the PRL response in male CFS patients compared to controls.51

According to our hypothesis, moderately increased cerebrospinal fluid pressure in FM/CFS may be involved in the dysfunction of the pituitary gland and the pituitary stalk. The intracranial pressure in FM and CFS may not be high enough to significantly change basal PRL levels, explaining the variability across studies. However, challenge tests may expose minor pituitary dysfunction in FM/CFS, such as increased PRL secretion due to decreased dopamine availability.

The Hypothalamo-Pituitary Gonadal Axis

Gonadotropin-releasing hormone stimulates the pituitary gland to produce and secrete LH and FSH. These hormones stimulate the ovaries to produce estrogen and progesterone or the testicles to produce testosterone.

Blood samples from primary ES patients showed significantly decreased FSH, LH and sex hormone levels. Additionally, erectile dysfunction was reported in 53–100% of male patients, and irregular menses were reported in 40% of female patients.10,12,14,16 The latter symptoms may be indications of abnormal hormone levels.

The results of comparisons of the LH, FSH, and sex hormone levels in patients with FM versus healthy controls vary across studies, with higher serum levels of LH and FSH;43 significantly lower estrogen levels;20,43 no difference in testosterone levels;43 and no differences in FSH, progesterone, or estradiol levels or the pulsatile secretion of LH all being reported.18,52 However, there was a significant blunted LH response to challenge with LHRH in FM patients, while the increase in FSH did not differ compared to that in controls.20

In CFS, no significant differences in FSH, LH, estradiol, or progesterone levels were documented.18,52,53 The findings of challenge tests were not reported.

The Hypothalamo-Pituitary Thyrotropic Axis

In one study in primary ES patients versus controls, TSH serum levels were lower in ES patients, but the mean serum free T4 and free T3 values were similar.54 Another study found lower TSH and lower free T4 and free T3 levels in 37% of primary ES patients than in controls.14 Moreover, abnormal (impaired, or exaggerated/delayed) TSH responses to exogenous TRH injection were found in 79% of patients with primary ES when compared to healthy individuals.54 In 38 patients with asthenia, an MRI and endocrinological evaluation revealed 22 (58%) patients with ES (6 complete ES and 16 partial ES). In this study, TSH and T4 serum levels were lower in the ES group and partial ES group than in the asthenia patients with normal pituitary size. TSH serum levels were not correlated with pituitary size.97

In FM/CFS patients, TSH levels vary across studies. In one study in patients with FM, basal TSH serum levels were significantly higher than those in controls,33 whereas another study demonstrated normal TSH and normal basal T3 and T4 levels.49 Significantly higher serum TSH levels were found in CFS patients than controls, whereas the free thyroxine level of CFS patients was comparable to that of controls.38 In a case‒control study in CFS patients, free T3 was below the reference range in 16% of patients versus 7% of controls (odds ratio (OR) 2.56), whereas TSH was in the normal range.55

A challenge test in FM patients using intravenous injection of TRH elicited a lower TSH and thyroid hormone secretion response,20,49 which is a similar response to TRH as in primary ES patients. To our knowledge, no challenge tests have been reported for CFS patients.

Conclusion on Hormone Serum Levels and Challenge Test Responses in Patients with Primary ES, FM and CFS

Lower pituitary hormone levels have been documented in a significant proportion of patients with primary ES than in healthy controls, indicating pituitary insufficiency. On the other hand, in primary ES, PRL serum levels were elevated due to insufficient supply of the PRL inhibitor dopamine to the pituitary gland.

The results of comparisons of ACTH, cortisol, GH, FSH, sex hormone, TSH, and PRL levels in patients with FM/CFS versus healthy individuals vary across studies. These disparities among studies may be due to the limited number of studies performed, the limited number of patients in the studies, diurnal variation, and the methods used. However, according to our hypothesis, the milder form of intracranial hypertension in FM/CFS than in ES will likely have less impact on basal pituitary hormone secretion.

Nevertheless, when using challenge tests to evaluate pituitary function, the hormone level responses in patients with FM/CFS are generally the same as in patients with primary ES. In patients with FM/CFS, challenge tests may identify minor pituitary dysfunction, such as a blunted ACTH and cortisol response, a blunted GH response, an increased PRL response (due to a lack of dopamine), a blunted LH response, and a blunted TSH response to the stimulation of the pituitary gland.

Obesity

In obese patients, excess visceral fat raises intra-abdominal pressure, which leads to decreased thoracal distensibility and increased intrathoracic pressure. Consequently, pleural and cardiac filling pressures increase, which obstructs venous return from the brain, leading to increased intracranial pressure.9 Additionally, morbid obesity can induce hypoxia and hypercapnia, which may be associated with chronically elevated cerebrospinal fluid pressure.11,69 Hence, 50% of primary ES patients are obese.56

Obesity is also a prevalent comorbidity in patients with FM/CFS. A systematic review of studies found that the overall prevalence of obesity in FM patients ranged from 43% in the USA to 32% in Europe and 22.1% in Asia. On the other hand, the prevalence of FM in obese individuals was between 37 and 51% compared to 4% reported in the general population. The majority of studies also demonstrated that obesity is associated with worse FM symptoms, including severe pain, a higher number of tender points, stiffness, fatigue, poor physical functioning/disability, poor sleep, cognitive dysfunction, and lower quality of life.57,98

An observational study in a large cohort of 16-year-old CFS patients demonstrated that adolescents with CFS were four times more likely to be obese than healthy adolescents of the same age.58

Obesity has been identified as a risk factor for FM.57 Moreover, obesity has been identified as a risk factor for HPA axis dysfunction in FM patients.36,41 According to our hypothesis, as obesity increases intracranial pressure, it may increase the risk for developing FM and primary ES.

Female Sex

Primary ES, FM and CFS are significantly more prevalent in female patients. The female-to-male sex ratio of primary ES ranges from 5:126 to 6:1.9,11 The female-to-male sex ratio in both FM59 and CFS is estimated to be 9:1.60 The reason for this overrepresentation of women is not yet known.

Headaches

The predominant symptom in primary ES is headache, which is the main reason for imaging tests. Headache has been reported in between 59% and 88% of patients.10,11,26,69

According to De Simone et al,99 increased intracranial pressure is likely involved in the progression of migraine in most patients diagnosed with unresponsive chronic migraine. Indeed, in unresponsive migraine patients, lumbar puncture with cerebrospinal fluid withdrawal resulted in sustained remission of chronic migraine pain in 77%.99

FM/CFS patients also often suffer headaches and migraines. An observational study in FM patients reported a 29% prevalence of migraine and a 59% prevalence of tension-type headache.61 An epidemiological study reported a high prevalence of headaches in patients with FM. Chronic headache was reported by 76% of patients, with 84% patients reporting substantial or severe impact from their headaches. Migraine was diagnosed in 63% of FM patients who reported headaches, with probable analgesic overuse headaches in only 8%.62 In a cross-sectional study in patients with CFS, the prevalence of migraine headaches was 84%, and that of tension-type headaches was 81% compared to 5% and 45% in healthy controls, respectively.63

Fatigue

Fatigue is a common symptom in primary ES patients.12,15,27,42 Additionally, an MRI study in patients with asthenia as the main complaint revealed that 58% of patients had ES.97 Fatigue may be due to hormonal disturbances27 or to increased intracranial pressure.6

In FM/CFS patients, fatigue is one of the core symptoms.5,95

Ophthalmological Abnormalities

A comprehensive review on ES syndrome revealed that ophthalmological disturbances included visual acuity worsening (13–37%), blurred vision (29%), diplopia (2%), and defects in the oculomotor nerve (1%). The ophthalmological signs in primary ES syndrome were mainly due to the presence of increased intracranial pressure.9 Additionally, an analysis using optical coherence tomography revealed that the retinal nerve fiber layer thickness of asymptomatic ES patients was thinner than that of controls. The authors assumed that ischemic and mechanical mechanisms rather than a mass effect on the optical nerve may be the cause of these abnormalities.67

In FM, retinal nerve fiber thinning,68 decreased optic disc perfusion,100,101 blurred vision (in 46%),64 and visual field defects64 have been detected. According to our hypothesis, similar to primary ES, these abnormalities may be due to perfusion changes in the optic nerve due to the mechanic and ischemic effects of moderately or intermittently increased intracranial pressure.

Additionally, diplopia (eye motility dysfunction) has been reported in FM64,102 and CFS.65,66 According to our hypothesis, eye motility dysfunction in FM may be caused by the forced filling of the third, fourth or sixth cranial nerve with cerebrospinal fluid due to increased intracranial pressure.5

Vestibulocochlear Disturbances

In primary ES patients, dizziness, syncope, cranial nerve disorders, convulsions, and depression have been reported in approximately 40% of patients.26,69 In a case‒control study, the prevalence of partial or total ES in patients with Menière’s disease was 46%. There was also a high prevalence of radiographic signs of intracranial hypertension in patients with Menière’s disease.70 The neurological signs in patients with primary ES syndrome are predominantly due to the presence of increased intracranial pressure: values from 19 to 33 cm H2O were found to be insufficient to provoke a clear case of intracranial hypertension but sufficient to maintain the neurological symptoms of primary ES syndrome, such as headache and visual disturbances.9 Up to 89% of patients with primary ES are diagnosed with hearing loss, most frequently sensorineural hearing loss (78%).69

In FM patients, a Dix-Halpike maneuver elicited positional rotary vertigo in 21%.71 Additionally, 30% to 84% of FM patients report vertigo.64,72 FM patients have a higher likelihood of reporting hearing loss than controls (OR 4.6).77 In a nationwide population-based retrospective cohort study in patients with FM, the overall hearing loss risk was found to be 1.5-fold higher than that in a non-FM group after adjustment for sex, age, and comorbidities. Specifically, similar to primary ES, significantly greater sensorineural hearing loss was detected in patients with FM than in those without FM.76 Other studies in FM patients versus controls found worse audiological test results in FM patients versus controls.74,75

Vestibular function testing in CFS patients revealed that patients performed below average in dynamic posturography testing, especially in tests requiring individuals to depend heavily on the vestibular system.73 To our knowledge, there are no studies on hearing loss in patients with CFS.

In intracranial hypertension, hearing loss and vertigo may result from the forced filling of the middle and inner ear with cerebrospinal fluid via the cochlear aqueduct. When a lumbar puncture was performed in patients with idiopathic intracranial hypertension, vertigo, dizziness, fluctuating hearing loss, tinnitus, and aural fullness improved.103

Bodily Pain

Whereas bodily pain is a core symptom in FM/CFS, it is less well known that idiopathic intracranial hypertension is associated with bodily pain. Allodynia, defined as the perception of pain or discomfort induced by non noxious stimuli, has been reported in 50% of patients with intracranial hypertension.85 Additionally, neck pain, backpain, and radicular pain due to the forced filling of the nerve root sheaths with cerebrospinal fluid have been reported in patients with intracranial hypertension.78–84

Bodily pain in FM/CFS has been attributed to the mechanism of central nervous sensitization. However, in FM, electrodiagnostic assessments have detected radicular abnormalities in the majority of patients.86,87 Additionally, a meta-analysis of 20 biopsy studies including 903 FM patients revealed small-fiber neuropathy in up to 49% of FM patients.89 Small-fiber neuropathy is the consequence of damage to the fibers that are responsible for nociceptive processing and may produce debilitating pain.

According to our hypothesis, in the same way that the thinning of the optic nerve fiber layer in primary ES is due to ischemic and mechanic mechanisms,67 small or large nerve fibers or neurons may be damaged in the dorsal root ganglion due to ischemia and mechanical stress from increased cerebrospinal fluid pressure.

Pain is also a common complaint in patients with CFS.90 The 2011 International Consensus Criteria on CFS describe pain with neuropathic characteristics (sharp, shooting, burning) as a common symptom in CFS.91 Skin biopsy studies or electrodiagnostic tests have not been reported in CFS. One study in CFS patients with low cardiac filling pressures during exercise indirectly suggested small-fiber neuropathy in 31% of patients.92

Limitations

The hormone level variability among studies may be due to the paucity of available studies and the often limited sample sizes and different methodologies used in the studies. However, almost all of the studies demonstrate similar responses to pituitary challenge tests in primary ES and in FM/CFS.

Conclusions

In this narrative review, we found several disease characteristics that are similar in primary ES and FM/CFS. Hormone secretion responses to pituitary challenge tests were similar in all three conditions. Primary ES is mainly caused by increased intracranial pressure. According to our hypothesis, similar to primary ES, the hormonal disturbances in FM/CFS may be attributed to compressive effects of the cerebrospinal fluid on the pituitary gland, impeding the blood flow in the pituitary gland and the pituitary stalk.

Furthermore, similar neurological and ophthalmological signs, obesity, headaches, and fatigue are prevalent in primary ES and FM/CFS.

Therefore, these findings provide further support for the hypothesis that moderately or intermittently increased cerebrospinal fluid pressure is involved in the pathogenesis of FM/CFS.

Abbreviations

FM, fibromyalgia; CFS, chronic fatigue syndrome; HPA, hypothalamo-pituitary-adrenal; ES, empty sella; MRI, magnetic resonance imaging; GH, growth hormone; PRL, prolactin; ACTH, adrenocorticotropic hormone; FSH, follicle-stimulating hormone; LH, luteinizing hormone; TSH, thyroid-stimulating hormone; ADH, antidiuretic hormone; CRH, corticotropin releasing hormone; IGF-1, insulin-like growth factor-1; GHRH, growth hormone-releasing hormone; TRH, thyrotropin releasing hormone; OR, odds ratio.

Funding

This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.

Disclosure

The authors declare that they have no competing interests in this work.

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73. Ash-Bernal R, Wall C, Komaroff AL, et al. Vestibular function test anomalies in patients with chronic fatigue syndrome. Acta Otolaryngol. 1995;115(1):9–17. doi:10.3109/00016489509133339

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COVID-19 and flu activity in Manitoba drops again

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COVID-19 and influenza activity is on a steady decline in Manitoba, with hospital admissions and new cases dropping significantly for the third straight week.

There were seven people hospitalized for COVID-19 from Jan. 15-21, the latest provincial surveillance data says. The previous reporting week had 28 hospitalizations.

Admissions to intensive care units, due to severe cases, also went down from six to three in that same span.

The total number of deaths related to the virus increased by 15 in the most recent surveillance report, compared to nine the previous week and 25 the week before that.

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There were just 59 new COVID-19 cases detected in the latest report, a more than 50 per cent decline from the 122 in the Jan. 8–14 report. Those numbers, though, are considered significant undercounts due to limited testing offered by Public Health. The province does not track results from home tests.

The weekly test positivity rate for COVID-19 went down to 11.3 per cent from 12.3 per cent in the previous report.

Flu test positivity falls below 1%

As for Influenza A, the primary flu strain this season, the number of cases detected in the current surveillance week is 10, versus 18 the prior week.

A total of two people were admitted to hospital for flu symptoms, with no ICU cases, which is identical to the previous week. Two additional deaths were attributed to the flu in the report for Jan. 15-21, compared to one the previous week.

The current weekly test positivity for Influenza A is 0.8 per cent, whereas it was 1.9 per cent a week ago.

The national rate is 1.3 per cent.

Other respiratory viruses continue to circulate as well, but the test positivity rate for and detection of respiratory syncytial virus (RSV) have both decreased as well.

The number of detected RSV cases in the latest report is 105 (down from 131) and the test positivity rate is 8.3 per cent (down from 8.7).

Wastewater surveillance data indicates sustained activity of COVID-19 in Winnipeg and Brandon but at lower levels.

The next reporting date is Feb. 3.

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Study Establishes Connections Between Emotional Maltreatment, Psychiatric Disorders

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New study results published in Child Maltreatment have found links between emotional maltreatment, also known as psychological violence, and psychiatric disorders in childhood and adolescence.

Emotional maltreatment can be challenging to recognize and record, both in research and in practice. Navigating that challenge resulted in an elaborate study conducted by researchers at the Faculty of Medicine in the University of Leipzig, with the goal of understanding the psychological effects that abuse, neglect, and emotional maltreatment have on children and adolescents.

Examples of emotional abuse include when parents subject their children to extreme humiliation, threaten to put them in foster care, or blame children for their own psychological distress or suicidal thoughts. Physical violence also plays a crucial role in the development of psychiatric disorders.

“Our study findings clearly show that emotional maltreatment is not only a very common form of maltreatment, but also one with psychiatric consequences that are similar to or even more severe than other forms of maltreatment,” said study leader and last author Lars White, PhD, in a press release.

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In their study of 778 children, researchers found that 80% of the children and adolescents who reported having been mistreated had also experienced emotional maltreatment. This makes emotional maltreatment the most common form of child abuse.

Additionally, the investigators were able to show that of all forms of maltreatment, psychological violence had the strongest effects on the psyche of the children and adolescents, even in comparison with forms of maltreatment that generally receive more attention, such as physical abuse. In younger children between 3 and 8 years of age, emotional maltreatment led primarily to behavioral problems, whereas in older children it was more likely to lead to depression and anxiety disorders.

To conduct the study, family data were collected with extensive interviews and the researchers analyzed files from youth welfare offices for evidence of maltreatment experiences. The sample consisted of 306 children and adolescents with an experience of maltreatment and 472 participants without these experiences. Among other sources, participants were recruited via the residents’ registration offices, daycare centers, child and youth psychiatry centers, and youth welfare offices in Leipzig and Munich.

“We are particularly grateful for the support of the youth welfare offices because this enabled us to recruit families for the study who have had extremely difficult experiences and who are otherwise difficult to reach for research projects,” said lead author Jan Keil, DrPhil, in the press release.

The findings illustrate that the risk of developing psychiatric disorders after maltreatment is already heightened in early and middle childhood, which underlines the need for early intervention. The authors said emotional maltreatment should be understood as a dimension of abuse unto itself and should be a key focus in both research and treatment efforts.

“We need to educate parents so that they take the child’s perspective more often,” White said in the press release. “As recently as 30 years ago, the commonly held view was that children should be left to cry and that what they experience in childhood they forget anyway. But increasingly, there is a complete shift in attitudes and an appreciation that we need to reach out to the youngest children when they are showing difficult emotions, such as being angry or sad.”

REFERENCE

From emotional maltreatment to psychiatric disorders in childhood and adolescence. News release. EurekAlert; January 12, 2023. Accessed January 17, 2023. https://www.eurekalert.org/news-releases/976487

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Leaders in discovery: five USask researchers honoured with top provincial health awards

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“Dr. Gerdts’ scientific and leadership accomplishments throughout his illustrious career make him most deserving of this award and recognition. We are grateful for his leadership of VIDO, particularly during the challenging times of the COVID-19 pandemic. He was able to grow and strengthen Canada’s pandemic response and was an integral part in creating Canada’s Centre for Pandemic Research,” said USask Vice-President Research Baljit Singh. “We are grateful for his ongoing commitment to our One Health Signature Area of Research and for inspiring the next generation of scientific leaders.”

Beyond his impressive professional achievements of publications and citations, Gerdts has been a mentor and leader in One Health, which recognizes the integral connections between human, animal, and environmental health. At the institutional level, he has been a champion for One Health as a signature area of research at USask. On the international stage, he co-led the Natural Sciences and Engineering Research Council of Canada (NSERC)-funded Integrated Training Program in Infectious Diseases, Food Safety and Public Policy, training more than 200 young researchers from 15 countries.

“This award is recognition of the many colleagues and collaborators I have worked with over the years, including an outstanding group of individuals here at VIDO,” said Gerdts. “I am excited to continue to develop solutions for emerging diseases of humans and animals. The support from SHRF and other funders over the years has helped to make this vision reality.”

With 91 grants totaling more than $117 million as principal investigator, more than $79 million as co-applicant and over $10 million in contract research, Gerdts has led the development of several vaccines and novel adjuvants—ingredients that help create a stronger immune response—for people and animals.

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His work helped to develop a universal protocol for vaccination of pregnant women to improve the health of newborn babies, and as a result, pregnant women now routinely receive the pertussis (whooping cough) vaccine to protect their newborns against the disease. Gerdts’ research focusing on the fetal immune system development was published in Nature Medicine, and his work on a single-immunization vaccine platform for neonates continues with research into a vaccine for pertussis and respiratory syncytial (RSV), which is undergoing production optimization so it can be ready for production in VIDO’s manufacturing facility and used in human clinical trials.

Under his leadership VIDO has experienced enormous growth, including the completion of its vaccine manufacturing facility that strengthens Canada’s production capacity, positioning VIDO as Canada’s Centre for Pandemic Research. He has also played an integral role in drawing top talent from around the globe to work and live in Saskatchewan, while at the same time elevating the province’s scientific reputation.

Since the beginning of the pandemic, Gerdts has demonstrated creative thinking and a keen ability to successfully bring together funders and interdisciplinary collaborators. His over 250 media interviews and presentations about COVID-19 are examples of his skills as a trusted scientific communicator.

Gerdts is among five USask researchers recognized by the provincial funding agency as part of its annual Santé Awards honouring health research excellence in Saskatchewan.

“We are proud of our researchers who have received these prestigious awards,” said Singh. “They are confronting the world’s greatest challenges head on through creativity and collaboration. Their collective impact includes discoveries for improved mental health and wellness, hope for new treatments for drug-resistant infections, and the expertise that will influence how our decision-makers will shape an accessible and culturally responsive healthcare system for the people of Saskatchewan.”

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