Recurrent sellar mass after resection of pituitary macroadenoma

Posted on June 17, 2015 by MaryO

A Puerto Rican woman aged 50 years presented to an ophthalmologist with complaints of vision changes, including difficulty seeing images in her peripheral vision in both eyes and difficulty in color perception. Her medical history was significant for menopause at age 43 years, type 2 diabetes and hypertension. She had no prior history of thyroid disease, changes in her weight, dizziness or lightheadedness, headaches, galactorrhea or growth of her hands or feet.

Formal visual fields showed bitemporal superior quadrantopsia, and she was sent to the ED for further evaluation.

Imaging and laboratory tests

A pituitary protocol MRI was performed that showed a large 3 cm x 2 cm x 2.2 cm mass in the pituitary with mild osseous remodeling of the sella turcica and mass effect on the optic chiasm (Figure 1). The mass was isointense with the brain parenchyma on T1-weighted and T2-weighted images and homogeneously enhanced after IV gadolinium contrast administration.

Baseline laboratory samples drawn at 11 p.m. in the ED showed a cortisol of 16.9 µg/dL (nighttime reference range: 3-16 µg/dL), adrenocorticotropic hormone 65 pg/mL (reference range: 6-50 pg/mL), prolactin 19.4 ng/mL (reference range: 5.2-26.5 ng/mL), thyroid-stimulating hormone 1.36 µIU/mL (reference range: 0.35-4.9 µIU/mL), free thyroxine 0.9 ng/dL (reference range: 0.6-1.8 ng/dL), triiodothyronine 85 ng/dL (reference range: 83-160 ng/dL), follicle-stimulating hormone (FSH) 11.1 mIU/mL (postmenopausal reference range: 26.7- 133.4 mIU/mL) and luteinizing hormone (LH) 1.2 mIU/mL (postmenopausal reference range: 5.2-62 mIU/mL).

 

Figure 1. T1-weighted MRI images with and without contrast of the pituitary. Coronal (A) and sagittal (C) images showed a large isodense (with brain parenchyma) 3 cm x 2 cm x 2.2 cm mass (red arrow) in the sella with superior extension to the optic chiasm. After gadolinium contrast, coronal (B) and sagittal (D) images show the mass homogenously enhances consistent with a pituitary adenoma.

Images courtesy of Pavani Srimatkandada, MD.

Given the patient’s high nighttime cortisol and adrenocorticotropic hormone (ACTH) levels, she underwent an overnight dexamethasone suppression test with 1 mg dexamethasone. Her morning cortisol was appropriately suppressed to less than 1 µg/dL, excluding Cushing’s disease.

Pituitary adenoma resection

The patient was diagnosed with a nonsecreting pituitary adenoma with suprasellar extension and optic chiasm compression with visual field deficits. The macroadenoma caused an inappropriately normal LH and FSH in a postmenopausal woman consistent with hypogonadotrophic hypogonadism.

She underwent transnasal transsphenoidal resection of the nonsecreting pituitary adenoma. The dural defect caused by the surgery was patched with an abdominal fat graft with a DuraSeal dura patch. A postoperative MRI showed complete resection of the adenoma with no evaluable tumor in the sella (Figure 2). Her postoperative course was complicated by transient diabetes insipidus requiring intermittent desmopressin; however, this resolved before her discharge from the hospital.

Figure 2. T1-weighted MRI images with contrast. Coronal views before (A) and after (B) transphenoidal tumor resection show complete resolution of the enhancing pituitary mass (A; red arrow) that is replaced with a new hypodense mass in the sella (B; yellow arrow). This mass is filled with cerebrospinal fluid with a residual rim of enhancing tissue. This is consistent with the development of a pseudomeningocele in the sella.

 

Postoperative testing confirmed secondary deficiency of the adrenal, thyroid and ovarian axes requiring hormone therapy. The patient had stable temporal hemianopia in the left eye with improved vision in the right eye.

Recurrent mass detected

One year after surgery, during a routine follow-up appointment, the patient reported no dizziness, lightheadedness, worsening vision changes, rhinorrhea or headache. She had a follow-up MRI of the brain with and without contrast, which showed the interval appearance of a mass in the sella that extended from the sphenoid sinus into the sella and came in contact with the optic nerve (Figure 3).

Figure 3. Axial MRI images of the sella after resection of pituitary adenoma. On T1-weighted images the mass (red arrow) in the sella is hypodense (black) compared with the brain parenchyma. On T2-weighted images, the mass (red arrow) is hyperdense (bright) compared with the brain, consistent with fluid. Cerebrospinal fluid in the sulci on the brain surface and the vitreous fluid within the eye are also hyperintense on T2-weighted images (yellow arrows).

 

On MRI, the mass was isodense with the cerebral spinal fluid (CSF) with a residual rim of enhancing normal pituitary tissue. This appearance is consistent with the postoperative development of a pseudomeningocele and not a solid mass in the sella (Table).

Pseudomeningoceles are abnormal collections of CSF that communicate with the CSF space around the brain; these occur after brain surgery involving duraplasty (incision and repair of the dura). Unlike meningoceles, pseudomeningoceles are not completely encased by a surrounding membrane, and they communicate with the circulating CSF. Similar to CSF, a pseudomeningocele is hypodense (dark) compared with brain on T1-weighted MRI images and hyperdense (bright) on T2-weight images.

 

Pseudomeningocele treatment

Treatment may be conservative or may involve neurosurgical repair if symptomatic. Little published data addresses the development of pseudomeningoceles after transsphenoidal pituitary surgery, but this complication occasionally occurs, especially if the dural incision is large. One study noted that pseudomeningoceles are one of the most common complications after suboccipital decompression for Chiari’s malformation, but the effect of this complication is unclear.

Endocrinologists must recognize that recurrent development of pituitary masses after transsphenoidal pituitary adenoma surgery may not represent regrowth of pituitary tissue, but instead development of a meningocele/pseudomeningocele. Pseudomeningocele can be easily confirmed because this fluid collection has very different MRI characteristics than pituitary adenoma (Table). Given that patients may remain asymptomatic after the development of a pseudomeningocele, periodic MRI imaging, hormonal evaluation and ophthalmologic monitoring of visual fields are required after transsphenoidal pituitary surgery.

References:
  • Hernandez Guilabert PM. Poster No C-1330. Presented at: European Society of Radiology; March 7-11, 2013; Vienna.
  • Parker SL, et al. J Neurosurg. 2013;doi:10.3171/2013.8.JNS122106.
For more information:
  • Stephanie L. Lee, MD, PhD, ECNU, is an associate professor of medicine and associate chief, in the Section of Endocrinology, Diabetes and Nutrition at Boston Medical Center. Lee can be reached at Boston Medical Center, 88 E. Newton St., Endocrinology Evans 201, Boston, MA 02118; email: stephanie.lee@bmc.org. Lee reports no relevant financial disclosures.
  • Pavani Srimatkandada, MD, is an endocrinology fellow in the Section of Endocrinology, Diabetes and Nutrition at Boston Medical Center. Srimatkandada can be reached at Boston Medical Center, 88 E. Newton St., Endocrinology Evans 201, Boston, MA 02118. She reports no relevant financial disclosures.

From http://www.healio.com/endocrinology/thyroid/news/print/endocrine-today/%7B82430fb6-bbe4-4908-a389-447eee8cd005%7D/recurrent-sellar-mass-after-resection-of-pituitary-macroadenoma

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Adrenal insufficiency – how to spot this rare disease and how to treat it

Posted on June 6, 2015 by MaryO

adrenal-glandsAddison’s disease, or adrenal insufficiency, is a rare hormonal disorder of the adrenal glands that affects around 8,400 people in the UK.

The adrenal glands are about the size of a pea and perched on top of the kidneys, and affect the body’s production of the hormones cortisol and sometimes aldosterone.

When someone suffers from adrenal insufficiency, those glands aren’t producing a sufficient amount of these hormones. This can have a detrimental effect on someone’s health and well-being. But because the symptoms are similar to a host of other conditions, Addison’s disease can prove tough to isolate.

What to look out for

According to advice provided by the NHS, the symptoms in the early stages of Addison’s disease, which affects both men and women, are gradual and easy to misread as they’re similar to many other conditions.

People can experience severe fatigue, muscle weakness, low moods, loss of appetite, unintentional weight loss, low blood pressure, nausea, vomiting and salt craving.

“Symptoms are often misread or ignored until a relatively minor infection leads to an abnormally long convalescence, which prompts an investigation,” says Professor Wiebke Arlt from the Centre for Endocrinology, Diabetes & Metabolism at the University of Birmingham.

Life-threatening condition

If Addison’s disease is left untreated, the level of hormones produced by the adrenal gland will gradually decrease in the body. This will cause symptoms to get progressively worse and eventually lead to a potentially life-threatening situation called an adrenal, or Addisonian, crisis. Signs include severe dehydration; pale, cold, clammy skin; rapid, shallow breathing; extreme sleepiness; severe vomiting and diarrhoea. If left untreated, it can prove fatal, so the patient should be admitted to hospital as an emergency.

Back to basics

To understand the disorder, it’s important to get to grips with the basics and that means understanding what the adrenal glands are – and so to the science.

“Adrenal glands have an inner core (known as the medulla) surrounded by an outer shell (known as the cortex) ,” explains Arlt.
The inner medulla produces adrenaline, the ‘fight or flight’ stress hormone. While the absence of this does not cause the disease, the cortex is more critical.

“It produces the steroid hormones that are essential for life: cortisol and aldosterone,” he adds.

“Cortisol mobilises nutrients, enables the body to fight inflammation, stimulates the liver to produce blood sugar and also helps control the amount of water in the body. Aldosterone, meanwhile, regulates the salt and water levels, which can affect blood volume and pressure.”

Why does it happen?

The disorder occurs if the adrenal glands are destroyed, absent or unable to function and failure of the glands themselves is known as primary adrenal insufficiency.

“It’s most often caused by autoimmune disease where the body’s immune system mounts an attack against its own adrenal glands,” explains Arlt.

“However it can also be caused by infection, most importantly by tuberculosis and sometimes by both adrenal glands being surgically removed.”

The pituitary effect

Another important cause is any disease affecting the pituitary gland, which is located behind the nose at the bottom of the brain.
“The pituitary is the master gland that tells the other glands in the body what to do,” continues Arlt.

“The pituitary gland produces a hormone called ACTH (adrenocorticotropic hormone to give it its full name), which travels in the blood stream to the adrenal glands.

“Here it acts as a signal, causing the adrenal glands to produce more cortisol. If the pituitary gland stops making ACTH, [then] cortisol production by the adrenals is no longer controlled properly and a condition called secondary adrenal insufficiency arises.”

But in most cases, aldosterone is still produced, which means that people suffering from secondary adrenal insufficiency have fewer problems than those with primary adrenal insufficiency.

Determining a diagnosis

Due to the ambiguous nature of the symptoms, a Short Synacthen Test (SST) needs to be performed in order to diagnose adrenal insufficiency.

“This measures the ability of the adrenal glands to produce cortisol in response to (the pituitary hormone) ACTH,” says Arlt. “When carrying out this test, a baseline blood sample is drawn before injecting a dose of ACTH, followed by drawing a second blood sample 30 to 60 minutes later. Failing adrenal glands will not be able to produce a certain level of cortisol.”

Getting treatment

If someone has been conclusively diagnosed with adrenal insufficiency, they should receive adrenal hormone replacement therapy as advised by an endocrinologist, a doctor specialising in hormone-related diseases.

“A normal adrenal gland does not need supplements to function properly and there is no recognised medical condition called ‘adrenal fatigue’,” warns Arlt.

“Either the adrenal gland is fine and needs no treatment or there is adrenal insufficiency due to adrenal or pituitary failure.”

So if in doubt, don’t self-diagnose but book an appointment with your GP.

For more information, visit Addison’s Disease Self-Help Group (www.addisons.org.uk) or Pituitary Foundation.

From https://home.bt.com/lifestyle/wellbeing/adrenal-insufficiency-how-to-spot-this-rare-disease-and-how-to-treat-it-11363985141306

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Silibinin from milk thistle seeds as novel, non-invasive treatment strategy for Cushing Disease

Posted on June 4, 2015 by MaryO
Silibinin has an outstanding safety profile in humans and is currently used for the treatment of liver disease and poisoning. Scientists at the Max Planck Institute of Psychiatry in Munich discovered in collaboration with scientists from the Helmholtz Zentrum München in cell cultures, animal models and human tumor tissue that silibinin can be applied to treat Cushing Disease, a rare hormone condition caused by a tumor in the pituitary gland in the brain. The researchers have filed a patent and now plan clinical trials using silibinin as a non-invasive treatment strategy. Thus, in future, patients might not have to undergo brain surgery anymore.
Treatment with silibinin, a constituent of milk thistle seeds, alleviated symptoms of Cushing Disease in cell cultures, animal models and human tumor tissue. In future, patients might not have to undergo brain surgery anymore.

Cushing Disease, not to be confused with Cushing’s Syndrome, is caused by a tumor in the pituitary gland in the brain. The tumor secrets increased amounts of the stress hormone adrenocorticotropin (ACTH) followed by cortisol release from the adrenal glands leading to rapid weight gain, elevated blood pressure and muscular weakness. Patients are prone to osteoporosis and infections and may show cognitive dysfunction or even depression. In 80 to 85 % of the patients, the tumor can be removed by uncomfortable brain surgery. For inoperable cases, there is currently only one targeted therapy approved, which unfortunately causes intense side effects such as hyperglycemia in more than 20 % of the patients.

Scientists around Günter Stalla, endocrinologist at the Max Planck Institute of Psychiatry in Munich, have now discovered in cell cultures, animal models and human tumor tissue that a harmless plant extract can be applied to treat Cushing Disease. “Silibinin is the major active constituent of milk thistle seeds. It has an outstanding safety profile in humans and is already used for the treatment of liver disease and poisoning,” explains Marcelo Paez-Pereda, leading scientist of the current study published in the renowned scientific journal Nature Medicine. After silibinin treatment, tumor cells resumed normal ACTH production, tumor growth slowed down and symptoms of Cushing Disease disappeared in mice.

In 2013, the Max Planck scientists filed a patent on a broad family of chemical and natural compounds, including silibinin, to treat pituitary tumors. Compared to humans, where only 5.5 in 100,000 people worldwide develop Cushing Disease, this condition is very common in several pets. For example, 4 % of dogs and even 7 % of horses suffer from Cushing Disease. Thus, the researchers now plan to test special formulations with a very pure substance and slow release of the active component silibinin in clinical trials.

Silibinin: Mode of action

“We knew that Cushing Disease is caused by the release of too much ACTH. So we asked ourselves what causes this over production and how to stop it,” says Paez-Pereda. In their first experiments, the researchers found tremendously high amounts of the heat shock protein 90 (HSP90) in tumor tissue from patients with Cushing Disease. In normal amounts, HSP90 helps to correctly fold another protein, the glucocorticoid receptor, which in turn inhibits the production of ACTH. “As there are too many HSP90 molecules in the tumor tissue, they stick to the glucocorticoid receptor,” explains Paez-Pereda. “We found that silibinin binds to HSP90 thus allowing glucocorticoid receptor molecules to dissolve from HSP90. With silibinin, we might have discovered a non-invasive treatment strategy not only for the rare Cushing Disease but also for other conditions with the involvement of glucocorticoid receptors, such as lung tumors, acute lymphoblastic leukemia or multiple myeloma,” concludes Paez-Pereda.

From http://www.psych.mpg.de/2034377/PM1507

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Endoscopic Pituitary Surgery – Remission Rates and Gland Preservation – Daniel F. Kelly, MD

Posted on May 31, 2015 by MaryO

2015 California Pituitary Conference

Dr. Daniel Kelly discusses the outcomes of endoscopic pituitary surgery with regards to endocrine function. He analyzes the current literature and the Pacific Brain Tumor Center’s experience with remission rates of hormone secreting tumors. He also evaluates the rate of pituitary dysfunction following pituitary tumor surgery.

Filed under: Cushing's, pituitary, Treatments, Video | Tagged: , , , , , | Leave a comment »

Cushing’s Syndrome

Posted on May 22, 2015 by MaryO
Prof André Lacroix, MDcorrespondence,  Richard A Feelders, MD, Constantine A Stratakis, MD, Lynnette K Nieman, MD
Published Online: 21 May 2015
DOI: http://dx.doi.org/10.1016/S0140-6736(14)61375-1

Summary

Chronic exposure to excess glucorticoids results in diverse manifestations of Cushing’s syndrome, including debilitating morbidities and increased mortality.

Genetic and molecular mechanisms responsible for excess cortisol secretion by primary adrenal lesions and adrenocorticotropic hormone (ACTH) secretion from corticotroph or ectopic tumours have been identified. New biochemical and imaging diagnostic approaches and progress in surgical and radiotherapy techniques have improved the management of patients.

The therapeutic goal is to normalise tissue exposure to cortisol to reverse increased morbidity and mortality. Optimum treatment consisting of selective and complete resection of the causative tumour is necessay to allow eventual normalisation of the hypothalamic-pituitary-adrenal axis, maintenance of pituitary function, and avoidance of tumour recurrence. The development of new drugs offers clinicians several choices to treat patients with residual cortisol excess.

However, for patients affected by this challenging syndrome, the long-term effects and comorbidities associated with hypercortisolism need ongoing care.

Read the entire article (there is a fee of $31.50US) here.

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