Grading system may predict recurrence, progression of pituitary neuroendocrine tumors

Posted on June 27, 2017 by MaryO

The risk for recurrence or progression of pituitary neuroendocrine tumors in adults is significantly associated with age and tumor type, according to findings published in The Journal of Clinical Endocrinology & Metabolism.

Gérald Raverot, MD, PhD, of Hospices Civils de Lyon, Federation d’Endocrinologie du Pole Est in France, and colleagues evaluated 374 adults (194 women) who underwent surgery for a pituitary neuroendocrine tumor (mean age at surgery, 51.9 years) between February 2007 and October 2012 to test the value of a new classification system on prognostic relevance.

Tumors were classified using a grading system based on invasion on MRI, immunocytochemical profile, Ki-67 mitotic index and p53 positivity. Noninvasive tumors were classified as grade 1a, noninvasive but proliferative tumors were grade 1b, invasive tumors were grade 2a, invasive and proliferative tumors were grade 2b and metastatic tumors were grade 3.

Macroadenomas were the most common type of tumor based on MRI classification (82.1%), followed by microadenoma (13.6%) and giant adenoma (4.3%).

Information on grade was available for 365 tumors; grade 1a was the most common (51.2%), followed by grades 2a (32.3%), 2b (8.8%) and 1b (7.7%).

The progression-free survival analysis included 213 participants from the original cohort during a mean follow-up of 3.5 years. A recurrent event occurred in 52 participants, and progression occurred in 37 participants. The risk for recurrence and/or progression was associated with age (P = .035), tumor type (P = .028) and grade (P < .001). The risk for recurrence and/or progression was increased with grade 2b tumors compared with grade 1a tumors (HR = 3.72; 95% CI, 1.9-7.26) regardless of tumor type. Invasion was significantly associated with recurrence in grade 2a tumors (HR = 2.98; 95% CI, 1.89-4.7), whereas proliferation was not significantly associated with prognosis for grade 1b (HR = 1.25; 95% CI, 0.73-2.13).

“This prospective study confirms the usefulness of our previously proposed classification and may now allow clinicians to adapt their therapeutic strategies according to prognosis, but may also be used to stratify patients and evaluate therapeutic efficacy in future clinical trials,” the researchers wrote. “Further progress can be expected, in particular if an improved understanding of molecular abnormalities associated with pituitary tumorigenesis generates better biomarkers.” – by Amber Cox

Disclosures: The researchers report no relevant financial disclosures.

From https://www.healio.com/endocrinology/neuroendocrinology/news/in-the-journals/%7B4dbd524c-4534-42e3-a1dc-4e3a0d82a0f1%7D/grading-system-may-predict-recurrence-progression-of-pituitary-neuroendocrine-tumors

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Cushing’s Syndrome: A Tale of Frequent Misdiagnosis

Posted on June 24, 2017 by MaryO
by Jessica Rotham, National Center for Health Research

What is it?

Cushing’s syndrome is a condition you probably have never heard of, but for those who have it, the symptoms can be quite scary.  Worse still, getting it diagnosed can take a while.  Cushing’s syndrome occurs when the tissues of the body are exposed to high levels of cortisol for an extended amount of time. Cortisol is the hormone the body produces to help you in times of stress. It is good to have cortisol at normal levels, but when those levels get too high it causes health problems.  Although cortisol is related to stress, there is no evidence that Cushing’s syndrome is directly or indirectly caused by stress.

Cushing’s syndrome is considered rare, but that may be because it is under-reported. As a result, we don’t have good estimates for how many people have it, which is why the estimates for the actual number of cases vary so much–from 5 to 28 million people.[1] The most common age group that Cushing’s affects are those 20 to 50 years old.  It is thought that obesity, type 2 diabetes, and high blood pressure may increase your risk of developing this syndrome.[2]

What causes Cushing’s Syndrome?

Cushing’s syndrome is caused by high cortisol levels. Cushing’s disease is a specific form of Cushing’s syndrome. People with Cushing’s disease have high levels of cortisol because they have a non-cancerous (benign) tumor in the pituitary gland.  The tumor releases adrenocorticotropin hormone (ACTH), which causes the adrenal glands to produce excessive cortisol.

Cushing’s syndrome that is not Cushing’s disease can be also caused by high cortisol levels that result from tumors in other parts of the body.  One of the causes is “ectopic ACTH syndrome.” This means that the hormone-releasing tumor is growing in an abnormal place, such as the lungs or elsewhere.  The tumors can be benign, but most frequently they are cancerous. Other causes of Cushing’s syndrome are benign tumors on the adrenal gland (adrenal adenomas) and less commonly, cancerous adrenal tumors (adrenocortical carcinomas). Both secrete cortisol, causing cortisol levels to get too high.

In some cases, a person can develop Cushing’s syndrome from taking steroid medications, such as prednisone. These drugs, known as corticosteroids, mimic the cortisol produced by the body. People who have Cushing’s syndrome from steroid medications do not develop a tumor.[3]

What are the signs and symptoms of Cushing’s Syndrome?

The appearance of people with Cushing’s syndrome starts to change as cortisol levels build up. Regardless of what kind of tumor they have or where the tumor is located, people tend to put on weight in the upper body and abdomen, with their arms and legs remaining thin; their face grows rounder (“moon face”); they develop fat around the neck; and purple or pink stretch marks appear on the abdomen, thighs, buttocks or arms. Individuals with the syndrome usually experience one or more of the following symptoms: fatigue, muscle weakness, high glucose levels, anxiety, depression, and high blood pressure. Women are more likely than men to develop Cushing’s syndrome, and when they do they may have excess hair growth, irregular or absent periods, and decreased fertility.[4]

Why is Cushing’s Syndrome so frequently misdiagnosed?

These symptoms seem distinctive, yet it is often difficult for those with Cushing’s syndrome to get an accurate diagnosis.  Why?  While Cushing’s is relatively rare, the signs and symptoms are common to many other diseases. For instance, females with excess hair growth, irregular or absent periods, decreased fertility, and high glucose levels could have polycystic ovarian syndrome, a disease that affects many more women than Cushing’s.   Also, people with metabolism problems (metabolic syndrome), who are at higher than average risk for diabetes and heart disease, also tend to have abdominal fat, high glucose levels and high blood pressure.[5]

Problems in testing for Cushing’s

When Cushing’s syndrome is suspected, a test is given to measure cortisol in the urine. This test measures the amount of free or unbound cortisol filtered by the kidneys and then released over a 24 hour period through the urine. Since the amount of urinary free cortisol (UFC) can vary a lot from one test to another—even in people who don’t have Cushing’s—experts recommend that the test be repeated 3 times. A diagnosis of Cushing’s is given when a person’s UFC level is 4 times the upper limit of normal.  One study found this test to be highly accurate, with a sensitivity of 95% (meaning that 95% of people who have the disease will be correctly diagnosed by this test) and a specificity of 98% (meaning that 98% of  people who do not have the disease will have a test score confirming that).[6] However, a more recent study estimated the sensitivity as only between 45%-71%, but with 100% specificity.[7]  This means that the test is very accurate at telling people who don’t have Cushing’s that they don’t have it, but not so good at identifying the people who really do have Cushing’s.  The authors that have analyzed these studies advise that patients use the UFC test together with other tests to confirm the diagnosis, but not as the initial screening test.[8]  

Other common tests that may be used to diagnose Cushing’s syndrome are: 1) the midnight plasma cortisol and late-night salivary cortisol measurements, and 2) the low-dose dexamethasone suppression test (LDDST).  The first test measures the amount of cortisol levels in the blood and saliva at night.  For most people, their cortisol levels drop at night, but people with Cushing’s syndrome have cortisol levels that remain high all night. In the LDDST, dexamethasone is given to stop the production of ACTH.  Since ACTH produces cortisol, people who don’t have Cushing’s syndrome will get lower cortisol levels in the blood and urine. If after giving dexamethasone, the person’s cortisol levels remain high, then they are diagnosed with Cushing’s.[9]

Even when these tests, alone or in combination, are used to diagnose Cushing’s, they don’t explain the cause. They also don’t distinguish between Cushing’s syndrome, and something called pseudo-Cushing state.

Pseudo-Cushing state

Some people have an abnormal amount of cortisol that is caused by something unrelated to Cushing’s syndrome such as polycystic ovarian syndrome, depression, pregnancy, and obesity. This is called pseudo-Cushing state.  Their high levels of cortisol and resulting Cushing-like symptoms can be reversed by treating whatever disease is causing the abnormal cortisol levels. In their study, Dr. Giacomo Tirabassi and colleagues recommend using the desmopressin (DDAVP) test to differentiate between pseudo-Cushing state and Cushing’s.  The DDAVP test is especially helpful in people who, after being given dexamethasone to stop cortisol production, continue to have moderate levels of urinary free cortisol (UFC) and midnight serum cortisol.[10]

An additional test that is often used to determine if one has pseudo-Cushing state or Cushing’s syndrome is the dexamethasone-corticotropin-releasing hormone (CRH) test. Patients are injected with a hormone that causes cortisol to be produced while also being given another hormone to stop cortisol from being produced. This combination of hormones should make the patient have low cortisol levels, and this is what happens in people with pseudo-Cushing state.  People with Cushing’s syndrome, however, will still have high levels of cortisol after being given this combination of hormones.[11]

How can Cushing’s be treated?

Perhaps because Cushing’s is rare or under-diagnosed, few treatments are available. There are several medications that are typically the first line of treatment.  None of the medications can cure  Cushing’s, so they are usually taken until other treatments are given to cure Cushing’s, and only after that if the other treatment fails.

The most common treatment for Cushing’s disease is transsphenoidal surgery, which requires the surgeon to reach the pituitary gland through the nostril or upper lip and remove the tumor.  Radiation may also be used instead of surgery to shrink the tumor.  In patients whose Cushing’s is caused by ectopic ACTH syndrome, all cancerous cells need to be wiped out through surgery, chemotherapy, radiation or a variety of other methods, depending on the location of the tumor. Surgery is also recommended for adrenal tumors.  If Cushing’s syndrome is being caused by corticosteroid (steroid medications) usage, the treatment is to stop or lower your dosage.[12]

Medications to control Cushing’s (before treatment or if treatment fails)

According to a 2014 study in the Journal of Clinical Endocrinology and Metabolism, almost no new treatment options have been introduced in the last decade. Researchers and doctors have focused most of their efforts on improving existing treatments aimed at curing Cushing’s. Unfortunately, medications used to control Cushing’s prior to treatment and when treatment fails are not very effective.

Many of the medications approved by the FDA for Cushing’s syndrome and Cushing’s disease, such as pasireotide, metyrapone, and mitotane, have not been extensively studied.  The research presented to the FDA by the makers of these three drugs did not even make clear what an optimal dose was.[13] In another 2014 study, published in Clinical Epidemiology, researchers examined these three same drugs, along with ten others, and found that only pasireotide had moderate evidence to support its approval.  The other drugs, many of which are not FDA approved for Cushing’s patients, had little or no available evidence to show that they work.[14] They can be sold, however, because the FDA has approved them for other diseases.  Unfortunately, that means that neither the FDA nor anyone else has proven the drugs are safe or effective for Cushing patients.

Pasireotide, the one medication with moderate evidence supporting its approval, caused hyperglycemia (high blood sugar) in 75% of patients who participated in the main study for the medication’s approval for Cushing’s.  As a result of developing hyperglycemia, almost half (46%) of the participants had to go on blood-sugar lowering medications. The drug was approved by the FDA for Cushing’s anyway because of the lack of other effective treatments.

Other treatments used for Cushing’s have other risks.  Ketoconazole, believed to be the most commonly prescribed medications for Cushing’s syndrome, has a black box warning due to its effect on the liver that can lead to a liver transplant or death.  Other side effects include: headache, nausea, irregular periods, impotence, and decreased libido. Metyrapone can cause acne, hirsutism, and hypertension. Mitotane can cause neurological and gastrointestinal symptoms such as dizziness, nausea, and diarrhea and can cause an abortion in pregnant women.[15]

So, what should you do if you suspect you have Cushing’s Syndrome?

Cushing’s syndrome is a serious disease that needs to be treated, but there are treatment options available for you if you are diagnosed with the disease. If the symptoms in this article sound familiar, it’s time for you to go see your doctor. Make an appointment with your general practitioner, and explain your symptoms to him or her.  You will most likely be referred to an endocrinologist, who will be able to better understand your symptoms and recommend an appropriate course of action.

 

All articles are reviewed and approved by Dr. Diana Zuckerman and other senior staff.

  1. Nieman, Lynette K. Epidemiology and clinical manifestations of Cushing’s syndrome, 2014. UpToDate: Wolters Kluwer Health
  2. Cushing’s syndrome/ disease, 2013. American Association of Neurological Surgeons. http://www.aans.org/Patient%20Information/Conditions%20and%20Treatments/Cushings%20Disease.aspx
  3. Cushing’s syndrome, 2012. National Endocrine and Metabolic Diseases: National Institutes of Health. http://endocrine.niddk.nih.gov/pubs/cushings/cushings.aspx#treatment
  4. Cushing’s syndrome, 2012. National Endocrine and Metabolic Diseases: National Institutes of Health. http://endocrine.niddk.nih.gov/pubs/cushings/cushings.aspx#treatment
  5. Cushing’s syndrome, 2012. National Endocrine and Metabolic Diseases: National Institutes of Health. http://endocrine.niddk.nih.gov/pubs/cushings/cushings.aspx#treatment
  6. Newell-Price, John, Peter Trainer, Michael Besser and Ashley Grossman. The diagnosis and differential diagnosis of Cushing’s syndrome and pseudo-Cushing’s states, 1998. Endocrine Reviews: Endocrine Society
  7. Carroll, TB and JW Findling. The diagnosis of Cushing’s syndrome, 2010. Reviews in Endocrinology and Metabolic Disorders: Springer
  8. Ifedayo, AO and AF Olufemi. Urinary free cortisol in the diagnosis of Cushing’s syndrome: How useful?, 2013. Nigerian Journal of Clinical Practice: Medknow.
  9. Cushing’s syndrome, 2012. National Endocrine and Metabolic Diseases: National Institutes of Health. http://endocrine.niddk.nih.gov/pubs/cushings/cushings.aspx#treatment
  10. Tirabassi, Giacomo, Emanuela Faloia, Roberta Papa, Giorgio Furlani, Marco Boscaro, and Giorgio Arnaldi. Use of the Desmopressin test in the differential diagnosis of pseudo-Cushing state from Cushing’s disease, 2013. The Journal of Clinical Endocrinology & Metabolism: Endocrine Society.
  11. Cushing’s syndrome, 2012. National Endocrine and Metabolic Diseases: National Institutes of Health. http://endocrine.niddk.nih.gov/pubs/cushings/cushings.aspx#treatment
  12. Cushing’s syndrome, 2012. National Endocrine and Metabolic Diseases: National Institutes of Health. http://endocrine.niddk.nih.gov/pubs/cushings/cushings.aspx#treatment
  13. Tirabassi, Giacomo, Emanuela Faloia, Roberta Papa, Giorgio Furlani, Marco Boscaro, and Giorgio Arnaldi. Use of the Desmopressin test in the differential diagnosis of pseudo-Cushing state from Cushing’s disease, 2013. The Journal of Clinical Endocrinology & Metabolism: Endocrine Society.
  14. Galdelha, Monica R. and Leonardo Vieira Neto. Efficacy of medical treatment in Cushing’s disease: a systematic review, 2014. Clinical Endocrinology: John Wiley & Sons.
  15. Adler, Gail. Cushing syndrome treatment & management, 2014. MedScape: WebMD.

Adapted from https://www.center4research.org/cushings-syndrome-frequent-misdiagnosis/

Filed under: adrenal, Cushing's, Diagnostic Testing, pituitary, Rare Diseases | Tagged: , , , , , , , , , , , , | Leave a comment »

Anomalous Response to Metyrapone in Cushing’s Syndrome Due to Adrenocortical Adenoma

Posted on June 11, 2017 by MaryO

L. F. PENNINGTON

R. A. KREISBERG
J. M. HERSHMAN
J Clin Endocrinol Metab (1970) 30 (1): 125-127.
DOI:
https://doi.org/10.1210/jcem-30-1-125

From https://academic.oup.com/jcem/article-abstract/30/1/125/2716035/Anomalous-Response-to-Metyrapone-in-Cushings

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Study links genetic mutations, Cushing syndrome

Posted on June 6, 2017 by MaryO

Researchers have determined mutations in the gene CABLES1 may lead to Cushing syndrome, a rare disorder in which the body overproduces the stress hormone cortisol.

The National Institutes of Health study findings published in Endocrine-Related Cancer found four of the 181 children and adult patient examined had mutant forms of CABLES1 that do not respond to cortisol.

The determination proved significant because normal functioning CABLES1 protein, expressed by the CABLES1 gene, slows the division and growth of pituitary cells that produce the hormone adrenocorticotropin (ACTH).

Researchers at the NIH’s Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD) joined scientists from other institutions in the United States, France and Canada, in the evaluation.

“The mutations we identified impair the tumor suppressor function in the pituitary gland,” Constantine A. Stratakis, the study’s senior author and director of the NICHD Division of Intramural Research, said. “This discovery could lead to the development of treatment strategies that simulate the function of the CABLES1 protein and prevent recurrence of pituitary tumors in people with Cushing syndrome.”

Cushing syndrome symptoms include obesity, muscle weakness, fatigue, high blood pressure, high blood sugar, depression and anxiety, officials said, adding excess cortisol found in the disorder can result from certain steroid medications or from tumors of the pituitary or adrenal glands.

Researchers maintain that more studies are needed to fully understand how CABLES1 suppresses tumor formation in the pituitary gland.

 

From https://lifesciencedaily.com/stories/21624-study-links-genetic-mutations-cushing-syndrome/

Filed under: Clinical trials, Cushing's, pituitary | Tagged: , , , , , , , , , , , , , , | Leave a comment »

Cataloging Cushing’s Patients

Posted on June 3, 2017 by MaryO

The Cushing/Whitney Medical Library is pleased to announce the completion of a grant funded to catalog 2,600 glass plate negatives from the Cushing Brain Tumor Registry.  The grant proposal, “Rethinking Early Neurosurgery: The Harvey Cushing Collection,” was funded through a National Network of Libraries of Medicine-New England Region Knowledge/Data Management Award.  From mid-February through April 30th 2017,  a team of graduate and undergraduate students carefully inputted information on over 3,000 glass plate negatives into the Cushing Center database, exceeding the estimated amount in the grant. The negatives depict Dr. Harvey Cushing’s patients, including histology.

Harvey Cushing, the pioneer and father of neurosurgery, was born on April 8, 1869 in Cleveland, Ohio. He graduated from Yale University in 1891, studied medicine at Harvard Medical School and received his medical degree in 1895. In 1896, he moved to Johns Hopkins Hospital where he trained to become a surgeon under the watchful eye of William S. Halstead, the father of American surgery. By 1899 Cushing became interested in surgery of the nervous system and began his career in neurosurgery. During his tenure at Johns Hopkins, there were countless discoveries in the field of neuroscience.

In 1913, Cushing relocated to Harvard as the surgeon-in-chief at the new Peter Bent Brigham Hospital. Cushing continued to operate on several hundred patients a year with remarkable results.  In addition he was relentless in his recording of patient histories and continued his careful attention to the details and documentation of each surgery.

In 1932 Harvey Cushing retired and in 1933 he agreed to join the staff at Yale University, his alma mater, as the Sterling Professor of Medicine in Neurology.  Cushing died in 1939.

The negatives are undergoing rehousing and digitization, and will be made available for research through the Cushing Center database, which brings multiple parts of Harvey Cushing’s work together in one place.  The database, still in development, will allow researchers to explore Cushing’s medical work and patients.  Please contact Terry Dagradi, Cushing Center Coordinator, for details.

 

From http://library.medicine.yale.edu/blog/cushing-center/cataloging-cushings-patients

Filed under: Cushing, Cushing's, Helpful Doctors, pituitary | Tagged: , , , , , | Leave a comment »

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