Mild Cases of Cushing’s Syndrome Present Diagnostic Challenges

By Tori Rodriguez, MA, LPC

 

In the early 20th century, the term “pluriglandular syndrome” was coined by Harvey Cushing to describe the disorder that results from chronic tissue exposure to excessive levels of glucocorticoids.1 Now called Cushing’s syndrome, the condition affects an estimated 10-15 million people annually, most often women and individuals between the ages of 20 and 50 years.2 Risk factors and common comorbidities include hypertension, obesity, osteoporosis, uncontrolled diabetes, depression, and anxiety.3

Presentation

The clinical presentation of the disorder is heterogenous and varies by sex, age, and disease severity. Common signs and symptoms include central adiposity, roundness of the face or extra fat around the neck, thin skin, impaired short-term memory and concentration, irritability, hirsutism in women, fatigue, and menstrual irregularity.4 Because each of these features may be observed in a wide range of other conditions, it may be difficult to diagnose cases that are not severe.

“It can be challenging to differentiate the milder forms from pseudo-Cushing’s states,” which are characterized by altered cortisol production and many of the same clinical features as Cushing’s syndrome, according to Roberto Salvatori, MD, the medical director of the Johns Hopkins Pituitary Center, Baltimore, Maryland. These may include alcoholism, obesity, eating disorders, and depression. “Because Cushing’s can cause depression, for example, it is sometimes difficult to determine which came first,” he says. In these states, however, hypercortisolism is believed to be driven by increased secretion of hypothalamic corticotropin-releasing hormone, which is suppressed in Cushing’s syndrome.5

Causes and Diagnosis

If Cushing’s syndrome is suspected on the basis of the patient’s physical appearance, the diagnostic workup should include a thorough medical history, physical exam, and 1 or more of the following tests to establish hypercortisolism: the 24-hour urinary cortisol test, the low-dose dexamethasone suppression test, or the late-night salivary cortisol test. “We sometimes use 2 or 3 of these tests since 1 may not accurately reflect cortisol production in a particular patient,” Dr Salvatori notes. The next step is to determine the source of the hypercortisolism, which may involve the high-dose dexamethasone suppression test, magnetic resonance imaging, or petrosal sinus sampling.2

Medication is the most common cause of Cushing’s syndrome. These iatrogenic or exogenous cases typically result from corticosteroids administered for conditions such as asthma, allergies, and autoimmune disorders.6 More rarely, the disorder can be caused by the use of medroxyprogesterone. In these cases, corticosteroids should be reduced or discontinued under medical care, if possible.

Endogenous Cushing’s syndrome results from the presence of benign or malignant tumors on the adrenal or pituitary glands or elsewhere in the body. These tumors can interfere with the adrenal glands’ production of cortisol that is usually prompted by the adrenocorticotropic hormone (ACTH) released by the pituitary gland.6 There are 3 different mechanisms by which the process can occur.

  • Pituitary adenomas, which account for approximately 70% of endogenous cases of Cushing’s syndrome, secrete ACTH and stimulate additional cortisol production. Because of the large proportion of cases this condition represents, it is specifically referred to as Cushing’s disease. It is more common in women than men (with a ratio of 3 to 4:1), although in pediatric patients, it occurs more frequently in boys vs girls.5
  • Adrenal tumors (adenomas, malignant tumors, or micronodular hyperplasia) produce cortisol in their own tissue in addition to the amount produced by the adrenal glands. These tumors, which cause approximately 15% of endogenous Cushing’s syndrome cases, are more common in children vs adults and in women vs men.
  • Benign or malignant tumors elsewhere in the body, most often the lungs, thyroid, thymus, and pancreas, secrete ACTH and trigger the excessive release of cortisol. An estimated 15% of endogenous cases are attributed to these types of tumors.

Treatment

Surgery is the first-line treatment for Cushing’s syndrome. “We first want to try to figure out the cause of the disorder,” Dr Salvatori says. “Ideally, treatment involves surgery to remove the tumor that is causing it.”

When surgery is unsuccessful, contraindicated, or delayed, other treatment options include radiation or medications that inhibit cortisol, modulate the release of ACTH, or inhibit steroidogenesis.5 Bilateral adrenalectomy may be indicated for patients who do not respond to medication or other surgery.

If surgical resection of the tumor is successful, then “all of the comorbidities reverse, but if it is unsuccessful or must be delayed, you would treat each comorbidity” with the appropriate medication; for example, antihypertensives for high blood pressure and antidiabetic medications for diabetes, Dr Salvatori advises. In severe cases, prophylactic antibiotics may be indicated for the prevention of severe infections such as pneumonia.

It is also important to inquire about and address psychiatric symptoms related to Cushing’s syndrome, even in patients who are in remission. It has been proposed that the chronic hypercortisolism and dysfunction of the HPA axis may “lead to structural and functional changes in the central nervous system, developing brain atrophy, particularly in the hippocampus, which may determine the high prevalence of psychiatric disorders, such as affective and anxiety disorders or cognitive dysfunctions,” according to a recently published paper on the topic.7 Patients should be screened with self-report questionnaires such as the Beck Depression Inventory and the Hospital Anxiety and Depression Scale, and management of psychiatric symptoms may include patient education, psychotropic medications, and referral to a mental health professional.

Future Directions

Several trials are currently planned or underway, including a phase 2 randomized, double-blind, placebo-controlled study of an oral medication called ATR-101 by Millendo Therapeutics, Inc. (ClinicalTrials.gov identifier: NCT03053271). In addition to the need for novel medical therapies, refined imaging techniques could improve surgical success rates in patients with Cushing’s disease in particular, according to Dr Salvatori. “A significant portion of these patients have tumors too small to be detected by MRI, and the development of more sensitive MRI could improve detection and provide a surgical target” for neurosurgeons treating the patients, he says.

Summary

Milder cases of Cushing’s syndrome present diagnostic challenges are a result overlapping features with various other conditions. Diagnosis may require careful observation as well as biochemical and imaging tests.

References

  1. Loriaux DL. Diagnosis and differential diagnosis of Cushing’s syndromeN Engl J Med. 2017;376:1451-1459. doi:10.1056/NEJMra1505550
  2. American Association of Neurological Surgeons. Cushing’s syndrome/disease. http://www.aans.org/Patients/Neurosurgical-Conditions-and-Treatments/Cushings-Disease. Accessed August 1, 2017.
  3. León-Justel A, Madrazo-Atutxa A, Alvarez-Rios AI, et al. A probabilistic model for cushing’s syndrome screening in at-risk populations: a prospective multicenter studyJ Clin Endocrinol Metab. 2016;101:3747-3754. doi:10.1210/jc.2016-1673
  4. The Pituitary Society. Cushing’s syndrome and disease–symptoms. https://pituitarysociety.org/patient-education/pituitary-disorders/cushings/symptoms-of-cushings-disease-and-cushings-syndrome. Accessed August 1, 2017.
  5. Sharma ST, Nieman LK, Feelders RA. Cushing’s syndrome: epidemiology and developments in disease managementClin Epidemiol. 2015;7:281-293. doi:10.2147/CLEP.S44336
  6. National Institutes of Health: Eunice Kennedy Shriver National Institute of Child Health and Human Development. What causes Cushing’s syndrome?https://www.nichd.nih.gov/health/topics/cushing/conditioninfo/pages/causes.aspx. Accessed August 1, 2017.
  7. Santos A, Resmini E, Pascual JC, Crespo I, Webb SM. Psychiatric symptoms in patients with Cushing’s syndrome: prevalence, diagnosis and management. Drugs. 2017;77:829-842. doi:10.1007/s40265-017-0735-z

From http://www.endocrinologyadvisor.com/adrenal/cushings-syndrome-diagnosis-treatment/article/682302/

Adrenal myelolipoma(s) as presenting manifestation of subclinical Cushing’s disease (eutopic ACTH-dependent Cushing’s syndrome)

  1. Partha Pratim Chakraborty1,
  2. Shinjan Patra1,
  3. Sugata Narayan Biswas1,
  4. Rana Bhattacharjee2

+Author Affiliations


  1. 1Department of MedicineMidnapore Medical College and HospitalMidnaporeWest Bengal, India

  2. 2Department of Endocrinology and MetabolismIPGME&R/SSKM HospitalKolkataWest Bengal, India
  1. Correspondence to Dr Partha Pratim Chakraborty, docparthapc@yahoo.co.in
  • Accepted 5 August 2017
  • Published 16 August 2017

Summary

Primary adrenal myelolipomas, relatively rare benign tumours of the adrenal cortex are typically unilateral, hormonally inactive and asymptomatic, hence often diagnosed as ‘adrenal incidentaloma’. Bilateral adrenal myelolipomas, in particular, may be associated with underlying endocrinopathies associated with elevated circulating adrenocorticotropic hormone (ACTH) concentration.

Subclinical cortisol hypersecretion, irrespective of its ACTH dependency, does not manifest typical clinical phenotype of hypercortisolemia, and thus termed subclinical Cushing’s syndrome.

In this article, hormonal evaluation in a middle-aged woman with diabetes, hypertension and incidentally discovered unilateral adrenal myelolipoma revealed underlying subclinical Cushing’s disease. Abdominal CT revealed another tiny focus in the contralateral adrenal gland, probably representing incipient myelolipoma.

From (you may buy the whole article at this link) http://casereports.bmj.com/content/2017/bcr-2017-221674.short?rss=1

Growth Hormone: Drug companies are growing less generous in helping patients pay for meds

For 14 years, Encino resident Ed Wright received an expensive prescription medication for free through a drug-industry program intended to assist people with limited or fixed incomes.

Now he’s rationing his doses after a change to the program that imposed a $1,100 deductible before he can get a refill.

“I can’t afford that,” Wright, 75, told me. “When I run out in a few weeks, that’s going to be it.”

He isn’t alone. Industry watchers say soaring drug prices have prompted many pharmaceutical companies to rethink long-standing programs to help subsidize purchases or even give meds away for free.

“More and more people have become aware of these programs, and demand has gone up,” said David P. Wilson, president of PRAM Insurance Services, a Brea firm that helps employers with prescription-drug benefits.

This means trouble for patients who, like Wright, can’t handle sticker shock at the drugstore.

He suffered a head injury 17 years ago that damaged his pituitary gland. In 2003, he was diagnosed as having an abnormally low level of growth hormone, which caused him to suddenly become overwhelmed with fatigue.

That’s a potentially life-threatening condition if an episode should occur while driving, walking down stairs or performing some other physical activity.

Wright’s doctor prescribed the self-injected human growth hormone Humatrope, manufactured by Eli Lilly & Co.

The cost, however, was out of reach for Wright, even with Medicare Part D. According to the drug-pricing website GoodRX, a 6-milligram cartridge of Humatrope — a one month’s supply — runs about $700.

Luckily, Wright’s fixed income made him eligible for a program called Lilly Cares, which made the drug available free of charge. He and his doctor would renew the paperwork annually, and for 14 years Wright had no difficulty receiving the med.

That’s no longer the case with the new $1,100 deductible, which requires Wright to spend that amount on prescription drugs before he can access his free Humatrope.

Wright requires few other drugs, so the deductible is an almost insurmountable barrier to maintaining normal quality of life.

Most drugmakers offer what are known as patient assistance programs, through which the company may provide meds directly to patients at little or no cost. Or the company may assist with co-payments — the patient’s out-of-pocket expense that’s not covered by an insurer.

2009 study published in the journal Health Affairs found that most patient assistance programs run by drug companies were reluctant to disclose details of the number of people they serve or the program’s eligibility requirements.

These programs “exist to provide patients with access to a wide variety of medications,” researchers concluded. However, “many details about these programs remain unclear. As a result, the extent to which these programs provide a safety net to patients is poorly understood.”

Aaron Tidball, chief Medicare advisor for the Illinois consulting firm Allsup, which assists individuals and businesses in navigating the public insurance system, said Lilly Cares “has been more generous than some programs we’ve seen.”

He said that, until now, people who qualified for Lilly’s assistance were able to receive whatever specialty meds that were prescribed by their doctor without cost or co-pay.

It should be noted, though, that Lilly has structured its program so the company benefits as well. Rather than provide drugs directly to patients, as many companies do, Lilly donates its medications to a private foundation, the Lilly Cares Foundation, which in turn deals with the public.

This allows Lilly to deduct the value of its donated drugs from its taxes. According to the nonprofit foundation’s 2015 tax return, which by law must be made public, the Lilly Cares Foundation received more than $408 million worth of drugs from the company. That figure represented the “fair market value” of the meds.

“That’s obviously a lot more than the cost to produce the drugs,” observed Jeff Geida, a Los Angeles estate lawyer who specializes in nonprofit foundations and who examined the most recent Lilly Cares tax return at my request.

In other words, Lilly was able to reduce its taxable income for the year by $408 million, although the actual expense of manufacturing the donated drugs almost certainly was just a fraction of the deducted amount.

“It’s a very good deal,” Geida said.

To be sure, the company is still doing enormous good by making millions of dollars worth of drugs available to people in need. But the inflated figures highlight the lack of transparency surrounding the true cost of prescription meds.

Julie Williams, a Lilly spokeswoman, declined to answer my questions about the Lilly Cares Foundation. But she forwarded a statement from Steven Stapleton, the foundation’s president.

He said the foundation imposed the $1,100 deductible for Medicare Part D beneficiaries “after benchmarking our program with other similar programs, helping Lilly Cares to balance all the criteria for the program and to try to help as many people as possible.”

That’s just gibberish to my ear — and doesn’t address the fact that Lilly still helps itself to that whopping tax deduction while making it considerably harder for low-income people to receive assistance.

I called the foundation and spoke with a service rep, but she said she didn’t know why the deductible was put in place. Nor could she explain how it’s in the best interest of patients with limited incomes to have to spend $1,100 on drugs before being eligible to receive a needed medicine.

Stapleton said notifications were sent to program participants in the fall of 2015 and 2016, but Wright told me he couldn’t recall receiving any such notice. The office manager of his doctor’s practice said she too was caught by surprise.

Lilly Cares made the situation even more inexplicable when it sent a notice to Wright last month formally dropping him from the program. The only reason it gave was “inactivity,” which made no sense considering that he’s been using Humatrope steadily for 14 years.

Williams, the Lilly spokeswoman, said she couldn’t discuss an individual patient.

Wright told me that, after I started poking around, he received a call from a Lilly representative. She advised him to contact the Partnership for Prescription Assistance, an industry-sponsored service intended to help people find subsidy programs that can help cover the high cost of their meds.

Wright contacted four subsidy programs through the service. Each one turned him down.

Lilly says it’s balancing all the criteria for Lilly Cares, which undoubtedly will make the company more profitable.

Wright, and the many other patients in similar positions, are a secondary consideration.

From http://www.latimes.com/business/lazarus/la-fi-lazarus-prescription-drug-assistance-20170815-story.html

The burden of Cushing’s disease: clinical and health-related quality of life aspects


Thanks to Robin Ess for the easy to read chart!

Abstract

Objective Cushing’s disease (CD) is a rare endocrine disorder characterized by excess secretion of ACTH due to a pituitary adenoma. Current treatment options are limited and may pose additional risks. A literature review was conducted to assess the holistic burden of CD.

Design Studies published in English were evaluated to address questions regarding the epidemiology of CD, time to diagnosis, health-related quality of life (HRQoL), treatment outcomes, mortality, prevalence of comorbidities at diagnosis, and reversibility of comorbidities following the treatment.

Methods A two-stage literature search was performed in Medline, EMBASE, and Science Citation Index, using keywords related to the epidemiology, treatment, and outcomes of CD: i) articles published from 2000 to 2012 were identified and ii) an additional hand search (all years) was conducted on the basis of bibliography of identified articles.

Results At the time of diagnosis, 58–85% of patients have hypertension, 32–41% are obese, 20–47% have diabetes mellitus, 50–81% have major depression, 31–50% have osteoporosis, and 38–71% have dyslipidemia. Remission rates following transsphenoidal surgery (TSS) are high when performed by expert pituitary surgeons (rates of 65–90%), but the potential for relapse remains (rates of 5–36%). Although some complications can be partially reversed, time to reversal can take years. The HRQoL of patients with CD also remains severely compromised after remission.

Conclusions These findings highlight the significant burden associated with CD. As current treatment options may not fully reverse the burden of chronic hypercortisolism, there is a need for both improved diagnostic tools to reduce the time to diagnosis and effective therapy, particularly a targeted medical therapy.

Introduction

Cushing’s disease (CD) is a rare condition caused by a pituitary adenoma that secretes excess ACTH (1), which promotes excess cortisol production from the adrenal glands. Excess cortisol induces a clinical phenotype that harbors all components of the metabolic syndrome, such as central obesity, diabetes mellitus, dyslipidemia, and hypertension, as well as muscle weakness, hirsutism, increased bruisability, psychological dysfunction, and osteoporosis (1234567891011).

Patients with CD experience a significant clinical burden due to comorbidities, increased mortality, and impaired health-related quality of life (HRQoL) due to prolonged exposure to elevated cortisol levels (3511121314151617181920). In particular, patients with CD often experience severe fatigue and weakness, physical changes, emotional instability, depression, and cognitive impairments, which have a profound impact on daily life (1321).

Although there have been several consensus statements published recently on the definition of remission, diagnosis, and the management of CD, the severity and diversity of the clinical scenario and associated morbidities continue to present a management challenge (12223). Additionally, there is recent evidence of persistent deleterious effects after remission, most notably persistent elevated cardiovascular risk (322). The main objective of the current literature review is to describe the current burden of the disease and to summarize data on specific aspects of this burden, which underscores the need for improved diagnostic and therapeutic approaches.

Materials and methods

Available literature were evaluated to address questions regarding the epidemiology of CD, time to diagnosis, mortality, prevalence of comorbidities at diagnosis, reversibility of comorbidities after treatment (in particular, after disease remission), outcomes and complications of current treatment options, and HRQoL associated with CD and interventions.

The literature search was performed in Medline, EMBASE, and Science Citation Index, using keywords related to the epidemiology, treatment, and outcomes of CD. It was conducted in two stages: i) articles published between 2000 and 2012 were identified through a PubMed search using the following keywords: CD, incidence, prevalence, mortality, treatment, remission, cure, excess cortisol, outcomes, cost, QoL, morbidities, transsphenoidal surgery (TSS), adrenalectomy, radiotherapy, steroidogenesis inhibitors, ketoconazole, mitotane, aminoglutethimide, etomidate, metyrapone, pasireotide, and cortisol receptor antagonists; and ii) an additional hand search was conducted on the basis of the bibliographies of identified articles. All studies that provided data (regardless of publication year) related to these research questions were retained.

Definitions

Different criteria for defining the remission of hypercortisolism have been proposed, ranging from the occurrence of definitive or transient postoperative hypocortisolemia to the adequate suppression of cortisol after dexamethasone administration. According to a recent consensus statement (23), persistent postoperative morning serum cortisol levels of <2 μg/dl (∼50 nmol/l) are associated with remission and a low recurrence rate of ∼10% at 10 years. Persistent serum cortisol levels above 5 μg/dl (∼140 nmol/l) for up to 6 weeks following surgery require further evaluation. When serum cortisol levels are between 2 and 5 μg/dl, the patient can be considered in remission and can be observed without additional treatment for CD. A subset of patients can even develop complete adrenal insufficiency (serum cortisol levels below 2 μg/dl (∼50 nmol/l)) up to 12 weeks postsurgery (2425). Therefore, repeated evaluation in the early postoperative period is recommended. However, long-term follow-up is necessary for all patients because no single cortisol cutoff value excludes those who later experience disease recurrence, and up to 25% of patients develop a recurrent adenoma within 10 years after surgery (262728).

Results

Incidence and prevalence of CD

Although epidemiologic data on CD are limited, several population-based studies indicate an incidence of 1.2–2.4 per million (1419) and the prevalence of diagnosed cases to be ∼39 per million population (14). Lindholm et al(19) used the case definition as either the presence of a corticotroph adenoma or remission after neurosurgery, which yielded an estimated incidence rate of 1.2–1.7 per million per year. Etxabe & Vazquez (14) reported an incidence of 2.4 per million in Vizcaya, Spain. A large-scale retrospective survey carried out in New Zealand by Bolland et al(29) found the approximate prevalence of all forms of Cushing’s syndrome (CS) (the majority of these cases were of pituitary origin) to be 79 per million and the incidence to be 1.8 per million per year. Differences in epidemiologic estimates may be attributable to varying case definitions (for instance, the study by Lindholm excluded cases in which the adenoma could not be localized or those that could not achieve remission from surgery), geographical differences, and temporal effects. The prevalence of CD may be underestimated due to unrecognized patients with mild symptoms and patients with a cyclic form of CD (30).

Time to diagnosis

Data on the time from onset of symptoms to diagnosis are also limited. In a prospective study by Flitsch et al(31) of 48 patients with pituitary adenomas, including 19 who had ACTH-secreting adenomas causing CD, the reported time from onset of symptoms to diagnosis was 4.3 years. A study by Martinez Ruiz et al(32), which was based on only four pediatric CD patients, reported the time between onset of symptoms and diagnosis as ranging from 2.5 to 5 years. Etxabe & Vazquez (14) estimated that the average time from onset of clinical symptoms to diagnosis in 49 CD patients was 45.8±2.7 months (6–144 months), thus 3.8 years. This is corroborated by the findings from a Belgian cross-sectional study on pituitary adenomas including CD, which estimated that patients experienced symptoms for an average of 45 months before diagnosis (33). However, the reliability and generalizability of these data are limited by small sample sizes and the retrospective nature of the studies. Indeed, the New Zealand data from Bolland et al(29) report that on presentation, patients experienced symptoms for a median of 2.0 years (but ranging up to 20 years) before diagnosis. On the basis of data from the prospective European Registry on Cushing’s syndrome (ERCUSYN) (total number of patients=481, of whom 66% of patients had CD), median delay in diagnosis was 2 years (34).

Mortality in patients with CD

Mortality in patients with CD has been analyzed in several small studies, with overall rates reported as standardized mortality ratio (SMR) ranging from 1.7 to 4.8 (Table 1) (14151719). In studies in which mortality was assessed among those in remission and those with persistent disease separately, patients with persistent hypercortisolemia consistently had the highest mortality risk (15193536). In addition, TSS as a first-line treatment has been an important advance as high remission rates after initial surgery have been accompanied by mortality rates that mirror those observed in the general population (173537). In a case series from the UK, it was found that the majority of deaths occurred before 1985, which was before TSS was employed as the routine first-line treatment at the center (36). In a recent retrospective study, 80 patients undergoing TSS for CD between 1988 and 2009 were evaluated, and long-term cure (defined as ongoing absence of hypercortisolism at last follow-up) was reported in 72% of patients. However, overall elevated mortality persisted in patients (SMR 3.17 (95% CI: 1.70–5.43)), including those who achieved ‘cure’ (SMR 2.47 (95% CI: 0.80–5.77)), although even higher mortality was seen in those with postoperative recurrence/persistent disease (SMR 4.12 (95% CI: 1.12–10.54) (38). Additionally, a nationwide, retrospective study in New Zealand reported significant persistently increased mortality both in macro- and microadenomas (SMR 3.5 (1.3–7.8) and 3.2 (2.0–4.8) respectively), despite long-term biochemical remission rates of 93 and 91% of patients, respectively (29).

Read more at http://m.eje-online.org/content/167/3/311.full

An unusual case of Cushing’s syndrome due to bihormonal ACTH–prolactin secreting pituitary macroadenoma with rapid response to cabergoline

  1. Shalini Kunasegaran1,2,
  2. Michael S Croxson1,
  3. Ian Holdaway1,
  4. Rinki Murphy1

+Author Affiliations


  1. 1Department of EndocrinologyAuckland District Health BoardAuckland, New Zealand

  2. 2Department of EndocrinologyWaitemata District Health BoardTakapuna, New Zealand
  1. Correspondence to Dr Shalini Kunasegaran, shal84@gmail.com
  • Accepted 13 July 2017
  • Published 7 August 2017

Summary

A 23-year-old man presenting with florid Cushing’s syndrome was found to have high plasma ACTH and very high serum prolactin. Pituitary MRI showed a large invasive macroadenoma.

Low-dose cabergoline promptly suppressed both ACTH and prolactin levels within 2 weeks, with unexpected clinical and biochemical hypocortisolism requiring hydrocortisone replacement. Secondary hypogonadism was reversed. Clinical and biochemical remission of his Cushing’s syndrome together with significant shrinkage of his macroadenoma has been maintained for 1 year on cabergoline 0.5 mg twice weekly. Reduction in pituitary

Reduction in pituitary tumour volume and brisk fall in serum prolactin in response to low-dose cabergoline is regularly observed in patients with macroprolactinomas, but the concurrent fall in the plasma ACTH level and hypocortisolism was a pleasant surprise.

We assume that he most likely has a single bihormonal adenoma that is enriched with dopamine-2 receptors.

From http://casereports.bmj.com/content/2017/bcr-2017-219921.short?rss=1

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