Intraoperative MRI improves complete resection of pituitary macroadenoma

Posted on October 18, 2017 by MaryO
Endocrine Today, October 2017
Brooke Swearingen, MD; Stephanie L. Lee, MD, PhD, ECNU

A 63-year-old man was referred to the Massachusetts General Hospital Neuroendocrine & Pituitary Tumor Clinical Center for management of a pituitary macroadenoma. He experienced increasingly severe retro-orbital headaches in the past year. He reported no double vision, fatigue, orthostatic dizziness, change in beard growth or reduction in libido. An outside head CT scan showed an enlarged pituitary gland.

Imaging and laboratory tests

A pituitary MRI with magnified pituitary slices and gadolinium contrast was ordered. A well-circumscribed “snowman-shaped” sellar mass was identified, measuring 2.6 cm x 2 cm x 1.8 cm (anteroposterior x transverse x craniocaudal) with suprasellar extension (Figure 1). The lesion was heterogeneous on T1-weighted scans after enhancement with IV gadolinium contrast. An area of hypointensity in the superior margin was consistent with a small area of cystic or hemorrhagic degeneration.

Although the mass did not extend laterally into the cavernous sinus, the sellar mass extended upward into the suprasellar cistern through a hole in the dural, the diaphragma sellae, to compress the optic chiasm. The restriction of adenoma growth by the diaphragma sellae results in the snowman shape of the macroadenoma. The optic chiasm and infundibulum (pituitary stalk) could not be identified on coronal or sagittal images (Figure 1). Visual field on confrontation suggested lateral field deficits (bilateral lateral hemianopsia) that were confirmed on formal Goldmann kinetic perimetry visual fields.

Figure 1. Preoperative MRI scan. A large “snowman-shaped” pituitary adenoma (green arrow) has heterogeneous enhancement after gadolinium contrast administration. A small hypodense area in the adenoma likely represented hemorrhage/cystic degeneration (yellow arrow). The tumor does not surround the carotid siphon, an S-shaped portion of the internal carotid artery (red arrows) within the cavernous sinus located laterally from the sella turcica where the pituitary gland resides. (A) Coronal image. (B) Sagittal image. Abbreviation: SS = spenoid sinus.

Source: Stephanie L. Lee, MD, PhD, ECNU. Reprinted with permission.

Initial hormonal evaluation was normal and included morning adrenocorticotropic hormone 18 pg/mL, cortisol 13.64 µg/dL, thyroid-stimulating hormone 2.14 uIU/mL, free thyroxine 1.2 ng/dL and prolactin 12.6 ng/mL. The patient’s morning testosterone level was normal at 324 ng/dL, with follicle-stimulating hormone 2.4 mIU/mL and luteinizing hormone 1.6 mIU/mL. His insulin-like growth factor I level was normal at 124 ng/mL.

Tumor resection

The patient was treated preoperatively with stress-dose hydrocortisone 50 mg. He then underwent transsphenoidal pituitary tumor resection. After the surgeon believed there was an adequate excision of the tumor, the extent of tumor resection was confirmed by an intraoperative MRI (Figure 2 on page 8).

Figure 2. Intraoperative MRI scan. The large macroadenoma is not seen after transsphenoidal surgery. The optic chiasm (yellow arrow) can be seen after removal of the tumor. (A) Coronal image. (B) Sagittal image. Abbreviation: SS = spenoid sinus.

The operation was concluded after the imaging confirmed the complete resection of the pituitary adenoma. The patient’s postoperative course was uneventful. Imaging 4 weeks after the resection confirmed complete resection of the suprasellar mass with residual enhancement of the resection bed and sphenoid sinuses (Figure 3 on page 8). The postoperative MRI revealed a normal optical chiasm and a downward tending of the infundibulum to the residual pituitary gland located inferiorly along the sella turcica (pituitary fossa) of the sphenoid bone. Pathology confirmed a pituitary adenoma. His anterior and posterior pituitary function were normal 6 weeks postoperatively, and his visual field deficit improved.

Intraoperative MRI

Imaging like that used in this case occurs in a specially designed operating room that allows MRI scans during surgery without moving the patient from the surgical table. The MRI is kept in a shielded enclosure during the procedure and then moved along a track into the operating room for imaging. Clinical indications for the use of intraoperative MRI in neurosurgery include resection of pituitary macroadenomas. In the past, these tumors underwent transsphenoidal resection, and the postoperative MRI was performed after 1 or more days after the procedure to check for complete removal. If residual tumor was found, the patients underwent watchful waiting, external radiation or repeat surgery.

The strategic advantage of an intraoperative MRI is that the imaging is performed during the operative procedure, and if there is any residual tumor, surgery can be resumed after the MRI is moved back into the shielded enclosure.

Figure 3. Four-week postoperative MRI scan. The large macroadenoma is not seen after the transsphenoidal survey. The optic chiasm and infundibulum (pituitary stalk) can be seen after resection of the tumor. The pituitary stalk is deviated to the left of the sella where the residual normal thyroid is locate along the sella turcica. The floor of the sella enhances with gadolinium infusion after surgery due to postoperative inflammation. (A) Coronal image. (B) Sagittal image. Abbreviation: SS = spenoid sinus.

It has been reported that the use of intraoperative MRI does not increase complication rates compared with conventional transsphenoidal surgery. Reports on the improvement of gross tumor resection using intraoperative MRI are variable, perhaps due to the expertise of the surgeon. Several reports suggest the use of intraoperative MRI allowed additional resection of noninvasive macroadenomas in 67% to 83% of the patients with a gross tumor resection. These results suggest that a substantial volume reduction and increased gross tumor resection of pituitary macroadenomas occurs with the use of intraoperative MRI compared with standard surgery. One study demonstrated that the gross tumor resection rates of invasive tumors was also improved with the use of intraoperative MRI compared with usual preoperative imaging and surgery (25% vs. 7%).

The use of intraoperative MRI, especially with transsphenoidal reoperations for invasive and noninvasive pituitary macroadenomas, leads to significantly higher “gross tumor resection” rates. This method prevents additional operations or treatment, such as radiation, because it reduces the number of patients with residual adenoma after surgery. This technology is usually found in specialized tertiary care hospitals but should be considered for reoperation for large pituitary macroadenomas or initial operation for large invasive pituitary macroadenomas.

  • References:
  • Boellis A, et al. J Magn Reson Imaging. 2014;doi:10.1002/jmri.24414.
  • Fomekong E, et al. Clin Neurol Neurosurg. 2014;doi:10.1016/j.clineuro.2014.09.001.
  • Tandon V, et al. J Clin Neurosci. 2017;doi:10.1016/j.jocn.2016.10.044.
  • For more information:
  • Stephanie L. Lee, MD, PhD, ECNU, is an Endocrine Today Editorial Board Member. She is associate professor of medicine and director of thyroid health in the Section of Endocrinology, Diabetes and Nutrition at Boston Medical Center. She can be reached at Boston Medical Center, 88 E. Newton St., Boston, MA 02118; email: stephanie.lee@bmc.org.
  • Brooke Swearingen, MD, is associate professor of surgery (neurosurgery) at Harvard Medical School and co-director of the neurological ICU at Massachusetts General Hospital. He can be reached at bswearingen@partners.org.

Disclosures: Lee and Swearingen report no relevant financial disclosures.

From https://www.healio.com/endocrinology/neuroendocrinology/news/print/endocrine-today/%7B23183444-4d29-477b-844f-6eb995ac74f4%7D/intraoperative-mri-improves-complete-resection-of-pituitary-macroadenoma

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Blood Sample from Tributary Adrenal Gland Veins May Help to Diagnose Subclinical Cushing’s Syndrome

Posted on October 18, 2017 by MaryO

Researchers report a new technique for collecting blood samples from tiny veins of the adrenal glands, called super-selective adrenal venous sampling (ssAVS). The technique can be used to help diagnose diseases marked by excessive release of adrenal hormones, such as subclinical Cushing’s syndrome (SCS) or primary aldesteronism (PA).

The study, titled “A Novel Method: Super-selective Adrenal Venous Sampling,” was published in JOVE, the Journal of Visualized Experiments. JOVE has also made a video that demonstrates the procedure.

The adrenal glands are a pair of glands found above the kidneys that produce a variety of hormones, including adrenaline and the steroids aldosterone and cortisol. Excessive production of cortisol in the adrenal glands is the cause SCS, and aldosterone of PA.

These glands have central veins running through them, and three tributary veins (veins that empty into a larger vein). Conventional AVS collects blood from the central veins, but these veins have blood from the adrenal glands as well as blood in wider circulation flowing through them.

ssAVS uses tiny catheters — very long, narrow tubes inserted into blood vessels, called microcatheters — to collect blood from the tributary veins in both adrenal glands. Only blood from the adrenal glands flows through the tributary veins, making analysis of hormone levels easier, and pinpointing the region, or segment, of the gland that is not working properly.

A medical imaging technique, known as angiography, is used to track the positions of the microcatheters. Angiography is a procedure widely used to visualize the inside of blood vessels and organs, and takes roughly 90 minutes.

The paper reported on the use of ssAVS in three patients with adrenal gland disorders, and one (case #2) was diagnosed with SCS and PA. “Overall, in Cases #1 and #2, the ssAVS method clearly indicated segmental adrenal hormone production, not only for aldosterone, but for cortisol, and enabled these patients to be treated by surgery,”  the researchers reported.

Conventional AVS measures hormone levels in whole glands. It is useful for identifying which of the two glands is diseased, and the type of hormone that is overproduced. But sometimes both glands are affected, and only removal of the diseased parts in both glands is safe and effective.

That’s one of the reasons why ssAVS is so useful. By sampling the smaller, tributary veins in three different regions of each gland, the diseased parts can be identified. The diseased parts can then be removed from both glands, if medically advisable, leaving the healthy parts of the glands intact and functional.

ssAVS is also useful because it collects samples of blood coming directly from the adrenal glands, making analysis of hormone levels more reliable.

Researchers concluded that ssAVS is useful in both the diagnosis of adrenal gland disorders and for research that might lead to new therapies.

“Between October 2014 and September 2015, two angiographers … performed ssAVS on 125 cases … with a 100 % success rate and within a reasonable time (58 – 130 min) without adrenal rupture or thrombosis that required surgery,” they wrote. “The ssAVS method is not difficult for expert angiographers, and, thus, is recommended worldwide to treat PA cases for which cAVS does not represent a viable surgical treatment option.”

From https://cushingsdiseasenews.com/2017/10/17/subclinical-cushings-syndrome-may-be-diagnosed-via-blood-from-tributary-adrenal-gland-veins/

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

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