【Abstract】ObjectiveTo investigate the effect of xenotransplantation of microencapsulated rabbit parathyroid tissue in different sites in rats for the treatment of hypoparathyroidism. MethodsThe parathyroid glands from Wistar rats were removed to make them aparathyroid. Ultimately, sixteen rats were included because their serum calcium values were continuously below 1.6 mmol/L. We also encapsulated the cultured rabbit parathyroid tissue with alginateBaCl2 microcapsule. According to the transplantation sites, rats were randomly divided into two groups: renal adipose microcapsule group and peritoneal microcapsule group, eight in each group. Encapsulated rabbit parathyroid tissues were then transplanted accordingly to different microcapsule groups. The calcium serum contents were examined on 5,15,25,35,45,55 and 65 d respectively after transplantation and the grafts were observed through electron microscope on the 65 d in particular. ResultsThe calcium contents after transplantation in renal adipose microcapsule group restored to normal and the observation outcomes of grafts showed that they survived well. The calcium contents of posttransplantation in peritoneal group also restored to normal with an exception that it dropped to a level lower than 1.6 mmol/L on the 65 d. Electron microscope also showed that there were necrotic tissues in the center and only a few cells survived on the edge of the grafts. Within peritoneal microcapsule group, the values were significantly lower than others taken at different phases. ConclusionMicroencapsulated rabbit parathyroid tissue that was xenotransplanted into rats can survive and function without administration of immunodepressant. There are significant differences of calcium contents at varying phases between two transplantation sites, which demonstrate that renal adipose may be an optimal site for microcapsule xenotransplantation.
Objective To understand anatomy of parathyroid gland and explore its application value in protection of parathyroid gland function during thyroidectomy. Methods The literatures, which were associated with the parathyroid anatomy and hypoparathyroidism were collected. The origin, function, anatomical location, number, blood supply, lymphatic system of the parathyroid gland and its relationship with surrounding tissues of parathyroid gland and its clinical significance in the thyroidectomy, were reviewed. Results The position of the superior parathyroid gland was relatively constant, and the inferior parathyroid gland was more likely to be ectopic. The number of the parathyroid gland was uncertain. The mainstream view was that the arterial supply of the parathyroid glands was mainly ensured by the inferior thyroid artery, a few by anastomosis of the superior and inferior thyroid arteries, or by the superior thyroid artery. However, the alternative view was that the blood supply of the parathyroid gland was not mainly derived from the inferior thyroid artery. The parathyroid gland was not easily distinguished from the adipose tissue and lymph node. Whether there was an independent lymphatic system in the parathyroid gland was still controversial. In the thyroidectomy, the parathyroid gland and its blood supply were reserved or protected by distinguishing from the Zuckerkandl tubercle, recurrent laryngeal nerve, and parathyroid specific attachment fat, which were identified by utilizing of the nanocarbon, loupe magnification, etc.. Especially in the central lymph neck dissection, the main thyroid artery trunk and its important branches should be carefully dissected or retained through the gentle capsular dissection and the correct use of energy devices for vessel sealing. The parathyroid gland in situ was reserved according to the parathyroid type. If it was not possible to be preserved, the parathyroid autotransplantation was necessary during the thyroidectomy. Conclusions Understanding origin and location of parathyroid gland, it could provide a direction for searching parathyroid gland during thyroidectomy. Being familiar with blood supply of parathyroid gland makes it possible to protect blood vessel and preserve parathyroid gland. Gentle capsular dissection, rational use of energy device, and indocyanine green angiography seem to be more important. Number of parathyroid gland allows us to treat each parathyroid gland as the last one, if it is not preserved in situ , parathyroid gland need to be autografted to avoid hypoparathyroidism.
ObjectiveTo summarize the latest progress of parathyroid gland identification in thyroid surgery, and to provide some reference for improving the clinical efficacy.MethodThe literatures about the identification of parathyroid gland in thyroid surgery in recent years were collected to make an review.ResultsThere were many methods for identifying parathyroid gland in thyroid surgery, such as naked eye identification method, intraoperative frozen section, intraoperative staining identification method, intraoperative optical identification method, intraoperative parathyroid hormone assay, γ-detector, and histological identification, each method had its own advantages and disadvantages.ConclusionThe identification of parathyroid gland does not only depend on a certain method, but also require surgeons to enhance their ability to distinguish parathyroid gland.
Objective To analysis causes of reoperation for primary hyperparathyroidism and its clinical characteristics. Method The clinical data of the patients with primary hyperparathyroidism who had undergone reoperation from January 1993 to May 2017 were retrospectively analyzed. Results A total of 11 patients underwent reoperation were collected in the 226 patients with primary hyperparathyroidism. Of the 11 cases, 8 cases underwent twice operations, 2 cases underwent thrice operations, 1 case underwent quintic operation. After the initial operation, 3 cases were persistent diseases and 7 cases were recurrent diseases, 1 patient was not defined as the persistent or recurrent disease. The main clinical manifestations before the reoperation were fatigue, pain in joints, bones, or muscle. The reasons for reoperation included 3 cases of ectopic parathyroid lesions, 3 cases of recurrent parathyroid carcinomas, 1 case of enlarged operation extent for parathyroid carcinoma, 2 cases of regrowth of double parathyroid aedomas, 1 case of missing adenoma, 1 case of parathyroid hyperplasia. Among the location examinations, the 99Tcm-MIBI was most sensitivity (8/9). Eight cases were received reoperation on the original incision, and the remaining 3 ectopic parathyroid lesions on the new incision. After the reoperation, 2 patients were lost of follow-up, 1 patient died, and the remaining 8 patients had no recurrences during follow-up period. Conclusion A comprehensive approach with multiple imageology examinations which attribute to accurate location of lesions, experienced surgeons and well knowledge of parathyroid anatomy and embryology help to descend reoperation ratio and improve success rate of reoperation.
ObjectiveTo investigate the risk factors for hypoparathyroidism following radical surgery for patients with thyroid papillary carcinoma (PTC).MethodsA retrospective analysis was made on 192 patients with PTC who underwent radical thyroidectomy in the Department of Head Neck and Thyroid Surgery of Henan Cancer Hospital from January 2019 to January 2020. There were 52 males and 140 females with a median age of 48 years. The risk factors of hypocalcemia and hypoparathyroidism syndrome were screened by χ2 test and binary logistic regression analysis.ResultsIn 192 patients the proportion of patients with normal or hypoparathyroidism after operation were 62.5% (120/192) and 37.5% (72/192), respectively. Univariate analysis showed that complications, Hashimoto’s thyroiditis (HT), total thyroidectomy, N1a staging, Ⅵ lymph node dissection and parathyroid not planted were risk factors for postoperative hypoparathyroidism in patients with PTC. Binary logistic regression analysis showed that: ① HT, N1a staging and Ⅵ lymph node dissection were independent risk factors for postoperative hypocalcemia [without HT: OR=0.313, 95%CI (0.129, 0.760), P=0.010; N1a staging: OR=3.457, 95%CI (1.637, 7.301), P=0.001; without Ⅵ lymph node dissection: OR=0.115, 95%CI (0.041, 0.323), P<0.001]. ② HT, N1a staging, Ⅵ lymph node dissection and parathyroid not planted were independent risk factors for postoperative low parathyroid hormone [without HT: OR=0.285, 95%CI (0.117, 0.698), P=0.006; N1a staging: OR=3.747, 95%CI (1.762, 7.968), P=0.001; without Ⅵ lymph node dissection: OR=0.112, 95%CI (0.039, 0.317), P<0.010; planted parathyroid: OR=0.464, 95%CI (0.221, 0.978), P=0.043].ConclusionHT, N1a staging, Ⅵ lymph node dissection and parathyroid not planted are vital risk factors for hypoparathyroidism in patients with PTC after radical thyroidectomy.
【Abstract】ObjectiveTo discuss how to identify and protect the parathyroid glands (PTGs) and their blood supplies during thyroidectomy. MethodsProtective measure of PTGs and their blood supplies were observed during the operation by eyes, as well as the occurrence of hypoparathyroidism after operation. Patients with syndrome of hypocalcaemia were given calcium and vitamin D3 supplementation until the serum calcium became normal. ResultsThere was no PTG found in 13 cases (13/259), 242 superior PTGs were found which were almost consistently (91.32%) located in the back sides of the thyroid glands and on the level of inferior edge of the thyroid cartilage. The blood supplies of 61 superior PTGs were often (68.85%) from the upper branch of inferior thyroid artery (ITA). Total 426 inferior PTGs were found, and the locations of which were more variable. Approximately 49.77% were located in the inferior 1/3 part of the back sides of the thyroids, 24.88% were positioned immediately to the inferior thyroid, where the ITA branches inserted into the thyroid. The blood supplies of 128 inferior PTGs were also mostly (80.47%) from the inferior branches of ITA system. There was no permanent hypoparathyroidism occurred and hypocalcemia after operation was happened to 27 patients, in which one patient of reoperation was underwent unilateral thyroidectomy, 3 patients were underwent unilateral thyroidectomy and contralateral subtotal thyroidectomy, 4 patients were underwent total thyroidectomy, 7 patients were underwent total thyroidectomy plus bilateral central neck dissection, 11 patients were underwent total thyroidectomy plus unilateral neck dissection, and one patient was underwent total thyroidectomy plus bilateral neck dissection. ConclusionThe blood supplies of PTGs are associated with their locations. The PTGs can be exposed and protected by eyes during operation. To prevent postoperative hypoparathyroidism, the PTGs should be protected in situ through meticulous dissection without
【Abstract】ObjectiveTo investigate the technique of establishing a model of aparathyroid rat which could be used in the study of parathyroid cells transplantation. Methods Parathyroid glands were surgically excised and identified pathologyically. Serum calcium and parathyroid hormone in rats before operation and on day 2,5,10,15 and 30 after operation were measured. Results Parathyroid glands were resected successfully in 8 rats, and the resection rate was 80% (8/10). No obvious changes of serum calcium and parathyroid hormone levels were found before and after operatiion in sham parathyroid gland excision group (Pgt;0.05). However, statistically significant changes of those data were found perioperatively in parathyroid gland excision group (P<0.01). Conclusion The model of aparathyroid rat can be established successfully after parathyroid glands in rats are excised exactly. Parathyroid allotransplantation could be performed ten days after parathyriodectomy.