Autotransplantation of rat parathyroid glands: a study on morphological changes

Preservation of parathyroid glands during thyroid and neck surgery

The parathyroid glands are situated in close proximity to the thyroid gland. They have an important endocrine function maintaining calcium and phosphate homeostasis in the body by the secretion of parathormone (PTH), which is responsible for this function. The parathyroid glands are commonly damaged during thyroid surgeries. This could lead to transient or permanent hypoparathyroidism in 30% of cases. Preservation of the parathyroid glands, is an important and integral part of thyroidectomy and other surgical interventions in the neck. The main principle underlying this is a thorough understanding of parathyroid anatomy in relation to the thyroid gland and other important structures in the area. There can also be significant variation in the anatomical location of the glands. Various techniques and methods have been described for parathyroid preservation. They include intraoperative identification utilizing indocyanine green (ICG) fluorescence, carbon nanoparticles, loupes, and microscopes. The techniques of surgery (meticulous capsular dissection), expertise, central compartment neck dissection, preoperative vitamin D deficiency, extent and type of thyroidectomy are the risk factors associated with damaged thyroids, inadvertent parathyroidectomy and subsequent hypoparathyroidism. Parathyroid Autotransplantation is a treatment option for inadvertent parathyroidectomy. Ultimately, the best way to assure normal parathyroid function is to preserve them in situ intraoperatively undamaged.

Vitamin D-independent therapeutic effects of extracellular calcium in a mouse model of adult-onset secondary hyperparathyroidism

Cell proliferation and PTH secretion in the parathyroid gland are known to be regulated by vitamin D and extracellular calcium. Here, we examined the vitamin D-independent effects of correction of extracellular calcium in an adult-onset secondary hyperparathyroidism (sHPT) model, using mice with a nonfunctioning vitamin D receptor (VDR). Wildtype and homozygous VDR mutant mice were kept on a rescue diet (RD) containing 2% calcium (Ca), 1.25% phosphorus (P), and 20% lactose until they were 4 mo or 1 yr of age. Subsequently, 4-mo-old mice were switched to a challenge diet (CD) containing the following: 0.5% Ca, 0.4% P, and 0% lactose. After 2 mo on the CD, groups of VDR mutant mice were either fed CD, a normal mouse chow with 0.9% Ca, 0.7% P, and 0% lactose, or the RD for another 3 mo. Feeding the RD protected VDR mutants against sHPT over 1 yr, showing that vitamin D is not essential for long-term control of the function and proliferation of parathyroid cells. When 4-mo-old VDR mutants were switched from the RD to the CD for 2 mo, they developed severe sHPT associated with hypertrophy and hyperplasia of parathyroid glands and profound bone loss. Subsequent feeding of the RD during a 3-mo therapy phase fully corrected sHPT, reduced chief cell proliferation, and reduced maximum parathyroid gland area by 25% by cell atrophy. There was no evidence of RD-induced chief cell apoptosis. We conclude that signaling by the calcium-sensing receptor regulates chief cell function and size in the absence of signaling through the VDR.

Endometriosis as a neurovascular condition: estrous variations in innervation, vascularization, and growth factor content of ectopic endometrial cysts in the rat

Endometriosis is a poorly understood, estradiol-dependent condition associated with severe pelvic pains and defined by vascularized endometrial growths outside the uterus. Endometriosis is produced in cycling rats by autotransplanting pieces of uterus onto abdominal arteries where they develop into cysts. The surgery induces vaginal and abdominal muscle hyperalgesia, whose severity is greatest in proestrus and nearly absent in estrus. The cysts contain growth factors and cytokines and develop their own sympathetic and sensory C- and Aδ-fiber innervation. Here, we used quantitative immunostaining and protein array analyses to test the hypothesis that the innervation and growth factor/cytokine content of the cysts, but not uterine horn, contribute to proestrous-to-estrous changes in hyperalgesic severity. If so, these characteristics in the cysts, but not the uterine horn, should change with estrous stage. In cysts, the density of sympathetic (but not sensory) neurites and amounts of NGF and VEGF proteins (but not cytokines IL-1, IL-6, IL-10, or TNF-α) were greater in proestrus than estrus. These changes were accompanied by vascular changes. Both sympathetic and sensory fibers in both stages colabeled with TrkA, indicating that changes in NGF could act on both afferent and efferent fibers. In contrast with the cysts, no changes occurred in the uterine horn between proestrus and estrus. Together, these results suggest that coordinated proestrous-to-estrous changes in innervation and vascularization of the cysts contribute to similar changes in hyperalgesic severity. The findings also encourage consideration of endometriosis as a neurovascular condition.

Neuroendocrine-immune disequilibrium and endometriosis: an interdisciplinary approach

Endometriosis, a chronic disease characterized by endometrial tissue located outside the uterine cavity, affects one fourth of young women and is associated with chronic pelvic pain and infertility. However, an in-depth understanding of the pathophysiology and effective treatment strategies of endometriosis is still largely elusive. Inadequate immune and neuroendocrine responses are significantly involved in the pathophysiology of endometriosis, and key findings are summarized in the present review. We discuss here the role of different immune mechanisms particularly adhesion molecules, proteinglycan interactions, and pro-angiogenic mediators in the development and progression of the disease. Finally, we introduce the concept of endometrial dissemination as result of a neuroendocrine-immune disequilibrium in response to high levels of perceived stress caused by cardinal clinical symptoms of endometriosis.

A new animal model to assess angiogenesis and endocrine function of parathyroid heterografts in vivo

BACKGROUND

It is still a matter of investigation how angiogenesis and restoration of gland perfusion determine graft function after free parathyroid autotransplantation. We provide a new animal model allowing simultaneous and repetitive in vivo assessment of angiogenesis and endocrine function of parathyroid transplants.

METHODS

Fresh human parathyroid tissue from patients with secondary hyperparathyroidism was grafted into dorsal skinfold chamber preparations of athymic nude mice (CD1-nu; n=8). Equivalent pieces of the same human donor specimens were heat-inactivated and served as control grafts (n=7).

RESULTS

In all animals receiving parathyroid transplants, intact human parathyroid hormone levels were detectable by species-specific enzyme-linked immunosorbent assay analysis of plasma samples on day 5 after transplantation and increased by 2.5-fold over the observation period (19 days) in contrast with controls. Plasma Ca levels revealed no differences between the groups. On day 5 after transplantation, intravital fluorescence microscopy revealed murine angiogenic microvessels sprouting along nonperfused human donor vessels, and 1 week later functional microvasculature was established in all parathyroid transplants. Histologic analysis revealed well-vascularized endocrine tissue. In contrast, control grafts were necrotic and partly resorbed; they exhibited no angiogenic activity or well-vascularized fat cells indicating fatty degeneration. In addition, species-specific Western blot analysis revealed vascular endothelial growth factor expression of parathyroid transplants rather than functional vessel density as the functional parameter of angiogenesis determining transplant function in vivo.

CONCLUSION

This model may serve to understand mechanisms associated with specific parathyroid transplant angiogenesis and its significance for transplant function to optimize clinical success of autotransplantation in therapy-resistant patients.

Innervation of ectopic endometrium in a rat model of endometriosis

Endometriosis (ENDO) is a disorder in which vascularized growths of endometrial tissue occur outside the uterus. Its symptoms include reduced fertility and severe pelvic pain. Mechanisms that maintain the ectopic growths and evoke symptoms are poorly understood. One factor not yet considered is that the ectopic growths develop their own innervation. Here, we tested the hypothesis that the growths develop both an autonomic and a sensory innervation. We used a rat model of surgically induced ENDO whose growths mimic those in women. Furthermore, similar to women with ENDO, such rats exhibit reduced fertility and increased pelvic nociception. The ENDO was induced by autotransplanting, on mesenteric cascade arteries, small pieces of uterus that formed vascularized cysts. The cysts and healthy uterus were harvested from proestrous rats and immunostained using the pan-neuronal marker PGP9.5 and specific markers for calcitonin gene-related peptide (CGRP) (sensory C and A delta fibers), substance P (SP) (sensory C and A delta fibers) and vesicular monoamine transporter (sympathetic fibers). Cysts (like the uterus) were robustly innervated, with many PGP9.5-stained neurites accompanying blood vessels and extending into nearby luminal epithelial layers. CGRP-, SP-, and vesicular monoamine transporter-immunostained neurites also were observed, with CGRP and SP neurites extending the furthest into the cyst lining. These results demonstrate that ectopic endometrial growths develop an autonomic and sensory innervation. This innervation could contribute not only to symptoms associated with ENDO but also to maintenance of the ectopic growths.

PTH pulsatility but not calcium sensitivity is restored after total parathyroidectomy with heterotopic autotransplantation

In healthy humans, parathyroid hormone (PTH) is secreted via basal mode with superimposed oscillatory bursts every 8 to 12 min. Amplitude and frequency changes mediate the instantaneous response of the parathyroids to changes in ambient Ca(2+) concentrations. The parathyroid gland tetrad may be synchronized by autonomic innervation. This study investigated the effect of total parathyroidectomy and heterotopic autotransplantation of parathyroid tissue (PTX) on PTH secretion patterns in nine patients with end-stage renal disease. Intact-PTH versus time concentration profiles were obtained early (1 to 8 wk, n = 4) or late (15 to 33 mo, n = 5) after PTX. In four patients late after PTX, Ca(2+) responsiveness of PTH secretion was additionally investigated by citrate and calcium clamp studies. The nonrandomness of plasma PTH fluctuations was assessed by the approximate entropy (ApEn) statistic, and secretion characteristics by multiparametric deconvolution analysis. Results were compared with those of matched normal subjects and chronic renal failure (CRF) patients without PTX. PTH burst frequency was 2.9 +/- 0.1 h(-1) early and 7 +/- 0.4 h(-1) late after PTX as compared with 8.1 +/- 0.4 h(-1) in CRF and 7 +/- 0.3 h(-1) in healthy controls. Fractional pulsatile PTH secretion was diminished after PTX (18 +/- 2%) compared with healthy controls (32 +/- 5%, P < 0.05) and CRF patients (25 +/- 4%, P = 0.05). The orderliness of PTH release was significantly reduced after PTX (ApEn: 1.59 +/- 0.03 versus 1.41 +/- 0.09 in healthy and 1.46 +/- 0.03 in CRF controls, P < 0.01). Acute hypocalcemia elicited a lesser increase in pulsatile PTH secretion in PTX patients (147 +/- 134%) than in the CRF (500 +/- 92%, P = 0.05) and healthy controls (1410 +/- 290%, P < 0.05), mainly due to a diminished mass of PTH secreted per burst. Pulsatile PTH secretion was also resistant to hypercalcemia, wherein the suppression of burst mass was significantly reduced compared with that in healthy controls. In conclusion, pulsatile PTH secretion is partially restored within 2 yr of PTX. However, the capacity of the autotransplanted tissue to adapt to changes in ionized calcium remains profoundly disturbed.

Pancreatic tissue grafts are reinnervated by neuro-peptidergic and cholinergic nerves within five days of transplantation

The reinnervation process is crucial for the survival and functioning of cell, tissue or organ transplants. This study was designed to examine the exact time of reinnervation of intraocular pancreatic tissue transplants in rats. The rate of survival of neuropeptide-containing cells in pancreatic tissue grafts was also investigated. Calcitonin gene-related peptide (CGRP), galanin (GAL), neuropeptide Y (NPY) were observed in the surviving nerve cell bodies of the grafts. The iridal nerves reinnervating the pancreatic grafts expressed CGRP, GAL, NPY and choline-acetyl-transferase (ChAT) on day 5, and tyrosine hydroxylase (TH) and nitric oxide synthase (bNOS) on day 6 of the transplantation period. The expression of CGRP in the reinnervating nerves was more consistent when compared to GAL, NPY, ChAT, TH and bNOS. Although all of the three neuropeptides (CGRP, GAL, NPY) were present in the surviving nerve cell bodies of the pancreatic tissue graft up to the end (day 9) of the transplantation period, the number of CGRP-immunopositive cells was consistently higher throughout the transplantation period. Hence, the number of CGRP-positive cells in the pancreatic tissue graft was significantly (P < 0.05) higher than that of GAL and NPY. In conclusion, pancreatic fragments were reinnervated by neuropeptidergic (CGRP, NPY) and cholinergic (ChAT) nerves within the first 5 days of transplantation. In addition to the reinnervation of pancreatic tissue grafts, the intrinsic neurones of the grafts also survived after transplantation. The rate of survival of CGRP-containing cells in the pancreatic tissue grafts was more consistent compared to that of NPY and GAL.

Parathyroid-produced angiopoietin-2 modulates angiogenic response

BACKGROUND

Upon explant, parathyroid tissue (PTH) upregulates vascular endothelial growth factor (VEGF), a potent endothelial cell mitogen, yet PTH induces a more robust angiogenic response than VEGF alone. This implies that other angiogenic factors are also produced. We tested PTH for production and function of angiopoietin-2 (Ang-2), a protein known to modulate VEGF response.

METHODS

With use of reverse transcriptase-polymerase chain reaction and SELDI (Surface Enhanced Laser Desorption/Ionization) (Ciphergen, Freemont, Calif) technology, we tested explanted PTH for Ang-2 production and determined the time sequence of Ang-2 upregulation. With use of an in vitro rat microvessel angiogenesis assay, we determined the angiogenic response to PTH-produced Ang-2.

RESULTS

Ang-2 messenger RNA was induced within 1 hour of parathyroid explant, with a maximum level detectable at 24 hours. Ang-2 protein production was maximal at 24 hours, with elimination by 48 hours. Ang-2 supplemented gels appeared to prompt earlier angiogenic induction, whereas sequestration of Ang-2 with soluble Tie2 receptor appeared to delay angiogenic induction. Soluble Tie2 treatment did not significantly decrease cumulative microvessel length, and no significant increase in neovessel length was seen with Ang-2 supplemented gels.

CONCLUSIONS

PTH upregulates Ang-2 upon explantation, with peak protein production by 24 hours. Ang-2 appears to functionally enhance initiation of PTH-induced angiogenesis, although the ultimate neovessel length appears to be dependent on other PTH-produced factors.

Parathyroid-induced angiogenesis is VEGF-dependent

BACKGROUND

Autotransplantation of parathyroid tissue after parathyroidectomy is successful at salvaging parathyroid function. The relatively high success of parathyroid transplantation is thought to be due, in part, to the ability of parathyroid tissue to induce angiogenesis and thus recruit a new vasculature. Vascular endothelial growth factor (VEGF) is a potent angiogenic factor produced by a number of tumors and hypoxic tissues. Using a 3-dimensional intact microvessel angiogenesis system, we evaluated the role of VEGF in the stimulation of angiogenesis by human parathyroid cells.

METHODS

Freshly isolated rat microvessels embedded in a 3-dimensional collagen I matrix were treated with healthy 1-mm(3) fragments of human parathyroid tissue or isolated parathyroid cells. Other gels were supplemented with VEGF(165) or FLT-1 soluble receptor fusion protein to bind VEGF. After 11 days in culture, the gels were stained with Gs-1 lectin, a marker for rat endothelium, and linear growth of the microvessels was determined by using image analysis. Parathyroid production of VEGF was determined with reverse transcriptase-polymerase chain reaction.

RESULTS

A significant increase in microvessel growth was seen in parathyroid coculture (8.4 +/- 1.0 mm) versus VEGF(165) supplemented gels (6.2 +/- 0.3 mm, P <.01). VEGF(165) significantly augmented parathyroid-stimulated angiogenesis (13.7 +/- 2.4 mm, P <.05 vs parathyroid alone). Using quantitative reverse transcriptase-polymerase chain reaction, we identified VEGF messenger RNA (mRNA) induction within 1 hour of parathyroid explant, with a 12-fold increase by 24 hours. Treatment of parathyroid cocultures with 0.2 microg/mL FLT-1 soluble receptor protein completely eliminated the parathyroid induction of angiogenesis.

CONCLUSIONS

Parathyroid tissue expresses low levels of VEGF mRNA, which is significantly upregulated on explantation. Furthermore, the increased VEGF expression is essential to drive parathyroid-induced angiogenesis in our model. However, our data suggests that other parathyroid-produced factors are involved in mediating parathyroid-induced angiogenesis.