4. DiscussionHexavalent chromium (C

4. Discussion
Hexavalent chromium (CrVI) has been widely used in industries throughout the world. Increased its usage and atmospheric emission of CrVI from catalytic converters of automobiles, and its improper disposal cause various health hazards [2].

Today, it is known that there is a close relationship between workers health and the amounts of industrial pollution provoked by industries manufacturing chromium containing materials. So, numerous and different in vitro and/or in vivo studies on chromium have been undertaken either in animals or in human [21].

The present work studied the effect of potassium dichromate on the thyroid gland structure and the possible protective role of vitamin C. The study revealed the effects of chromium compound on the thyroid gland which appeared in the form of irregularity in size and shape of the follicles. Some of them were lined with squamous epithelium, others lined with cubical and the third group of follicles were lined with tall columnar cells with apical pseudopodia. Interfollicular spaces were widened either as a result of collapse of some follicles or due to necrosis of the others leaving empty spaces. The cytoplasm of some follicular cells appeared vacuolated and even desquamation of some cells into the lumens were seen in the majority of sections.

Other work reported that, administration of sodium dichromate in the drinking water to rats and mice resulted in focal ulceration, hyperplasia, and metaplasia in the glandular stomach and hyperplasia of the duodenum [22]. Also, histological analysis of the effect of chromium on male reproductive system revealed pronounced morphological alterations with enlarged intracellular spaces and tissue loosening [15].

The present work revealed increase in the interfollicular spaces and disruption of the basal lamina of follicles and these findings were coincided with other studies [23]. The latter reported decrease in the size of follicles and widening of the interfollicular spaces and attributed this widening to disruption of the connective tissue. At the end they concluded that Cr(VI) is potentially toxic to the thyroid gland. Also, another studies found the same results with irregularity and shrunken of some follicular cells increase in the number of disorganized and collapsed follicles. Hyperplasia of follicular cells and nuclei appeared oval, rounded, irregular and even shrunken. They added that disruption of the apical and basal laminae were seen [24].

Disorganization of the thyroid follicles and cytoarchitecture indicate high level of toxicity caused by the chromium. TSH is responsible for the morphological appearance of thyroid follicles and the synthesis and secretion of thyroid hormones leading to hypertrophy and hyperplasia of the follicular cell. One of the early responses of TSH-stimulated thyroid follicular cells is engulfment of colloid material from the follicular lumen into the apical cytoplasm of thyrocytes, in the form of membrane-bound colloid droplets. Administration of TSH to rats pretreated with thyroxin resulted in the formation of numerous pseudopods on the apical surface of thyrocytes, followed by the appearance of colloid droplets, at first in the apical and later on in the deeper parts of the cytoplasm. It was also stated that the percentage of follicular cells containing colloid droplets and the number of droplets in cells gradually increased with the increase of TSH dose [23] and [25].

However, irregularity in the size of follicles in some animals may be normal, as the size distribution pattern of thyroid follicles is different between the peripheral and central gland regions. In rats, the larger thyroid gland follicles are mostly located at the periphery of the thyroid lobes stated that the large follicles at periphery mainly serve as a pool of old hormone, whereas the smaller, centrally distributed ones are responsible for thyroid hormone secretion [26] and [27].

Variation in the nuclear shape and size was characteristic finding in this work and explained by some authors that increased nuclear area is often observed in compounds that block cell cycle and induce DNA damage [28].

Bcl-2 is an apoptosis-related molecule that was shown to be down-regulated during the early events leading to programmed cell death and its protein might be as an inhibiting molecule and play an important role in the balance between apoptosis promotion and inhibition [29] and [30].

The detection of apoptosis in the follicular cells in this study which was explained in many other studies [31] and [32]. They stated that CrVI induced DNA fragmentation, increased apoptosis, increased cytochrome c release from the mitochondria to cytosol, down regulated anti-apoptotic Bcl-2 and other mediators; upregulated pro-apoptotic [2]. Also it was documented that potassium dichromate-induced apoptosis and oxidative stress in the hepatocytes of Wistar rats.

Some authors explained in details the mechanism by which the Cr(VI) lead to apoptosis. They hypotheses that soluble Cr(VI) is metabolized within cells by reductive agents including ascorbic acid, glutathione and cysteine and a diverse range of genetic lesions are generated. Some forms of Cr damage present physical barriers to DNA replication/transcription and promote a terminal cell fate such as apoptosis or terminal growth arrest. Other DNA lesions are potentially pre-mutagenic and lead to DNA damage and cell cycle arrest [33], [34] and [35].

The electron microscopic results confirmed the results obtained by the light microscope. Some follicles were lined with low prismatic, cuboidal or flattened epithelium with apparent decrease in epithelial height. That was attributed to hypoactivity of the thyroid gland. This was confirmed by biochemical changes in this work in the form of decrease in T3 and T4 level and increase in the TSH level [36]. Others showed stratification of their lining epithelium. The nuclei of thyrocytes appeared shrunked hyperchromatic nuclei, fragmented and dilated rER, swollen mitochondria with degenerated cristae, accumulation of colloid vesicles inside the thyrocytes, even complete loss of all the cytoplasmic organelles. Similar results observed previously in the form of disrupted basal laminae of the follicles, regressed nuclei and disrupted cell organelles [24]. Also, follicular hyperplasia may be connected with a cascade of cellular events involving oxidative stress, genomic DNA damage, and modulation of apoptotic regulatory gene (P53) after exposure to chromium [37]

The mechanism of chromium toxicity was reported to be associated with mitochondrial and lysosomal injury by biologically Cr(VI) reactive intermediates and reactive oxygen species [4]. The results demonstrated that potassium dichromate was highly cytotoxic to cells, and its cytotoxicity seems to be mediated by oxidative stress and DNA damage [7]. The results indicated that administration of Cr(VI) had caused a significant increase of reactive oxygen species (ROS) level generated during reduction of Cr(VI) [38] and [39].

Previous studies both in vitro and in vivo have demonstrated that chromium(VI) induces an oxidative stress through enhanced production of reactive oxygen species (ROS) leading to genomic DNA damage and oxidative deterioration of lipids and proteins. A cascade of cellular events occur following chromium (VI)-induced oxidative stress including enhanced production of superoxide anion and hydroxyl radicals, increased lipid peroxidation and genomic DNA fragmentation, modulation of intracellular oxidized states, activation of protein kinase C, apoptotic cell death and altered gene expression [40], [41] and [42].

In a recent study demonstrated that catalase is a classical oxidative biomarker and is the most abundant in peroxisomes, where oxidative stress most frequently occurs [43] and [44]. The increase in these enzyme activities suggests a response toward increased ROS generation [45] and [46]. Previously, it was reported that Cr(VI) induced thyroid toxicity through increasing cellular oxidative stress and decreasing the activity of antioxidants [47].

Some authors explained that Cr(VI) accumulates in the pituitary and hypothalamus resulting in apoptosis evidenced by nuclear fragmentation and caspase 3 activation. Their results indicate that the anterior pituitary gland can be a target of Cr(VI) toxicity in vivo and in vitro, thus producing a negative impact on the hypothalamic–pituitary-axis and affecting the normal endocrine function [9] and [48].

Some researches observed hypertrophic follicular cells contain dilated r-ER and colloid droplets. Follicles were lined by tall columnar cells and vacuolated mitochondria with disrupted cristae. They explained their results due to Goitrogenic effects of a soybean diet which result in increased thyroid stimulating hormone leading to hyperplasia in thyroid gland [49].

As regard to the thyroid hormone level there was decrease in the level of free T3 and T4. The protective group revealed more or less normal value near to that of the control group. The same results were documented in other works which showed significantly increased TSH and decreased FT3 and FT4 concentrations in protective group serum TSH, FT3 and FT4 concentrations neared control [14]. It was reported that Cr toxicity led quite possibly to a state of hypothyroidism as indicated by a significant increase in the serum TSH and a decrease in the serum FT3 and FT4 concentrations [50].

Vitamin C administration in this work showed some improvement in the thyroid gland function and structure. As, the level of the thyroid hormones became near to the control one. Also, the thyroid gland regained its normal cellular architecture and appeared more or less near to the control.

Previous studies detected that early and repeated high intravenous doses of vitamin C was the therapy of choice for Cr(VI) poisoning [51]. Also the results of [52] showed that vitamin C had antimutagenic