17 Thyroid and Parathyroid

Thyroid:

Have you ever wondered how your body stays stable and comfortable in varying temperatures? Whether it is ice cold or burning hot your body temperature will regulate so you do not freeze or melt. This is due to the butterfly shaped thyroid gland lying inferior to the larynx. It is composed of left and right lateral lobes on either side of the trachea. It secretes many important hormones. Within the thyroid are microscopic thyroid follicles, consisting of:

• Follicular cells: form the lumen(internal space) which produce several hormones
• Basement membrane: surrounds each follicle

Thyroid hormones:

As depicted above, follicular cells produce two hormones: thyroxine (T4) and triiodothyronine (T3). The number depicts the number of iodine atoms present in the hormone. Roughly 99% of T4 and T3 combine with thyroxine-binding globulin (TBG) to be carried through the bloodstream. Some parafollicular cells lie in between follicular cells which produce a hormone called calcitonin, which helps regulate calcium homeostasis. The basic functions of thyroid hormone (T3 and T4) are as follows:

1. Increase basal metabolic rate (BMR), the rate of oxygen consumption under standard or basal (awake, at rest, and fasting) conditions.
2. Stimulates synthesis of sodium-potassium ATPase pumps. The increased concentration of pumps leads to increased ATP usage and therefore increases the body temperature. Therefore, thyroid hormone plays key roles in maintaining body temperature especially in cold environments.
3. Stimulate protein synthesis, and increase use of glucose or fatty acids.
4. Enhances actions of some catecholamines (epinephrine, norepinephrine) leading to increased heart rate, and blood pressure.
5. In conjunction with human growth hormone, thyroid hormone stimulates nervous and skeletal growth.

Thyroid Hormone homeostasis:

Like most – not all – hormones, T3 and T4 are regulated within a negative feedback loop which detects high levels of a hormone and subsequently inhibits the original stimulus to return to homeostasis:

1. Low levels of T3 or T4, or low metabolic rate causes the hypothalamus to release TRH
2. TRH enters the hypophyseal portal system and into the anterior pituitary to release TSH
3. TSH stimulates various aspects of the thyroid to promote hormone synthesis and growth of follicular cells
4. Thyroid follicles release T3 and T4 which in turn inhibit TRH and TSH release, thus returning thyroid hormone to homeostatic concentrations.

Calcitonin:

Calcitonin is a hormone produced from parafollicular cells which help regulate the levels of calcium and phosphate in the blood, promoting the formation of bone and reducing the levels of calcium in the blood when they’re too high. Calcitonin also inhibits calcium release by inhibiting osteoclasts which break down bone tissue.

Calcitonin works to keep the balance of calcium in your body by lowering it when there’s too much. It helps to store calcium in bones and reduces the amount of calcium absorbed in the intestines and kidneys when calcium levels are too high.

Parathyroid Glands:

The parathyroid glands are usually found in pairs on the back of the thyroid gland. Normally, they are where the main blood vessels enter the thyroid, but the lower pair can be found anywhere from the bottom of the thyroid to the upper chest area.

Blood supply to the parathyroid glands comes from the thyroid arteries, and the veins drain into the thyroid veins.

Parathyroid glands are like the body’s calcium accountants releasing a hormone called parathyroid hormone (PTH), which increases blood calcium levels by breaking down bones via osteoclasts and increasing calcium absorption in the intestines and kidneys. PTH acts on bones as if they are banks of calcium which can be used to maintain proper calcium concentrations.

PTH is produced by chief cells (not those in the stomach), which are surrounded by large adipose cells within the parathyroid.

View the image below to get a clearer understanding of the thyroid and parathyroid secretions: