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Anatomy and Physiology 2 Lab Manual: 1 - Endocrine System

Anatomy and Physiology 2 Lab Manual
1 - Endocrine System
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table of contents
  1. 1 - Endocrine System
  2. 2 - Blood
  3. 3 - Heart Anatomy
  4. 4 - Cardiovascular Physiology
  5. 5 - Blood Vessels
  6. 6 - Lymphatic System
  7. 7 - Respiratory System
  8. 8 - Digestive System
  9. 9 - Urinary System
  10. 10 - Reproductive System

Exercise 1: Endocrine System

A group of mailboxes with numbers.

Figure 1.1 Post office boxes and the unique keys needed to unlock each one provides an analogy for how hormones act like ‘keys’ in the body to promote or inhibit biological processes.

Exercise 1 Learning Goals

After completing this lab, you should be able to:

  • Explain the relationship between the endocrine and nervous systems in maintaining homeostasis
  • Identify and locate the major organs of the endocrine system
  • Understand the basic functions of the major endocrine organs
  • Explain the fundamental differences between water- and lipid-soluble hormones
  • Identify the stimuli for release or inhibition of major hormone
  • Identify the target tissue and general outcome of major hormones

The endocrine system, along with the nervous system, is how organ systems throughout the body communicate with each other. Above all others, the endocrine and nervous system together have the primary responsibility of maintaining homeostasis throughout the body.

Nervous vs. Endocrine Signaling

The nervous system communicates throughout the body via either electrical or chemical signals. The electrical signals occur via electrical potentials sent along nerves based on ion flow and the chemical signals are via neurotransmitters. Neurotransmitters (NT) are small molecules or neuropeptides which, when stimulated by an action potential, are released from the synaptic terminal of a neuron. Neurotransmitters then diffuse across the synaptic cleft and may interact with receptor proteins on neurons or muscle cells immediately adjacent to that they will be acting upon. When a neurotransmitter binds with its post-synaptic receptor, it results in the continued propagation of electrical signaling or induces a change in cellular functioning. Due to the limited distance and extremely brief period of time they are active, neurotransmitters are the body’s rapid response system. Recall that the sympathetic division of the autonomic nervous system is often called the “fight-or-flight” response- this is an example of when neurotransmitters are rapidly being released and allow an individual to respond to a threatening situation. When a physiological situation requires an immediate and rapid response, neurotransmitters are involved. Therefore, the nervous system, and the release of neurotransmitters are associated with physiological reactions to the external environment (i.e., when a bear is chasing you; you hear a scary noise in the middle of the night; or if you show up unprepared to your A&P lab practical).

In contrast to the immediate, lightning-quick response of the nervous system- the endocrine system works more slowly. Since it uses only chemical signals, called hormones, and not electrical potentials- the endocrine system does not react as rapidly. Furthermore, hormones must travel through the body via the bloodstream to reach their target cells. This means that even the quickest endocrine responses can take several minutes to hours, and most are even slower acting, taking several days to induce a change. Additionally, many hormones can interact with a variety of target cells throughout the body and therefore can produce a wide range of physiological outcomes depending on the tissue involved. Due to its slower, more measured pace of response- the endocrine system is associated with physiological reactions to the internal environment of the body (i.e., stimulating the release of a hormone when blood glucose levels are low; regulating changes in blood pressure; or responding to major events like childbirth).

Structures of the Endocrine System

In contrast to the exocrine system of glands which secrete their products into ducts and then convey these to their site of action (i.e., sweat, sebum, milk, salivary & digestive enzymes), the glands of the endocrine system secrete their hormones in a ductless manner directly into the interstitial fluid around them or into the bloodstream for transportation elsewhere in the body. There are many glands with primarily endocrine functions like the pituitary, thyroid, parathyroid, adrenal, and pineal glands. Others like the hypothalamus, pancreas, and most others have both endocrine and non-endocrine functions.

Alternate Methods of Chemical Signaling

When an endocrine organ or tissue secretes its hormonal products into the interstitial (or extracellular) fluid surrounding it, the hormone may enter a blood vessel and travel in a classic endocrine signaling fashion and is thus known as a circulating hormone. If the hormone remains nearby and exerts its effects on cells within the same area where it was released, it is acting as a paracrine hormone (para- = “nearby”). If acting only on a directly adjacent cell, it is a juxtacrine hormone (juxta-=” next to”). When a hormone is produced but only acts upon the cell which created it, it is called an autocrine hormone (auto- = “self”).

Mechanism for Control of Hormone Secretion

Because hormones can induce such a wide variety of and potentially lethal physiological responses, it is important for the body to be able to control their secretion with great precision. The processes involved in controlling a specific hormone’s secretion is called a feedback loop. Feedback loops determine how the body, and a hormone will respond in each physiological situation and what outcome will occur. These are typically used in the frame of how to return the body to homeostasis when an imbalance has occurred and may be caused by disease or normal everyday healthy disruptions.

Feedback loops fall into one of two categories- negative or positive. The least common of the two is the positive feedback loop. A positive feedback loop is reserved for special physiological circumstances because of its method of action where the release of a specific hormone causes MORE of the same hormone to be released. Examples of positive feedback loops are the release of oxytocin during childbirth which stimulates the uterine contractions necessary for the progression of labor or a nursing infant stimulating the production of prolactin for continued milk production by nursing. In both situations, a continuation (and potentially an increase) of the physiological response is desirable.

Figure 1.2 Example of a negative feedback loop in the secretion control of cortisol.

This diagram shows a negative feedback loop using the example of glucocorticoid regulation in the blood. Step 1 in the cycle is when an imbalance occurs. The hypothalamus perceives low blood concentrations of glucocorticoids in the blood. This is illustrated by there being only 5 glucocorticoids floating in a cross section of an artery. Step 2 in the cycle is hormone release, where the hypothalamus releases corticotropin-releasing hormone (CRH). Step 3 is labeled correction. Here, the CRH release starts a hormone cascade that triggers the adrenal gland to release glucocorticoid into the blood. This allows the blood concentration of glucocorticoid to increase, as illustrated by 8 glucocorticoid molecules now being present in the cross section of the artery. Step 4 is labeled negative feedback. Here, the hypothalamus perceives normal concentrations of glucocorticoids in the blood and stops releasing CRH. This brings blood glucocorticoid levels back to homeostasis.

The most common method for hormone regulation is through negative feedback loops. In contrast to positive feedback, negative feedback loops stop the secretion of a hormone once its levels have reached appropriate concentrations in the blood. It is a general rule that most every hormone is regulated through some version of a negative feedback loop.

Endocrine Structures to Know:

  • Hypothalamus
  • Pituitary gland
    • Anterior portion
    • Posterior portion
  • Pineal gland
  • Thyroid gland
  • Parathyroid glands
  • Pancreatic islets (Pancreas)
  • Adrenal glands
    • Adrenal cortex
    • Adrenal medulla

A diagram of the body showing the endocrine structures in their correct anatomical locations.

Figure 1.3 Location and names of major endocrine organs.

Exercise 1 Activities: Identification of Organs and Tissues

Lab Activity1.1: Identifying Endocrine Organs and Tissues

Locate all the structures listed above on pictures in your required textbook or on models presented in lab. Label each structure from the list above using sticky-note tabs and placing them on each structure.

Lab Activity 1.2: Matching Hormones to Site of Production

Complete the table of endocrine structures below.

Endocrine Structure

Hormone

Abbreviation

Or N/A

Water- or Lipid-Soluble?

Hypothalamus

1. Growth Hormone-Releasing Hormone

GHRH

Water

2.

3.

4.

5.

6.

7.

Anterior Pituitary

1.

2.

3.

4.

5.

6.

7.

Posterior Pituitary

1.

2.

Pineal Gland

Thyroid Gland

1.

2.

3.

Parathyroid Glands

Pancreas

1.

2.

3.

4.

Adrenal Cortex

1.

2.

3.

Adrenal Medulla

1.

2.

Lab Activity 1.3: Defining Hormone Functions and Target Tissues

Complete the missing information from the table below. You will want to refer to this information throughout the semester as new organ systems and their major hormones are discussed.

Hormone

Produced by:

Physiological Action

Growth Hormone Releasing Hormone

Hypothalamus

Acts on somatotroph cells in the A.P.; stimulates release of Growth Hormone

Growth Hormone Inhibiting Hormone

Thyrotropin Releasing Hormone

Gonadotropin Releasing Hormone

Prolactin Inhibiting Hormone

Corticotropin Releasing Hormone

Prolactin Releasing Hormone

(Human) Growth Hormone 

Thyroid-Stimulating Hormone

Follicle-Stimulating Hormone 

Luteinizing Hormone 

Prolactin 

Adrenocorticotropic Hormone 

Melanocyte-Stimulating Hormone 

Anti-Diuretic Hormone

Oxytocin

Triiodothyronine

Thyroxine

Calcitonin

Parathyroid Hormone

Insulin

Glucagon

Erythropoietin

Calcitriol

Mineralocorticoids (Primary)

Glucocorticoids

(Primary)

Gonadocorticoids

(Primary)

Epinephrine

Norepinephrine

Post-Lab 1 Review

Post-Lab Activity 1.1: Questions

  1. Define using your own words and give an example of each:
    1. Endocrine gland –
    2. Neuroendocrine cells–
    3. Hormones –
    4. Autocrine –
    5. Paracrine –
    6. Negative feedback loop –
    7. Positive feedback loop –
  2. How do water-soluble hormones travel through the body to their target tissue?
  3. How do water-soluble hormones enter their target cell? Describe the general process.
  4. Give several examples of water-soluble hormones in each category.
    1. Amine Hormones –
    2. Peptides & Protein Hormones –
    3. Eicosanoid Hormones –
  5. How do lipid-soluble hormones travel through the body to their target tissue?
  6. How do lipid-soluble hormones enter their target cell? Describe the general process
  7. Give several examples of lipid-soluble hormones in each category.
    1. Steroid Hormones –
    2. Thyroid Hormones –

Post-Lab Activity 1.2: Matching

Write the letter of the organ next to the hormone that the organ produces/secretes.

Letter

Hormone

Organ

Somatotropin

  1. Thyroid

Glucagon

  1. Pancreas

Androgens

  1. Pineal gland

Prolactin Inhibiting

  1. Pituitary

Follicle stimulating

  1. Parathyroid

T3

  1. Hypothalamus

Insulin

  1. Adrenal glands

Mineralocorticoids

oxytocin

Thyrotropin releasing

Prolactin

Calcitonin

Melatonin

Parathyroid

Adrenocorticotropic

Write the letter of the function next to the hormone that causes the physiological action.

Letter

Hormone

Function

Thyrotropin

a. conservers body water by decreasing urine volume, reducing water loss, and raising blood pressure

Calcitonin

b. raises blood glucose levels by increasing breakdown of glycogen into glucose

Androgens

c. stimulates the adrenal cortex to secrete cortisol

Adrenocorticotropic

d. initiates development of oocytes or spermatocytes and induces secretion of estrogens

Pancreatic Polypeptide

e. stimulates secretion of follicle stimulating hormone and luteinizing hormone

T4

f. enhances the effects of the sympathetic division of the autonomic nervous system when stressed

Follicle stimulating

g. inhibits secretion of insulin and glucagon, as well as, slowing absorption of nutrients from the GI

Vasopressin

h. assist in growth of axillary and pubic hair in men and women

Oxytocin

i. stimulates contraction of smooth muscle in the uterus during childbirth and cause milk ejection

Glucocorticoids

j. inhibits somatostatin secretion and secretion of digestive enzymes

Glucagon

k. controls secretions and activities of the thyroid gland

Somatotropin

l. increases basal metabolic rate, stimulates synthesis of proteins, and accelerates body growth

Gonadotropin-releasing

m. lowers blood calcium and phosphate by inhibiting osteoclast activity

Somatostatin

n. increase breakdown of protein stimulating gluconeogenesis and lipolysis, dampens inflammation and depresses immune response

Norepinephrine

o. stimulates liver, muscle, cartilage, and bone to synthesize and secrete insulin-like growth factors which promote tissue growth

Annotate

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