brief history of endocrinology and diabetes
Control systems regulating hormone production
Learning objectives
To be capable of defining endocrinology
To understand what endocrinology means as a basic science and a clinical specialty
To appreciate the history of endocrinology
To understand the classification of hormones into peptides, steroids and amino acid derivatives
To understand the principle of how feedback mechanisms regulate hormone levels in the circulation
This chapter introduces endocrinology and diabetes including some of the basic principles that underpin the following chapters
Box 1.1 The endocrine and nervous systems are the two main communication systems in the body
| Monitor internal and external environments | Ensure homeostasis |
| Allow appropriate adaptive changes | |
| Communicate via chemical messengers |
Figure 1.1 Chemical signalling in the endocrine and neural systems. (a) In endocrine communication, the producing cell secretes hormone into the blood vessel, where it is carried, potentially over large distances, to its target cell. (b) Sometimes hormones can act on the cell that produces them (autocrine, A) or nearby cells (paracrine, P) without the need for transport via the circulation. For instance, glucagon from α‐cells and somatostatin from δ‐cells can regulate insulin secretion by adjacent β‐cells within the pancreatic islet. (c) In neuroendocrine communication, neurons can secrete hormones into the surrounding blood vessels to reach a more distant target. A good example is hypothalamic regulation of the anterior pituitary. (d) In pure neural communication, neurons activate other neurons via neurotransmitters released from axonic terminals into the synaptic space. Conceptually, neurotransmitters are similar to hormones and in some instances, such as for norepinephrine/noradrenaline, can actually be the same chemical.
All organisms need to be able to analyze and respond to their surroundings in order to provide a constant internal environment. Maintaining this internal constancy is called homeostasis. For an organism comprised of a single or a few cells homeostasis is relatively easy as no cell is more than a short diffusion distance from the outside world or its neighbours. This simplicity has been lost with the evolution of more complex, larger, multicellular organisms. Diffusion alone is inadequate in larger animal species where discrete functions localize to specific organs. In humans, there are ∼1014 cells of more than 200 different types. With this compartmentalized function comes the need for effective communication to disseminate information throughout the whole organism – only a few cells face the outside world, yet all need to respond to it. Two communication systems facilitate this: the endocrine and nervous systems (Box 1.1).
Whereas gastrointestinal cells tend to secrete chemicals into ducts, the specialized cells that make up the glands and tissues of the endocrine system release their chemical messengers, called hormones, into the extracellular space, from where they enter the bloodstream. Historically, this blood‐borne transit of hormones was what defined ‘endocrinology’; however, the principle is identical for hormone action on a neighbouring cell (called a paracrine effect) or, indeed, the endocrine cell itself (an autocrine or intracrine effect) (Figure 1.1).
The nervous and endocrine systems interact. Endocrine glands can be under nervous control; the adrenal medulla is an excellent example (Chapter 6). Conversely, neural cells can themselves release hormones into the bloodstream. This is particularly relevant in the hypothalamus (Chapter 5). Indeed, this interplay between the body's two main communication systems has led to the composite specialty of ‘neuroendocrinology’ (Figure 1.1).
A brief history of endocrinology and diabetes
The term ‘hormone’, derived from the Greek word ‘hormaein’ meaning ‘to arouse’ or ‘to excite’, was first used in 1905 by Sir Ernest Starling in his Croonian Lecture to the Royal College of Physicians. However, endocrinology is built on foundations that are far older. Although Aristotle described the pituitary, gigantism, caused by excess growth hormone (GH) from the somatotrophs of the anterior pituitary, was referred to in the Old Testament. It was only two millennia or so later in the 19th century that the gland’s anterior and posterior components were appreciated by Rathke, and Pierre Marie connected GH‐secreting pituitary tumours to acromegaly and excess growth.
Diabetes was recognized by the ancient Egyptians. Areateus later described the disorder in the second century AD as ‘a melting down of flesh and limbs into urine’. Consequently, diabetes comes from the Greek word meaning ‘siphon’. The pancreas was only implicated relatively recently when Minkowski realized in 1889 that the organ’s removal in dogs mimicked diabetes in humans.
The roots of reproductive endocrinology are equally long. The Bible refers to eunuchs and Hippocrates recognized that mumps could result in sterility. Oophorectomy in sows and camels was used to increase strength and growth in ancient Egypt. The dependence of endocrinology on technology is also long standing. It took the invention of the microscope in the 17th century for Leeuwenhoek to visualize spermatozoa and later, in the 19th century, for the mammalian ovum to be discovered in the Graafian follicle.
During the last 500 years, many endocrine organs and systems (‘axes’) have been identified and characterized.
