Chapter 1
Anatomy and Physiology: The Nervous System

Understanding the anatomy and physiology of the nervous system is essential as it forms the basis for comprehending various health conditions, conducting assessments and delivering quality patient care. Care providers have contact with a number of patients who are living with neurological disorders who may be at home following acute neurosurgical interventions or with long-term neurological conditions or being cared for in a hospital setting as a result of a brain injury.

The nervous system is one of the main communicating and control systems within the body. It works closely with the endocrine system to control many body functions. The nervous system provides a rapid and short-acting response and the endocrine system provides a slower but often more sustained response. The two systems work together to maintain homeostasis (McErlean and Migliozzi 2020).

The nervous system interacts with all other body systems. This is a large and complex system. In order to enable understanding of the nervous system, it has to be divided into smaller functional and anatomical parts. This chapter outlines the divisions of the nervous system; it discusses the structure and function of the nervous system and how it influences other structures of the body.

Organisation of the Nervous System

The nervous system is divided into two parts: the central nervous system and the peripheral nervous system. The central nervous system is made up of the brain and spinal cord, which is the control and integration centre for many body functions. The peripheral nervous system carries sensory information to the central nervous system and motor information out of the central nervous system. The direction of information flow to and from the nervous system is shown in Figure 1.1.

Figure 1.1 Organisation of the nervous system

Sensory Division of the Peripheral Nervous System

Sensory information (called stimuli) is gathered from inside and outside of the body. This sensory input is delivered to the central nervous system via the peripheral nerves. Sensory nerve fibres are also called afferent fibres. Sensory information always travels from the peripheral nervous system towards the central nervous system. There are many kinds of sensory information, including pain, pressure, temperature, chemical levels and more. McErlean and Migliozzi (2020) consider the maintenance of body temperature; it is important that body temperature is maintained between 36.5 and 37.5 °C. Temperature receptors in the skin, known as thermoreceptors, detect changes in temperature, as temperature changes have the potential to cause damage to cells and tissues; this information has to be relayed to the central nervous system and if needed, it is acted upon.

Central Nervous System

The central nervous system consists of the brain and spinal cord. The central nervous system processes and integrates sensory information. The information received has to be interpreted, which can either be stored to be dealt with later or can be acted upon immediately with one or more motor responses. For example, the sensation of a temperature change would be received and interpreted by the hypothalamus (a structure of the central nervous system) and an appropriate action would be initiated.

Motor Division of the Peripheral Nervous System

The motor division of the peripheral nervous system always carries impulses away from the central nervous system, usually to effector organs (these respond to signals from the nervous system or hormonal system by producing a specific effect). Motor nerve fibres are also called efferent fibres. There are two types of motor information: motor information to the somatic nervous system or to the autonomic nervous system.

Somatic Nervous System

The somatic nervous system is under voluntary control and the effector (tissue or organ responding to instruction from the central nervous system) is skeletal (voluntary) muscle.

The central nervous system’s response to sensory information may be to activate the somatic nervous system, prompting a voluntary response that involves skeletal muscle movement. For example, if an increase in temperature is detected, then it may require the removal of a coat or the opening of a window. This is the motor response that involves the somatic nervous system. This is a voluntary activity the person has chosen to take.

Autonomic Nervous System

The central nervous system’s response to sensory information may be to activate the autonomic nervous system. This would lead to an involuntary action. The autonomic nervous system is responsible for involuntary motor responses. The effector may be smooth or cardiac muscle (they are both involuntary muscles) or a gland.

In the example of increased temperature, the involuntary response is to lose heat through the skin–so warm blood is directed to the skin when peripheral blood vessels vasodilate. Vasodilatation is an example of an involuntary autonomic nervous system response. The individual cannot control this response.

The autonomic nervous system is further divided into the sympathetic (fight or flight) and the parasympathetic (rest and digest) divisions. A fine balance between both of these divisions is required for the maintenance of homeostasis.

Neurones

The functional unit of the nervous system is the neurone or nerve cell. It has several features in common with other cells, including a nucleus and mitochondria. As a result of its vital role, it is well protected and has some specialist modifications. Two specialist characteristics of neurones are:

• Irritability, in response to a stimulus – the ability to initiate a nerve impulse.
• Conductivity – the ability to conduct an impulse.

Neurones comprise an axon, dendrites and a cell body. Their function is to transmit nerve impulses. Nerve impulses only travel in one direction: from the receptive area – the dendrites – to the cell body and down the length of the axon (see Figure 1.2).

Figure 1.2 Motor neurone

Axons bundled together are known as nerves. Neurones depend on a constant supply of oxygen and glucose. Once the neurones of the brain and spinal cord have matured after birth, they are not replaced or regenerated if they become damaged. Peripheral neurones can regenerate if the cell body is not damaged and the alignment of the neurone has not been disrupted.

Dendrites

These are short branching processes that receive information and conduct it towards the cell body. Their branching processes provide a large surface area for this function. In sensory neurones, dendrites may form a part of the sensory receptors, and in motor neurones, they can form part of the synapse between one neurone and the next.

Cell Body

Most neurone cell bodies are located inside the central nervous system, forming the grey matter. When clusters of cell bodies are grouped together in the central nervous system, they are known as nuclei. Cell bodies located in the peripheral nervous system are called ganglia.

Axons

Each neurone has only one axon conducting information away from the cell body. The axon can branch to form an axon collateral and will also branch at its terminal into many axon terminals (see Figure 1.1). The axon delivers the impulse to another neurone or a gland or a muscle. Axon length can vary significantly from very short to 100 cm long (Marieb and Hoehn 2019).

Myelin Sheath

Peripheral nerve axons and long or large axons are covered in a myelin sheath, a fatty material protecting the neurone and electrically insulating it, speeding up impulse transmission. Within the peripheral nervous system, Schwann cells are wrapped in layers around the neurone from the myelin sheath. The outermost part of the Schwann cell is its plasma membrane, which is called the neurilemma. There is a regular gap (about 1 mm) between adjacent Schwann cells. The gaps are called the nodes of Ranvier. Collateral axons can occur at the node (see Figure 1.2). Some nerve fibres are unmyelinated, which makes nerve impulse transmission significantly slower.

Sensory (Afferent) Nerves

Dendrites of sensory neurones are often sensory receptors; when stimulated, the impulse generated travels towards the spinal cord and brain. There are different types of sensory receptors:

• Special senses.
• Somatic sensory receptors, located in the skin, such as touch, temperature and pain.
• Autonomic nervous system receptors, located throughout the body, such as baroreceptors monitoring blood pressure, chemoreceptors monitoring blood pH and visceral pain receptors.
• Proprioceptors, monitoring muscle movement, stretch and pain.

Motor (Efferent) Nerves

Information from the central nervous system is delivered to the peripheral nervous system via the motor nerves. Information transmitted through a voluntary somatic nerve can cause skeletal muscle contraction or the information may be autonomic in nature, not under voluntary control, and may lead to smooth muscle contraction or release of the products of a gland.

The Action Potential

The nervous system is a vast communicating network sending information from the internal and external environment to the central nervous system and from the central nervous system to the muscles and glands. The way the functional unit, the neurone, achieves this is by the generation...