Last's Anatomy, Regional and Applied PDF

Summary

This book, an anatomy textbook, details human regional anatomy for clinical and surgical purposes. It covers topics from the upper and lower limbs to the thorax, abdomen, head, neck, and spinal column. The book is well-illustrated and includes clinical applications.

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Table of Contents
Cover Image
Front matter
Copyright
Preface to the twelfth edition
Preface to the eleventh edition
Preface to the tenth edition
Acknowledgements
Chapter 1. Introduction to regional anatomy
Part one. Tissues and structures
Part two. Nervous system
Part three. Embryology
Part four. Anatomy of the child
2. Upper limb
Part one. Pectoral girdle
Part two. Shoulder
Part three. Axilla
Part four. Breast
Part five. Anterior compartment of the arm
Part six. Posterior compartment of the arm
Part seven. Anterior compartment of the forearm
Part eight. Posterior compartment of the forearm
Part nine. Wrist and hand
Part ten. Summary of upper limb innervation
Part eleven. Summary of upper limb nerve injuries
Part twelve. Osteology of the upper limb
Chapter 3. Lower limb
Part one. Anterior compartment of the thigh
Part two. Medial compartment of the thigh
Part three. Gluteal region and hip joint
Part four. Posterior compartment of the thigh
Part five. Popliteal fossa and knee joint
Part six. Anterior compartment of the leg
Part seven. Dorsum of the foot
Part eight. Lateral compartment of the leg
Part nine. Posterior compartment of the leg
 Part ten. Sole of the foot
Part eleven. Ankle and foot joints
Part twelve. Summary of lower limb innervation
Part thirteen. Summary of lower limb nerve injuries
Part fourteen. Osteology of the lower limb
Chapter 4. Thorax
Part one. Body wall
Part two. Thoracic wall and diaphragm
Part three. Thoracic cavity
Part four. Superior mediastinum
Part five. Anterior mediastinum
Part six. Middle mediastinum and heart
Part seven. Posterior mediastinum
Part eight. Pleura
Part nine. Lungs
Part ten. Osteology of the thorax
Chapter 5. Abdomen
Part one. Anterior abdominal wall
Part two. Abdominal cavity
Part three. Peritoneum
Part four. Development of the gut
Part five. Vessels and nerves of the gut
Part six. Gastrointestinal tract
Part seven. Liver and biliary tract
Part eight. Pancreas
Part nine. Spleen
Part ten. Posterior abdominal wall
Part eleven. Kidneys, ureters and suprarenal glands
Part twelve. Pelvic cavity
Part thirteen. Rectum
Part fourteen. Urinary bladder and ureters in the pelvis
Part fifteen. Male internal genital organs
Part sixteen. Female internal genital organs and urethra
Part seventeen. Pelvic vessels and nerves
Part eighteen. Perineum
Part nineteen. Male urogenital region
 Part twenty. Female urogenital region
Part twenty-one. Pelvic joints and ligaments
Part twenty-two. Summary of lumbar and sacral plexuses
Chapter 6. Head and neck and spine
Part one. General topography of the neck
Part two. Triangles of the neck
Part three. Prevertebral region
Part four. Root of the neck
Part five. Face
Part six. Scalp
Part seven. Parotid region
Part eight. Infratemporal region
Part nine. Pterygopalatine fossa
Part ten. Nose and paranasal sinuses
Part eleven. Mouth and hard palate
Part twelve. Pharynx and soft palate
Part thirteen. Larynx
Part fourteen. Orbit and eye
Part fifteen. Lymph drainage of head and neck
Part sixteen. Temporomandibular joint
Part seventeen. Ear
Part eighteen. Vertebral column
Part nineteen. Osteology of vertebrae
Part twenty. Cranial cavity and meninges
Part twenty-one. Cranial fossae
Part twenty-two. Vertebral canal
Chapter 7. Central nervous system
Part one. Forebrain
Part two. Brainstem
Part three. Cerebellum
Part four. Spinal cord
Part five. Development of the spinal cord and brainstem nuclei
Part six. Summary of cranial nerves
Part seven. Summary of cranial nerve lesions
Chapter 8. Osteology of the skull and hyoid bone
Part one. Skull
 Part two. Hyoid bone
Biographical notes
Index
Front matter
Last's Anatomy
Commissioning Editor: Timothy Horne, Jeremy Bowes
Development Editor: Sally Davies
Project Manager: Elouise Ball
Design Direction: Charles Gray
Illustration Direction: Bruce Hogarth
Artwork colouring: Ian Ramsden
New artwork: Gillian Oliver
Last's Anatomy
Regional and Applied
Twelfth Edition

Chummy S. Sinnatamby FRCS
Formerly:
Head of Anatomy, Royal College of Surgeons of England
Member of Court of Examiners, Royal College of Surgeons of England
Examiner in Anatomy, Royal College of Surgeons in Ireland
Director of Studies in Anatomy, St Catharine's College and Hughes Hall, Cambridge
External Examiner in Anatomy, University of Cambridge
External Examiner in Anatomy, Trinity College, University of Dublin
Copyright

© 2011 Elsevier Ltd. All rights reserved.
The right of Chummy S. Sinnatamby to be identified as author of this work has been asserted by him in
accordance with the Copyright, Designs and Patents Act 1988.
No part of this publication may be reproduced or transmitted in any form or by any means, electronic
or mechanical, including photocopying, recording, or any information storage and retrieval system,
without permission in writing from the publisher. Details on how to seek permission, further
information about the Publisher's permissions policies and our arrangements with organizations such
as the Copyright Clearance Center and the Copyright Licensing Agency, can be found at our website:
www.elsevier.com/permissions.
This book and the individual contributions contained in it are protected under copyright by the
Publisher (other than as may be noted herein).
First edition 1954
Second edition 1959
Third edition 1963
Fourth edition 1966
Fifth edition 1972
Sixth edition 1978
Seventh edition 1984
Eighth edition 1990
Ninth edition 1994
Tenth edition 1999
Eleventh edition 2006
Twelfth edition 2011
ISBN 978 0 7020 3395 7
International ISBN 978 0 7020 3394 0
British Library Cataloguing in Publication Data
A catalogue record for this book is available from the British Library
Library of Congress Cataloging in Publication Data
A catalog record for this book is available from the Library of Congress

Notices
Knowledge and best practice in this field are constantly changing. As new research and
experience broaden our understanding, changes in research methods, professional practices,
or medical treatment may become necessary.
Practitioners and researchers must always rely on their own experience and knowledge in
evaluating and using any information, methods, compounds, or experiments described herein.
In using such information or methods they should be mindful of their own safety and the safety
of others, including parties for whom they have a professional responsibility.
To the fullest extent of the law, neither the Publisher nor the authors, contributors, or editors,
assume any liability for any injury and/or damage to persons or property as a matter of
products liability, negligence or otherwise, or from any use or operation of any methods,
products, instructions, or ideas contained in the material herein.

Printed in China
Preface to the twelfth edition
For the first time in its publication history all the illustrations in the previous (eleventh) edition of
Last's Anatomy appeared in full colour. This development transformed the illustrations and received
very favourable readership response. In the light of such evaluation the publication of a twelfth
edition has provided the opportunity to augment the illustrations in the book by the inclusion of new
photographs depicting anatomy of clinical, endoscopic and surgical relevance and additional
photographs of prosections. Where necessary the colour, tone, shade and contrast of existing
illustrations have been enhanced. Colour consistency for related structures has been maintained
throughout to ensure ease of cross-reference from one illustration to another.
The text has been wholly reviewed and refinements made where required in the interests of relevance
and readability. The anatomy of surgical approaches has been updated in the light of the continuing
evolution of surgical practice, advances in laparoscopic surgery and the increasing scope of minimal
access procedures. The limited field of vision provided by these latter techniques emphasises the
need for a reliable knowledge of regional anatomy and structural relationships. Eponyms in common
clinical use have been added.
Curricular reforms and changes to surgical training programmes have resulted in a reduction of
anatomy study time and prosection experience for medical students, and in difficulties encountered by
surgical trainees in including anatomy demonstratorships in their career pathways. These
developments have reiterated the continuing need for a regionally arranged, clinically and surgically
relevant anatomy textbook appropriate for both undergraduate study and postgraduate utilisation. The
twelfth edition of Last's Anatomy aims to fulfil this role and be of value to medical students, surgical
trainees and practising surgeons.
Chummy S. Sinnatamby
2010
Preface to the eleventh edition
In response to innumerable requests, all the illustrations in the eleventh edition appear in full colour.
Care has been taken in the choice of and consistency in use of colours for similar structures to
facilitate ease of recognition and enhance the reader's appreciation of the illustrations as a meaningful
adjunct to the text. Some of the illustrations in the first edition of R. J. Last's Anatomy, Regional and
Applied were partly coloured as they appeared in relation to the text. In the seventh edition several
partly coloured illustrations were collectively positioned as plates at the front of the book, but these
were then omitted from subsequent editions. It has been gratifying to be able to restore colour to
Last's Anatomy and extend its application to full colour for all the illustrations as they remain
integrated with the text. Several new illustrations, including clinical photographs, radiographs and
magnetic resonance images, have been added, depicting normal anatomy and lesions that have an
anatomical basis.
The text has been extensively revised with several additions to the clinical and applied aspects of
anatomy and textual changes in the interests of clarity and accuracy.
I am grateful to the many readers, postgraduate and undergraduate, in the UK and abroad, who have
communicated their appreciation of and comments on the tenth edition. Their input has encouraged
and aided the preparation of the eleventh edition.
Chummy S. Sinnatamby
2005
Preface to the tenth edition
In 1954, after seven years of association with postgraduate students of anatomy at the Royal College
of Surgeons of England, R. J. Last published the first edition of Anatomy, Regional and Applied.
Forty-five years later Last's ‘approach to the study of anatomy’ is still of value to undergraduate and
postgraduate students of anatomy. The chief assets of Last's Anatomy were epitomised in its title. In
the assessment and treatment of patients' lesions, clinicians encounter the anatomy of the human body
on a regional basis, and the book presented applied anatomy data regionally arranged. When R. M. H.
McMinn took over the editorship in 1990 he retained ‘the flavour of earlier versions’ and added to
the applied aspects of the subject.
In preparing the tenth edition of Last's Anatomy, I have maintained the overall structure and
arrangement of the book. The entire text, however, has undergone comprehensive revision directed
towards a reduction of its volume and greater clarity. Anatomical detail of no clinical relevance,
phylogenetic discussion and comparative anatomy analogies have been omitted. Within the constraints
of conciseness, clinically correlated topographical anatomy relevant to the expanding frontiers of
diagnostic and surgical procedures has been included. Surface anatomy pertaining to physical
examination is presented. Histological features and developmental aspects have been mentioned only
where they aid the appreciation of the gross form or function of organs and the appearance of the
commoner congenital anomalies.
In keeping with the extensive textual changes in this edition, the illustrations have also undergone
major revision. While several figures which appeared in previous editions but did not significantly
contribute to or enhance the text, have been removed, 97 new illustrations have been added. The latter
include original artwork specially commissioned for this edition, figures reproduced from Gray's
Anatomy (with the kind permission of the publishers) on account of their anatomical accuracy and
clarity, and examples of current diagnostic imaging techniques.
Throughout the preparation of this edition the curricular reforms of undergraduate education and the
restructuring of surgical training have been borne in mind. Time constraints and the interdisciplinary
integration pertaining to both have restricted the study of anatomy. Nevertheless, anatomical
knowledge is required for performing physical examination and diagnostic tests, interpreting their
results and instituting treatment, particularly surgical procedures. In his preface to the second edition
Last stated that: ‘While the text was written chiefly to help students who are revising their anatomy
for an examination, it is particularly gratifying to find that so many clinicians and surgeons have found
the book of value in their practice.’ It is hoped that the clinically relevant anatomical information
presented in the tenth edition, in as concise a form as its content concedes, will be of use to students
preparing for examinations, participants in basic and higher surgical training programmes, and
practising surgeons.
Thirty-seven years ago I purchased a copy of the second edition of Last's Anatomy while preparing
for the primary fellowship examination, in the oral section of which I was examined by Professor Last
himself. Little did I imagine then that it would one day be my privilege to prepare the tenth edition of
Last's Anatomy, thereby maintaining the linkage between the editorship of this publication and the
headship of anatomy at the Royal College of Surgeons of England.
Chummy S. Sinnatamby
1998
Acknowledgements
Appreciative communications from the readership of the eleventh edition of Last's Anatomy have
inspired the publication of another edition of this textbook of regional and applied anatomy. Several
people have contributed to the production of the twelfth edition. In particular I thank Timothy Horne,
lately of Churchill Livingstone and Elsevier Limited, for his encouragement, and Sally Davies,
Elouise Ball and Bruce Hogarth of Elsevier Limited for their assistance with the preparation of the
manuscript and the colouring of figures. I am grateful to Dr Ruchi Sinnatamby of Addenbrooke's
Hospital, Cambridge, for her help with the harvesting of new clinical illustrations. I am greatly
indebted to my wife, Selvi, for her patient support at all times.
Chapter 1. Introduction to regional anatomy
Part one. Tissues and structures
Skin
Skin consists of two components: epidermis and dermis (Fig. 1.1). The surface epithelium of the skin
is the epidermis and is of the keratinized stratified squamous variety. The various skin appendages—
sweat glands, sebaceous glands, hair and nails—are specialized derivatives of this epidermis, which
is ectodermal in origin. The deeper dermis is mesodermal in origin and consists mainly of bundles of
collagen fibres together with some elastic tissue, blood vessels, lymphatics and nerve fibres.

Figure 1.1 Structure of the skin and subcutaneous tissue.

The main factor determining the colour of skin is the degree of pigmentation produced by melanocytes
in the basal layer of the epidermis. Melanocyte numbers are similar in all races. In darker skins the
melanocytes produce more pigment. Melanins vary in colour from yellows to browns and blacks.

Sweat glands are distributed all over the skin except on the tympanic membranes, lip margins,
nipples, inner surface of prepuce, glans penis and labia minora. The greatest concentration is in the
thick skin of the palms and soles, and on the face. Sweat glands are coiled tubular structures that
extend into the dermis and subcutaneous tissue. They are supplied by cholinergic fibres in sympathetic
nerves. Apocrine glands are large, modified sweat glands confined to the axillae, areolae,
periumbilical, genital and perianal regions; their ducts open into hair follicles or directly on to the
skin surface. Their odourless secretion acquires a smell through bacterial action. They enlarge at
puberty and undergo cyclic changes in relation to the menstrual cycle in females. They are supplied by
adrenergic fibres in sympathetic nerves.
Sebaceous glands are small saccular structures in the dermis, where they open into the side of hair
follicles. They also open directly on to the surface of the hairless skin of the lips, nipples, areolae,
inner surface of prepuce, glans penis and labia minora. There are none on the palms or soles. They
are particularly large on the face. Androgens act on these glands which have no motor innervation.
Hair and nails are a hard type of keratin; the keratin of the skin surface is soft keratin. Each hair is
formed from the hair matrix, a region of epidermal cells at the base of the hair follicle, which extends
deeply into the dermis and subcutaneous tissue. As the cells move up inside the tubular epidermal
sheath of the follicle they lose their nuclei and become converted into the hard keratin hair shaft.
Melanocytes in the hair matrix impart pigment to the hair cells. The change with age is due to
decreasing melanocyte activity. An arrector pili muscle attached to the connective tissue of the base
of the follicle passes obliquely to the upper part of the dermis. Contraction of this smooth muscle,
with a sympathetic innervation, makes the hair ‘stand on end’, and squeezes the sebaceous gland that
lies between the muscle and the hair follicle. Hair follicles are richly supplied by sensory nerves.

Nails consist of nail plates lying on nail beds on the dorsum of the terminal segment of fingers and
toes. Compacted keratin-filled squames form the nail plate, which develops from epidermal cells
deep to its proximal part. Here the nail plate is overlapped by the skin of the proximal nail fold.
Blood vessels and sensory nerve endings are plentiful in the nail bed.
The arteries of the skin are derived from a tangential plexus in the subcutaneous connective tissue.
Branches from this plexus form a subpapillary network in the dermis (Fig. 1.1). The veins have a
similar arrangement to the arteries and arteriovenous anastomoses are abundant. From a meshwork of
lymphatic capillaries in the papillary layer of the dermis, lymphatics pass inwards and then run
centrally with the blood vessels. Cutaneous nerves carry afferent somatic fibres, mediating general
sensation, and efferent autonomic (sympathetic) fibres, supplying smooth muscle of blood vessels,
arrector pili muscles and sweat glands. Both free sensory nerve endings and several types of sensory
receptors are present in the skin.
The proportionate surface area of the skin over different regions of the body can be estimated by the
‘rule of nines’ and this is useful in assessing the need for fluid replacement after burns. This rule is a
guide to the size of body parts in relation to the whole: head 9%; upper limb 9%; lower limb 18%;
front of thorax and abdomen 18%; back of thorax and abdomen 18%.
Tension lines of the skin, due to the patterns of arrangement of collagen fibres in the dermis, run as
shown in Figure 1.2. They are often termed relaxed skin tension lines because they coincide with fine
furrows present when the skin is relaxed. Wrinkle lines are caused by the contraction of underlying
muscles; they do not always correspond to tension lines. Flexure lines over joints run parallel to
tension lines. The cleavage lines originally described by Langer in 1861 on cadavers do not entirely
coincide with the lines of greatest tension in the living. Incisions made along skin tension lines heal
with a minimum of scarring (Fig. 1.3).
 Figure 1.2 Tension lines of the skin, front and back.

Figure 1.3 An incision over the medial part of the right breast has crossed tension lines and
resulted in excess scar formation. An incision at the lower margin of the areola along a tension line
has healed with minimal scarring. The tubercles in the areola are due to the presence of large
sebaceous glands.

Superficial fascia
The skin is connected to the underlying bones or deep fascia by a layer of loose areolar connective
tissue. This layer, usually referred to as superficial fascia, is of variable thickness and fat content.
Flat sheets of muscles are also present in some regions. These include both skeletal muscles
(platysma, palmaris brevis) and smooth muscles (subareolar muscle of the nipple, dartos, corrugator
cutis ani). The superficial fascia is most distinct on the lower abdominal wall where it differentiates
into two layers. Strong connective tissue bands traverse the superficial fasica binding the skin to the
underlying aponeurosis of the scalp, palm and sole.

Deep fascia
The limbs and body wall are wrapped in a membrane of fibrous tissue, the deep fascia. It varies
widely in thickness. In the iliotibial tract of the fascia lata, for example, it is very well developed,
while over the rectus sheath and external oblique aponeurosis of the abdominal wall it is so thin as to
be scarcely demonstrable and is usually considered to be absent. In other parts, such as the face and
the ischioanal fossa, it is entirely absent. Where deep fascia passes directly over bone it is always
anchored firmly to the periosteum and the underlying bone is described as being subcutaneous. In the
neck, as well as the investing layer of deep fascia, there are other deeper fascial layers enclosing
neurovascular structures, glands and muscles. Intermuscular septa are laminae of deep fascia which
extend between muscle groups. Transverse thickenings of deep fascia over tendons, attached at their
margins to bones, form retinaculae at the wrists and ankles and fibrous sheaths on the fingers and toes.

Ligaments
Ligaments are composed of dense connective tissue, mainly collagen fibres, the direction of the fibres
being related to the stresses which they undergo. In general ligaments are unstretchable, unless
subjected to prolonged strain. A few ligaments, such as the ligamenta flava between vertebral laminae
and the ligamentum nuchae at the back of the neck, are made of elastic fibres, which enables them to
stretch and regain their original length thereafter. Ligaments are usually attached to bone at their two
ends.

Tendons
Tendons have a similar structure to collagenous ligaments, and attach muscle to bone. They may be
cylindrical, or flattened into sheet-like aponeuroses. Tendons have a blood supply from vessels
which descend from the muscle belly and anastomose with periosteal vessels at the bony attachment.
Synovial sheaths
Where tendons bear heavily on adjacent structures, and especially where they pass around loops or
pulleys of fibrous tissue or bone and change the direction of their pull, they are lubricated by being
provided with a synovial sheath. The parietal layer of the sheath is attached to the surrounding
structures, the visceral layer is fixed to the tendon, and the two layers glide on each other, lubricated
by a thin film of synovial fluid secreted by the lining cells of the sheath. The visceral and parietal
layers join each other at the ends of their extent. Usually they do not enclose the tendon cylindrically;
it is as though the tendon was pushed into the double layers of the closed sheath from one side. In this
way blood vessels can enter the tendon to reinforce the longitudinal anastomosis. In other cases blood
vessels perforate the sheath and raise up a synovial fold like a little mesentery—a vinculum—as in
the flexor tendons of the digits (see Fig. 2.47C, p. 90).

Cartilage
Cartilage is a type of dense connective tissue in which cells are embedded in a firm matrix,
containing fibres and ground substance composed of proteoglycan molecules, water and dissolved
salts. There are three types of cartilage. The most common is hyaline cartilage which has a blue-
white translucent appearance. Costal, nasal, most laryngeal, tracheobronchial, articular cartilage of
typical synovial joints and epiphyseal growth plates of bones are hyaline cartilage.
Fibrocartilage is like white fibrous tissue but contains small islands of cartilage cells and ground
substance between collagen bundles. It is found in intervertebral discs, the labrum of the shoulder and
hip joints, the menisci of the knee joints and at the articular surface of bones which ossify in
membrane (squamous temporal, mandible and clavicle). Both hyaline cartilage and fibrocartilage tend
to calcify and they may even ossify in old age.
Elastic cartilage has a matrix that contains a large number of yellow elastic fibres. It occurs in the
external ear, auditory (Eustachian) tube and epiglottis. Elastic cartilage never calcifies.
Fibrocartilage has a sparse blood supply, but hyaline and elastic cartilage have no capillaries, their
cells being nourished by diffusion through the ground substance.

Muscle
There are three kinds of muscle—skeletal, cardiac and smooth—although the basic histological
classification is into two types: striated and non-striated. This is because both skeletal and cardiac
muscle are striated, a structural characteristic due to the way the filaments of actin and myosin are
arranged. The term striated muscle, however, is usually taken to mean skeletal muscle. Smooth
muscle, also known as visceral muscle, is non-striated. Smooth muscle also contains filaments of
actin and myosin, but they are arranged differently. The terms ‘muscle cell’ and ‘muscle fibre’ are
synonymous. Smooth muscle fibres have a single nucleus, cardiac muscle fibres have one or two
nuclei and skeletal muscle fibres are multinucleated.
Smooth muscle consists of narrow spindle-shaped cells, usually lying parallel. They are capable of
slow but sustained contraction. In tubes that undergo peristalsis they are arranged in longitudinal and
circular fashion (as in the alimentary canal and ureter). In viscera that undergo a mass contraction
without peristalsis (such as urinary bladder and uterus) the fibres are arranged in whorls and spirals
rather than demonstrable layers. Contractile impulses are transmitted from one cell to another at sites
called nexuses or gap junctions, where adjacent cell membranes lie unusually close together.
Innervation is by autonomic nerves.
Cardiac muscle consists of broader, shorter cells that branch. Cardiac muscle is less powerful than
skeletal muscle, but is more resistant to fatigue. Part of the boundary membranes of adjacent cells
make very elaborate interdigitations with one another to increase the surface area for impulse
conduction. The cells are arranged in whorls and spirals; each chamber of the heart empties by mass
contraction. Although the heart has an intrinsic impulse generating and conduction system, the rate and
force of contraction are influenced by autonomic nerves.

Skeletal muscle consists of long, cylindrical non-branching fibres. Individual fibres are surrounded
by a fine network of connective tissue, the endomysium. Parallel groups of fibres are surrounded by
less delicate connective tissue, the perimysium, to form muscle bundles or fasciculi. Thicker
connective tissue, the epimysium, envelops the whole muscle. Neurovascular structures pass along the
sheaths.
The orientation of individual skeletal muscle fibres is either parallel or oblique to the line of pull of
the whole muscle. The range of contraction is long with the former arrangement, while the latter
provides increased force of contraction. Sartorius is an example of a muscle with parallel fibres.
Muscles with an oblique disposition of fibres fall into several patterns:
Unipennate muscles, where all the fibres slope into one side of the tendon, giving a pattern like a
feather split longitudinally (e.g. flexor pollicis longus).
Bipennate muscles, where muscle fibres slope into the two sides of a central tendon, like an
 intact feather (e.g. rectus femoris).
Multipennate muscles, which take the form of a series of bipennate masses lying side by side
(e.g. subscapularis), or of a cylindrical muscle within which a central tendon forms. Into the central
tendon the sloping fibres of the muscle converge from all sides (e.g. tibialis anterior).
The attachment of a muscle, where there is less movement, is generally referred to as its origin, and
the attachment, where there is greater movement, as its insertion. These terms are relative; which end
of the muscle remains immobile and which end moves depends on circumstances and varies with
most muscles. Simple usage of ‘attachment’ for both sites of fixation of a muscle avoids confusion and
inaccuracy.
Movements are the result of the coordinated activity of many muscles, usually assisted or otherwise
by gravity. Bringing the attachments of a muscle (origin and insertion) closer together is what is
conventionally described as the ‘action’ of a muscle (isotonic contraction, shortening it). If this is the
desired movement the muscle is said to be acting as a prime mover, as when biceps is required to
flex the elbow. A muscle producing the opposite of the desired movement—triceps in this example—
is acting as an antagonist; it is relaxing but in a suitably controlled manner to assist the prime mover.
Two other classes of action are described: fixators and synergists. Fixators stabilize one attachment
of a muscle so that the other end may move, e.g. muscles holding the scapula steady are acting as
fixators when deltoid moves the humerus. Synergists prevent unwanted movement; the long flexors of
the fingers pass across the wrist joint before reaching the fingers, and if finger flexion is the required
movement, muscles that extend the wrist act as synergists to stabilize the wrist so that the finger
flexors can act on the fingers. A muscle that acts as a prime mover for one activity can of course act
as an antagonist, fixator or synergist at other times. Muscles can also contract isometrically, with
increase of tension but the length remaining the same, as when the rectus abdominis contracts prior to
an anticipated blow on the abdomen. Many muscles can be seen and felt during contraction, and this is
the usual way of assessing their activity, but sometimes more specialized tests such as electrical
stimulation and electromyography may be required.
Muscles have a rich blood supply. Arteries and veins usually pierce the surface in company with the
motor nerves. From the muscle belly vessels pass on to supply the adjoining tendon. Lymphatics run
back with the arteries to regional lymph nodes.
Embedded among the ordinary skeletal muscle cells are groups of up to about 10 small specialized
muscle fibres that constitute the muscle spindles. The spindle fibres are held together as a group by a
connective tissue capsule and are called intrafusal fibres (lying within a fusiform capsule), in contrast
to ordinary skeletal muscle fibres which are extrafusal. Spindles act as a type of sensory receptor,
transmitting to the central nervous system information on the state of contraction of the muscles in
which they lie.
Skeletal muscle is supplied by somatic nerves through one or more motor branches which also
contain afferent and autonomic fibres. The efferent fibres in spinal nerves are axons of the large α
anterior horn cells of the spinal cord which pass to extrafusal fibres, and axons of the small γ cells
which supply the spindle (intrafusal) fibres. The motor nuclei of cranial nerves provide the axons for
those skeletal muscles supplied by cranial nerves.
The nerves supplying the ocular and facial muscles (third, fourth, sixth and seventh cranial nerves)
contain no sensory fibres. Proprioceptive impulses are conveyed from the muscles by local branches
of the trigeminal nerve. The spinal part of the accessory nerve and the hypoglossal nerve likewise
contains no sensory fibres. Proprioceptive impulses are conveyed from sternoclei-domastoid and
trapezius by branches of the cervical plexus, and from the tongue muscles probably by the lingual
nerve (trigeminal).

Bone
Bone is a type of vascularized dense connective tissue with cells embedded in a matrix composed of
organic materials, mainly collagen fibres, and inorganic salts rich in calcium and phosphate.
Macroscopically, bone exists in two forms: compact and cancellous. Compact bone is hard and
dense, and resembles ivory. It occurs on the surface cortex of bones, being thicker in the shafts of long
bones, and in the surface plates of flat bones. The collagen fibres in the mineralized matrix are
arranged in layers, embedded in which are osteocytes. Most of these lamellae are arranged in
concentric cylinders around vascular channels (Haversian canals), forming Haversian systems or
osteons, which usually lie parallel to each other and to the long axis of the bone. Haversian canals
communicate with the medullary cavity and each other by transversely running Volkmann's canals
containing anastomosing vessels. Cancellous bone consists of a spongework of trabeculae, arranged
not haphazardly but in a very real pattern best adapted to resist the local strains and stresses. If for
any reason there is an alteration in the strain to which cancellous bone is subjected there is a
rearrangement of the trabeculae. The moulding of bone results from the resorption of existing bone by
phagocytic osteoclasts and the deposition of new bone by osteoblasts. Cancellous bone is found in the
interior of bones and at the articular ends of long bones. The organization of cancellous or trabecular
bone is also basically lamellar but in the form of branching and anastomosing curved plates. Blood
vessels do not usually lie within this bony tissue and osteocytes depend on diffusion from adjacent
medullary vessels.
The medullary cavity in long bones and the interstices of cancellous bone are filled with red or
yellow marrow. At birth all the marrow of all the bones is red, active haemopoiesis going on
everywhere. As age advances the red marrow atrophies and is replaced by yellow, fatty marrow,
with no power of haemopoiesis. This change begins in the distal parts of the limbs and gradually
progresses proximally. By young adult life red marrow remains only in the ribs, sternum, vertebrae,
skull bones, girdle bones and the proximal ends of the femur and humerus; these tend to be sites of
deposition of malignant metastases.
The outer surfaces of bones are covered with a thick layer of vascular fibrous tissue, the periosteum,
and the nutrition of the underlying bone substance depends on the integrity of its blood vessels. The
periosteum is osteogenic, its deeper cells differentiating into osteoblasts when required. In the
growing individual new bone is laid down under the periosteum, and even after growth has ceased the
periosteum retains the power to produce new bone when it is needed, e.g. in the repair of fractures.
The periosteum is united to the underlying bone by collagen (Sharpey's) fibres, particularly strongly
over the attachments of tendons and ligaments. Periosteum does not, of course, cover the articulating
surfaces of the bones in synovial joints; it is reflected from the articular margins and blends with the
capsule of the joint.
The single-layered endosteum that lines inner bone surfaces (marrow cavity and vascular canals) is
also osteogenic and contributes to new bone formation.
One or two nutrient arteries enter the shaft of a long bone obliquely and are usually directed away
from the growing end. Within the medullary cavity they divide into ascending and descending
branches. Near the ends of bone they are joined by branches from neighbouring vessels and from
periarticular arterial anastomoses. Cortical bone receives blood supply from the periosteum and from
muscular vessels at their attachments. Veins are numerous and large in the cancellous red marrow
bones (e.g. the basivertebral veins). Lymphatics are present, but scanty; they drain to the regional
lymph nodes of the part.
Subcutaneous periosteum is supplied by the nerves of the overlying skin. In deeper parts the local
nerves, usually the branches to nearby muscles, provide the supply. Periosteum in all parts of the
body is very sensitive. Other nerves, probably vasomotor in function, accompany nutrient vessels into
bone.
Bone develops by two main processes, intramembranous and endochondral ossification (ossification
in membrane and cartilage). In general the bones of the vault of the skull, the face and the clavicle
ossify in membrane, while the long bones of the skeleton ossify in cartilage.
I n intramembranous ossification, osteoblasts simply lay down bone in fibrous tissue; there is no
cartilage precursor. The bones of the skull vault, face and the clavicle develop in this way and the
growth in the thickness of other bones (subperiosteal ossification) is also by intramembranous
ossification.
I n endochondral ossification a pre-existing hyaline cartilage model of the bone is gradually
destroyed and replaced by bone. The majority of the bones of the skeleton, including the long bones,
are formed in this way. The cartilage is not converted into bone; it is destroyed and then replaced by
bone.
During all the years of growth there is constant remodelling with destruction (by osteoclasts) and
replacement (by osteoblasts), whether the original development was intramembranous or
endochondral. Similarly endochondral ossification, subperiosteal ossification and remodelling occurs
in the callus of fracture sites.
The site where bone first forms is the primary centre of ossification, and in long bones is in the
middle of the shaft (diaphysis), the centre first appearing about the eighth week of intrauterine life.
The ends of the bone (epiphyses) remain cartilaginous and only acquire secondary ossification
centres much later, usually after birth. The growing end of the diaphysis is the metaphysis, and the
adjacent epiphyseal cartilage is the epiphyseal plate. When ossification occurs across the epiphyseal
plate, the diaphysis and epiphysis fuse and bone growth ceases. The more actively growing end of a
bone starts to ossify earlier and is the last to fuse with the diaphysis.
In the metaphysis the terminal branches of the nutrient artery of the shaft are end arteries, subject to
the pathological phenomena of embolism and infarction; hence osteomyelitis in the child most
commonly involves the metaphysis. The cartilaginous epiphysis has, like all hyaline cartilage, no
blood supply. As ossification of the cartilaginous epiphysis begins, branches from the periarticular
vascular plexus penetrate to the ossification centre. They have no communication across the
epiphyseal plate with the vessels of the shaft. Not until the epiphyseal plate ossifies, at cessation of
growth, are vascular communications established. Now the metaphysis contains no end arteries and is
not subject to infarction from embolism; therefore osteomyelitis no longer has any particular site of
election in the bone.
Sesamoid bones
Sesame seed-like sesamoid bones are usually associated with certain tendons where they glide over
an adjacent bone. They may be fibrous, cartilaginous or bony nodules, or a mixture of all three, and
their presence is variable. The only constant examples are the patella, which is by far the largest, and
the ones in the tendons of adductor pollicis, flexor pollicis brevis and flexor hallucis brevis. In the
foot they can also occur in the peroneus longus tendon over the cuboid, the tibialis anterior tendon
against the medial cuneiform and the tibialis posterior tendon opposite the head of the talus. A
sesamoid bone in the lateral head of gastrocnemius (the fabella) is not associated with a tendon. The
reasons for the presence of sesamoids are uncertain. Sometimes they appear to be concerned in
altering the line of pull of a tendon (patella in the quadriceps tendon) or with helping to prevent
friction (as in the peroneus longus tendon moving against the cuboid bone).

Joints
Union between bones can be in one of three ways: by fibrous tissue; by cartilage; or by synovial
joints.
Fibrous joints occur where bones are separated only by connective tissue (Fig. 1.4A) and movement
between them is negligible. Examples of fibrous joints are the sutures that unite the bones of the vault
of the skull and the syndesmosis between the lower ends of the tibia and fibula.

Figure 1.4 Fibrous and cartilaginous joints in section: A fibrous joint; B primary cartilaginous
joint; C secondary cartilaginous joint.

Cartilaginous joints are of two varieties, primary and secondary. A primary cartilaginous joint
(synchondrosis) is one where bone and hyaline cartilage meet (Fig. 1.4B). Thus all epiphyses are
primary cartilaginous joints, as are the junctions of ribs with their own costal cartilages. All primary
cartilaginous joints are quite immobile and are very strong. The adjacent bone may fracture, but the
bone–cartilage interface will not separate.

A secondary cartilaginous joint (symphysis) is a union between bones whose articular surfaces are
covered with a thin lamina of hyaline cartilage (Fig. 1.4C). The hyaline laminae are united by
fibrocartilage. There may be a cavity in the fibrocartilage, but it is never lined with synovial
membrane and it contains only tissue fluid. Examples are the pubic symphysis and the joint of the
sternal angle (between the manubrium and the body of the sternum). An intervertebral disc is part of a
secondary cartilaginous joint, but here the cavity in the fibrocartilage contains a gel (p. 423).
A limited amount of movement is possible in secondary cartilaginous joints, depending on the amount
of fibrous tissue within them. All symphyses occur in the midline of the body.
Typical synovial joints, which include all limb joints, are characterized by six features: the bone
ends taking part are covered by hyaline cartilage and surrounded by a capsule enclosing a joint
cavity, the capsule is reinforced externally or internally or both by ligaments, and lined internally by
synovial membrane, and the joint is capable of varying degrees of movement. In atypical synovial
joints the articular surfaces of bone are covered by fibrocartilage.
The synovial membrane lines the capsule and invests all non-articulating surfaces within the joint; it
is attached round the articular margin of each bone. Cells of the membrane secrete a hyaluronic acid
derivative which is responsible for the viscosity of synovial fluid, whose main function is lubrication.
The viscosity varies, becoming thinner with rapid movement and thicker with slow. In normal joints
the fluid is a mere film. The largest joint of all, the knee, only contains about 0.5 mL.
The extent to which the cartilage-covered bone-ends make contact with one another varies with
different positions of the joint. When the surfaces make the maximum possible amount of contact, the
fully congruent joint is said to be close-packed (as in the knee joint in full extension). In this position
the capsule and its reinforcing ligaments are at their tightest. When the surfaces are less congruent (as
in the partly flexed knee), the joint is loose-packed and the capsule looser, at least in part.
Intra-articular fibrocartilages, discs or menisci, in which the fibrous element is predominant, are
found in certain joints. They may be complete, dividing the joint cavity into two, or incomplete. They
occur characteristically in joints in which the congruity between articular surfaces is low, e.g. the
temporomandibular, sternoclavicular and knee joints.
Fatty pads are found in some synovial joints, occupying spaces where bony surfaces are incongruous.
Covered in synovial membrane, they probably promote distribution of synovial fluid. The Haversian
fat pad of the hip joint and the infrapatellar fold and alar folds of the knee joint are examples.

Mucous membranes
A mucous membrane is the lining of an internal body surface that communicates with the exterior
directly or indirectly. This definition must not be taken to imply that all mucous membranes secrete
mucus; many parts of the alimentary and respiratory tracts do, but most of the urinary tract does not.
Mucous membranes consist of two and sometimes three elements: always an epithelium and an
underlying connective tissue layer, the lamina propria, which in much of the alimentary tract contains
a thin third component of smooth muscle, the muscularis mucosae. The whole mucous membrane,
often called ‘mucosa’, usually lies on a further connective tissue layer, the submucous layer or
submucosa. The epithelium of a mucous membrane varies according to the site and functional needs,
e.g. stratified squamous in the mouth, columnar in the intestine, ciliated in the trachea.

Serous membranes
A serous membrane (serosa) is the lining of a closed body cavity—pericardial, pleural and peritoneal
—and consists of connective tissue covered on the surface by a single layer of flattened mesothelial
cells (derived from the mesoderm of the coelomic cavity). The part of the serosa that lines the wall of
the cavity (the parietal layer of pericardium, pleura or peritoneum) is directly continuous with the
same membrane that covers or envelops the mobile viscera within the cavity (the visceral layer). The
peritoneal, pericardial and pleural cavities are potential slit-like spaces between the visceral layer
and the parietal layer. The two layers slide readily on each other, lubricated by a film of tissue fluid.
There are no glands to produce a lubricating secretion. The serous membranes are usually very
adherent to the viscera. The parietal layer is attached to the wall of the containing cavity by loose
areolar tissue and in most places can be stripped away easily.
The parietal layer of all serous membranes is supplied segmentally by spinal nerves. The visceral
layer has an autonomic nerve supply.

Blood vessels
Blood vessels are of three types: capillaries; arteries; and veins.
Capillaries are the smallest vessels. Their walls consist only of flattened endothelial cells.
Capillaries form an anastomotic network in most tissues. Certain structures, such as the cornea of the
eye and hyaline cartilage, are devoid of capillaries.
Arteries conduct blood from the heart to the capillary bed, becoming progressively smaller, and as
they do so, give way to arterioles which connect with the capillaries. Arterial walls have three
layers. The tunica intima is very thin and comprises the endothelial lining, little collagenous
connective tissue and an internal elastic lamina. Surrounding this layer is the tunica media consisting
mainly of elastic connective tissue fibres and smooth muscle in varying amounts. The aorta and major
arteries have a large proportion of elastic tissue which enables them to regain their original diameter
after the expansion that follows cardiac contraction. Smaller arteries have less elastic tissue and more
muscle. The tunica media of arterioles is almost entirely composed of smooth muscle. The outermost
layer of the arterial wall is the tunica adventitia, which has an external elastic lamina surrounded by
collagenous connective tissue.
Veins collect blood from the capillaries. They generally have a thinner wall and a larger diameter
than their corresponding arteries. Veins have the same three layers in their walls as arteries, but a
distinct internal elastic lamina is absent and there is much less muscle in the media. Peripheral limb
veins are often double, as venae comitantes of their arteries. In the proximal parts of limbs venae
comitantes unite into a single large vein. Many veins in the limbs and the neck have valves which
prevent reflux of blood. These valves usually have two cup-shaped cusps formed by an infolding of
the tunica intima. These cusps are apposed to the wall as long as the flow is towards the heart; when
blood flow reverses, the valves close by assuming their cup-shaped form. On the cardiac side of a
valve the vein wall is expanded to form a sinus. In general, there are no valves in the veins of the
thorax and abdomen; testicular veins have valves.

Anastomoses between arteries are either actual or potential. In the former instance arteries meet
end to end, such as the labial branches of the two facial arteries. A potential anastomosis is by
terminal arterioles. Given sufficient time these arterioles can dilate to convey adequate blood, but
with sudden occlusion of a main vessel the anastomosis is inadequate to immediately nourish the
affected part, as in the case of the coronary arteries.
In many cases there is no precapillary anastomosis between adjacent arteries. Such vessels are end-
arteries, and here interruption of arterial flow necessarily results in gangrene or infarction. Examples
are found in the liver, spleen, kidney, lung, medullary branches of the central nervous system, the
retina and the straight branches of the mesenteric arteries.
Arteriovenous anastomoses are short-circuiting channels between terminal arterioles and primary
venules which occur in many parts of the body. They are plentiful in the skin, where they may have a
role in temperature regulation.
Sinusoids are wide capillaries which have a fenestrated or discontinuous endothelium. They are
numerous in the liver, spleen, adrenal medulla and bone marrow.
Blood vessels are innervated by efferent autonomic fibres which regulate the contraction of the
smooth muscle in their walls. These nerves act on muscular arteries and especially on arterioles.
Their main effect is vasoconstriction and increase in vascular tone, mediated by adrenergic
sympathetic fibres. In some areas sympathetic cholinergic fibres inhibit muscle activity and cause
vasodilatation. Circulating hormones and factors such as nitric oxide also act on vessel wall muscle.
On account of the thickness of their walls, large vessels have their own vascular supply through a
network of small vessels, the vasa vasorum.

Lymphatics
Not all the blood entering a part returns by way of veins; much of it becomes tissue fluid and returns
by way of lymphatic vessels. Lymphatic capillaries are simple endothelial tubes. Larger collecting
channels have walls similar to those of veins, but the specific tunics, or layers, are less distinct. They
differ from veins in having many more valves. In general superficial lymphatics (i.e. in subcutaneous
tissues) follow veins, while deep lymphatics follow arteries.
Clinical spread of disease (e.g. infection, neoplasm) by lymphatics does not necessarily follow
strictly anatomical pathways. Lymph nodes may be bypassed by the disease process. If lymphatics
become dilated by obstruction their valves may be separated and reversal of lymph flow can then
occur. Lymphatics communicate with veins freely in many parts of the body; the termination of the
thoracic duct in the neck may be ligated with impunity, for lymph finds its way satisfactorily into more
peripheral venous channels.

Lymphoid tissue
The defence mechanisms of the body include phagocytosis, which is a non-specific engulfing
process, and the immune response, which is a specific reaction to microorganisms and foreign
proteins (antigens). The immune response may occur in two ways: (1) by the humoral antibody
response, with production of antibodies which are protein molecules that circulate in the blood and
attach themselves to the foreign protein so that the combination of antigen and antibody can be
destroyed by phagocytosis; and (2) by the cell-mediated immune response, with the production of
specific cells that circulate in the blood and destroy the antigen or stimulate its phagocytosis. Two
types of lymphocyte produce these reactions: T cells are responsible for cell-mediated immunity and
B cells for humoral antibody production. The B cells become transformed into plasma cells which
produce the antibody molecules (the immunoglobulins: IgG; IgM; IgA; IgE; and IgD).
All lymphocytes arise from common stem cells in bone marrow (in the embryo from yolk sac, liver
and spleen). Some of them circulate to and settle in the thymus, where they proliferate. After release
into the bloodstream as T cells they colonize the spleen, lymph nodes and lymphoid follicles at other
sites by passing through the postcapillary venules of those structures. Other stem cells become B cells
and colonize lymphoid follicles without passing through the thymus. The T cells are so named because
they depend on the thymus for their development; cell-mediated immunity thus depends on this organ.
The B cells acquire their name from the bursa of Fabricius in birds, for it was in chickens that this
organ (a diverticulum of the cloaca) was first found to be the source of humoral antibodies. The main
types of T cell are cytotoxic T, helper T and regulatory T cells. B cells can either form plasma cells
or become B memory cells.
The lymphoid organs consist of the thymus, lymph nodes and spleen. All are encapsulated and have
an internal connective tissue framework to support the cellular elements. In all except the thymus the
characteristic structural feature is the lymphoid nodule or follicle, which is typically a spherical
collection of lymphocytes with a pale central area, the germinal centre. Unencapsulated lymphoid
tissue occurs in mucosa-associated lymphoid tissue (MALT) in the mucosa and submucosa of the
alimentary, respiratory and genitourinary tracts. Gut-associated lymphoid tissue (GALT) and
bronchus-associated lymphoid tissue (BALT) are categories of MALT. Waldeyer's peripharyngeal
lymphoid ring of tonsils (palatine, lingual, nasopharyngeal and tubal) and Peyer's patches in the ileum
are areas of organized mucosa-associated lymphoid tissue (O-MALT). The overlying epithelium of
these sites is able to sample antigens in the lumen and translocate them to the underlying lymphoid
aggregation.

In the thymus the lymphocytes are not concentrated in rounded follicles but form a continuous dense
band of tissue at the outer region or cortex of the lobules into which the organ is divided. The inner
(paler) regions of the lobules form the medulla which has fewer lymphocytes and contains the
characteristic thymic corpuscles (of Hassall); these are remnants of the epithelium of the third
pharyngeal pouches from which the thymus developed.
In a typical lymph node the rounded follicles of lymphocytes are concentrated at the periphery
(cortex). Lymphocytes, not collected into follicles, are also present in the paracortical areas and
medullary region. B lymphocytes are found in the follicles and medulla; T lymphocytes in the
paracortical areas and in the cortex between follicles. Several afferent lymph vessels enter through
the capsule of the node and open into the subcapsular sinus. From here radial cortical sinuses drain to
medullary sinuses which are confluent with the efferent vessel draining the node at the hilum, where
blood vessels enter and leave. The thymus, spleen and the O-MALT aggregations, such as the tonsils,
do not have afferent lymphatics.
The (palatine and pharyngeal) tonsils possess lymphoid follicles similar to those of lymph nodes, but
while the nodes have a capsule of connective tissue the tonsils have, on their inner surfaces, a
covering of mucous membrane that dips down deeply to form the tonsillar crypts.

The lymphoid follicles of the spleen are found in its white pulp, which is scattered in the red pulp that
constitutes most of the substance of the spleen and contains large numbers of venous sinuses. In the
white pulp T lymphocytes form periarteriolar sheaths. The sheaths are enlarged in places by lymphoid
follicles with B lymphocytes in the germinal centres. These follicles are visible to the naked eye on
the cut surface of the spleen as whitish nodules up to 1 mm in diameter.
Apart from lymphocytes, all lymphoid organs and organized lymphoid tissue contain macrophages,
which are part of the mononuclear phagocyte system of the body.
Part two. Nervous system
The nervous system is divided into the central nervous system, which consists of the brain and
spinal cord, and the peripheral nervous system composed of cranial and spinal nerves and their
associated ganglia. The central and peripheral parts each have somatic and autonomic components;
the somatic are concerned with the innervation of skeletal muscle (along efferent pathways) and the
transmission of sensory information (along afferent pathways), and the autonomic are concerned with
the control of cardiac muscle, smooth muscle and glands (also involving efferent and afferent
pathways). The term autonomic nervous system is applied collectively to all autonomic components.

Neurons and nerves
The structural and functional unit of the nervous system is the nerve cell or neuron. It consists of a
cell body containing the nucleus, and a variable number of processes commonly called nerve fibres.
A single cytoplasmic process, the axon (often very long), conducts nerve impulses away from the cell
body, and may give off many collaterals and terminal branches to many different target cells. Other
multiple cytoplasmic processes, the dendrites (usually very short), expand the surface area of the cell
body for the reception of stimuli.
Pathways are established in the nervous system by communications between neurons at synapses,
which are sites on the cell body or its processes where chemical transmitters enable nerve impulses
to be handed on from one neuron to another. Transmission between neurons and cells outside the
nervous system, for example muscle cells (neuromuscular junctions), is also effected by neuro-
transmitters. The small number of ‘classic’ transmitters such as acetylcholine and noradrenaline
(norepinephrine) has been vastly supplemented in recent years by many substances. These include
monoamines, amino acids, nitric oxide and neuropeptides.
Cell bodies with similar function show a great tendency to group themselves together, forming nuclei
within the central nervous system and ganglia outside it. Similarly processes from such aggregations
of cell bodies tend to run together in bundles, forming tracts within the central nervous system and
nerves outside the brain and spinal cord.
Apart from neurons the nervous system contains other cells collectively known as neuroglial cells
(neuroglia or glia), which have supporting and other functions but which do not have the property of
excitability or conductivity possessed by neurons. The main types of neuroglial cell are astrocytes
and oligodendrocytes, which like neurons are developed from ectoderm of the neural tube. A third
type of neuroglial cell is the microglial cell (microglia) which is the phagocytic cell of the nervous
system, corresponding to the macrophage of connective tissue, and is derived from mesoderm.
Nerve fibres may be myelinated or unmyelinated. In the central nervous system myelin is formed by
oligo-dendrocytes, and in peripheral nerves by Schwann cells (neurolemmocytes). In myelinated
fibres, the regions where longitudinally adjacent Schwann cells or oligodendrocyte processes join
one another are the nodes (of Ranvier). The white matter of the nervous system is essentially a mass
of nerve fibres and is so called because of the general pale appearance imparted by the fatty myelin,
in contrast to grey matter which is darker and consists essentially of cell bodies.
Peripheral nerve fibres have been classified in relation to their conduction velocity, which is
generally proportional to size, and function:
Group A—Up to 20 μm diameter, subdivided into:
α:12–20 μm. Motor and proprioception (Ia and Ib)
β:5–12 μm. Touch, pressure and proprioception (II)
γ:5–12 μm. Fusimotor to muscle spindles (II)
δ:1–15 μm. Touch, pain and temperature (III)
Group B—Up to 3 μm diameter. Myelinated. Preganglionic autonomic
Group C—Up to 2 μm diameter. Unmyelinated. Postganglionic autonomic, and touch and pain
(IV).
The widest fibres tend to conduct most rapidly. Unfortunately, as can be seen from the above, it is not
possible to make a precise prediction of function from mere size. Thus the largest myelinated fibres
may be motor or proprioceptive and the smallest, whether myelinated or unmyelinated, are autonomic
or sensory.
Spinal nerves
There are 31 pairs of spinal nerves: 8 cervical, 12 thoracic, 5 lumbar, 5 sacral and 1 coccygeal. Each
spinal nerve is formed by the union of an anterior (ventral) and a posterior (dorsal) root which are
attached to the side of the spinal cord by little rootlets. The union takes place within the intervertebral
foramen through which the nerve emerges immediately distal to the swelling on the posterior root, the
posterior root ganglion; most of these are also within the foramen. The anterior root of every spinal
nerve contains motor (efferent) fibres for skeletal muscle; those from T1 to L2 inclusive and from S2
to S4 also contain autonomic fibres. The anterior root also contains a small number of unmyelinated
afferent pain fibres which have ‘doubled back’ from their cells of origin in the posterior root ganglion
to enter the spinal cord by the anterior root instead of by the posterior root. The posterior root of
every nerve contains sensory (afferent) fibres whose cell bodies are in the posterior root ganglion.
These are unipolar neurons, having a single process that bifurcates to pass to peripheral receptors and
the central nervous system. Unlike in autonomic ganglia there are no synapses in posterior root
ganglia.
Immediately after its formation the mixed spinal nerve divides into a larger anterior and a smaller
posterior ramus. The great nerve plexuses—cervical, brachial, lumbar and sacral—are formed from
anterior rami; posterior rami do not form plexuses.
Connective tissue binds the fibres of spinal nerves together to form the single nerve. Delicate loose
connective tissue, the endoneurium, lies between individual fibres. Rounded bundles of fibres, or
fascicles, are surrounded by the perineurium, a condensed layer of collagenous connective tissue.
Fascicles are bound together into a single nerve by a layer of loose but thicker connective tissue, the
epineurium. In the largest nerve, the sciatic, only about 20% of the cross-sectional area is nerve, so
80% is connective tissue, but in smaller nerves the amount of neural tissue is proportionally greater.
The larger nerves have their own nerves, the nervi nervorum, in their connective tissue coverings.
Peripheral nerve trunks in the limbs are supplied by branches from local arteries. The sciatic nerve in
the buttock and the median nerve at the elbow each have a large branch from the inferior gluteal and
common interosseous arteries respectively. Elsewhere, however, regional arteries supply nerves by a
series of longitudinal branches which anastomose freely within the epineurium, so that nerves can be
displaced widely from their beds without risk to their blood supply.

General principles of nerve supply
Once the nerve supply to a part is established in the embryo it never alters thereafter, unlike the
vascular supply. However far a structure may migrate in the devel-oping fetus it always drags its
nerve with it. Conversely, the nerve supply to an adult structure affords visible evidence of its
embryonic origin.
Skeletal muscles are innervated from motor neuron ‘pools’—groups of motor nerve cell bodies in
certain cranial nerve nuclei of the brainstem and anterior horns of the spinal cord. The pool supplying
any one muscle overlaps the pools of another, e.g. the anterior horn cells of spinal cord segments C5
and C6 that supply deltoid are intermixed with cells of the same segments supplying subscapularis
and other muscles. The only exceptions to the overlapping of neuronal pools are the brainstem nuclei
of the fourth and sixth cranial nerves, as they are the only motor nerve cell groups supplying only one
muscle (superior oblique and lateral rectus of the eye respectively).

Nerve supply of the body wall
The body wall is supplied segmentally by spinal nerves (Fig. 1.5). The posterior rami pass
backwards and supply the extensor muscles of the vertebral column and skull, and to a varying extent
the skin that overlies them. The anterior rami supply all other muscles of the trunk and limbs and the
skin at the sides and front of the neck and body.

Figure 1.5 Course of a typical intercostal nerve along the neurovascular plane of the body wall,
between the middle and innermost of the three muscle layers.

Posterior rami
In the trunk, all the muscles of the erector spinae and transversospinalis groups that lie deep to the
thoracolumbar fascia, and the levator costae muscles of the thorax are supplied by the posterior rami
of spinal nerves (Fig. 1.6). In the neck, splenius and all muscles deep to it are similarly supplied.

Figure 1.6 Distribution of posterior rami. On the right, the cutaneous distribution is shown (medial
branches down to T6, to clear the scapula, and lateral branches below this); the stippled areas of
skin are supplied by anterior rami. On the left, the muscular distribution is shown, to erector spinae
and to splenius and the muscles deep to it.

Each posterior ramus divides into a medial and a lateral branch (Fig. 1.5). Both branches of the
posterior rami supply muscle, but only one branch, either medial or lateral, reaches the skin. In the
upper half of the thorax the medial branches, and in the rest of the body the lateral branches, of the
posterior rami provide the cutaneous branches (Fig. 1.6).
C1 has no cutaneous branch, and the posterior rami of the lower two nerves in the cervical and
lumbar regions of the cord likewise fail to reach the skin. All 12 thoracic and five sacral nerves reach
the skin. No posterior ramus ever supplies skin or muscle of a limb.
Anterior rami
The anterior rami supply the prevertebral flexor muscles segmentally by separate branches from each
nerve (e.g. longus capitis and colli, scalene muscles, psoas, quadratus lumborum, piriformis). The
anterior rami of the lower four cervical and the first thoracic nerves supply muscles in the upper limb
via the brachial plexus. The anterior rami of the 12 thoracic nerves and L1 supply the muscles of the
body wall segmentally. Each intercostal nerve supplies the muscles of its intercostal space, and the
lower six nerves pass beyond the costal margin to supply the muscles of the anterior abdominal wall.
The first lumbar nerve (iliohypogastric and ilioinguinal nerves) is the lowest spinal nerve to supply
the anterior abdominal wall. Muscles supplied by anterior rami below L1 are no longer in the body
wall; they have migrated into the lower limb.
C2, 3 and 4 supply skin in the neck by branches of the cervical plexus. C5, 6, 7 and 8 and T1 supply
skin of the upper limb via the brachial plexus.
In the trunk the skin is supplied in strips or zones in regular sequence from T2 to L1 inclusive. The
intercostal nerves each have a lateral branch to supply the sides and an anterior terminal branch to
supply the front of the body wall (Fig. 1.5). The lower six thoracic nerves pass beyond the costal
margin obliquely downwards to supply the skin of the abdominal wall (Fig. 1.7).

Figure 1.7 Overlap of dermatomes on the body wall. On the right side, the supraclavicular and
thoracic nerves are shown. On the left, the anterior axial line is indicated; this marks the boundary
on the chest wall between skin supplied by the cervical plexus and by intercostal nerves. Adjacent
dermatomes overlap and thereby, for instance, the dermatomes of T6 and T8 meet each other,
completely covering T7, explaining why division of a single intercostal nerve does not give rise to
anaesthesia on the trunk.

Neurovascular plane
The nerves of the body wall, accompanied by their segmental arteries and veins, spiral around the
walls of the thorax and abdomen in a plane between the middle and deepest of the three muscle layers
(see p. 181 and Fig. 1.5). In this neurovascular plane the nerves lie below the arteries as they run
around the body wall. But the nerves cross the arteries posteriorly alongside the vertebral column and
again anteriorly near the ventral midline, and at these points of crossing the nerve always lies nearer
the skin. The spinal cord lies nearer the surface of the body than the aorta, and as a result the spinal
nerve makes a circle that surrounds the smaller arterial circle. The arterial circle is made of the aorta
with its intercostal and lumbar arteries, completed in front by the internal thoracic and the superior
and inferior epigastric arteries. As a part of the same arterial pattern the vertebral arteries pass up to
the cranial cavity. The spinal nerves, as they emerge from the intervertebral foramina, pass laterally
behind the vertebral artery in the neck, behind the posterior intercostal arteries in the thorax, behind
the lumbar arteries in the abdomen and behind the lateral sacral arteries in the pelvis. The anterior
terminal branches of the spinal nerves similarly pass in front of the internal thoracic and the superior
and inferior epigastric arteries (Fig. 1.5).
The sympathetic trunk runs vertically within the arterial circle. From the base of the skull to the
coccyx the sympathetic trunk lies anterior to the segmental vessels (vertebral, posterior intercostal,
lumbar and lateral sacral arteries).
Sympathetic fibres
Every spinal nerve without exception, from C1 to the coccygeal, carries postganglionic
(unmyelinated, grey) sympathetic fibres which ‘hitch-hike’ along the nerves and accompany all their
branches. They leave the spinal nerve only at the site of their peripheral destination. They are in the
main vasoconstrictor in function, though some go to sweat glands in the skin (sudomotor) and to the
arrectores pilorum muscles of the hair roots (pilomotor). In this way the sympathetic system
innervates the whole body wall and all four limbs. This is chiefly for the function of temperature
regulation. The visceral branches of the sympathetic system have a different manner of distribution
(see p. 19).

Nerve supply of limbs
The body wall has been seen to be supplied segmentally by spinal nerves (Fig. 1.5). A longitudinal
strip posteriorly is supplied by posterior rami, a lateral strip by the lateral branches of the anterior
rami, and a ventral strip by the anterior terminal branches of the anterior rami. In the fetus the limb
buds grow out from the lateral strip supplied by the lateral branches of the anterior rami and these
lateral branches, by their anterior and posterior divisions, form the plexuses for supply of the muscles
and skin of the limbs. The posterior divisions supply extensor muscles and the anterior divisions
supply flexor muscles. Both divisions supply skin of the limbs.
Each limb consists of a flexor and an extensor compartment, which meet at the preaxial and postaxial
borders of the limb. These borders are marked out approximately by veins. In the upper limb the
cephalic vein lies at the preaxial and the basilic vein at the postaxial border. In the lower limb,
extension and medial rotation, which replace the early fetal position of flexion, have complicated the
picture. The great saphenous vein marks out the preaxial and the small saphenous vein the postaxial
borders of the limb.
The spinal nerves entering into a limb plexus come from enlarged parts of the cord, the cervical
enlargement for the brachial plexus and the lumbar enlargement for the lumbar and sacral plexuses.
The enlargements are produced by the greatly increased number of motor neurons in the anterior horns
at these levels (see p. 487).
On account of the way nerve fibres become combined and rearranged in plexuses, any one spinal
nerve can contribute to more than one peripheral nerve and peripheral nerves can receive fibres from
more than one spinal nerve. It follows that the area of skin supplied by any one spinal nerve or spinal
cord segment is not the same as the area supplied by a peripheral spinal nerve. Two kinds of skin
maps or charts are therefore required, one showing segmental innervation and the other showing
peripheral nerves. The segmental supplies are reviewed below; the peripheral nerves of the upper
and lower limbs are summarized on pages 91 and 162.

Segmental innervation of the skin
The area of skin supplied by a single spinal nerve is called a dermatome. On the trunk, adjacent
dermatomes overlap considerably, so that interruption of a single spinal nerve produces no
anaesthesia (Fig. 1.7); the same applies to the limbs, except at the axial lines. The line of junction of
two dermatomes supplied from discontinuous spinal levels is demarcated by an axial line, and such
axial lines extend from the trunk on to the limbs. In the upper limb (Fig. 1.8) the anterior axial line
runs from the sternal angle across the second costal cartilage and down the front of the limb almost to
the wrist. The dermatomes lie in orderly numerical sequence when traced distally down the front and
proximally up the back of the anterior axial line (C5, 6, 7, 8 and T1) and these dermatomes are
supplied by the nerves of the brachial plexus. In addition, skin has been ‘borrowed’ from the neck and
trunk to clothe the proximal part of the limb (C4 over the deltoid muscle, T2 for the axilla).

Figure 1.8 Approximate dermatomes and axial lines of the right upper limb. See text for
explanation.

Considerable distortion occurs to the dermatome pattern of the lower limb (Fig. 1.9) for two reasons.
Firstly the limb, from the fetal position of flexion, is medially rotated and extended, so that the
anterior axial line is caused to spiral from the root of the penis (clitoris) across the front of the
scrotum (labium majus) around to the back of the thigh and calf in the midline almost to the heel.
Secondly, a good deal of skin is ‘borrowed’ from the trunk on the cranial side (from T12, L1, 2 and
3). As in the upper limb, the dermatomes can be traced in numerical sequence down in front and up
behind the anterior axial line (L1, 2, 3, 4, 5 and S1, 2, 3).

Figure 1.9 Approximate dermatomes and axial lines of the right lower limb. See text for
explanation.
A practical application of the anterior axial line arises in spinal analgesia. A ‘low spinal’ (caudal)
anaesthetic anaesthetizes the skin of the posterior two-thirds of the scrotum or labium majus (S3), but
to anaesthetize the anterior one-third of the scrotum or labium L1 must be involved, an additional
seven spinal segments higher up.
It must be remembered that a single chart cannot indicate individual variations or the differing
findings of several groups of investigators, and that such charts are a compromise between the
maximal and minimal segmental areas which experience has shown can occur. Original charts, such
as those made by Sherrington, Head and Foerster, are being modified by the continuing accumulation
of new information. Thus T1 nerve, for example, is not usually considered to supply any thoracic skin
but has sometimes been considered to do so, and L5 and S1 have been reported to extend to buttock
skin although this is not usually expected. It is probable that posterior axial lines do not exist, but
evidence for anterior axial lines is more convincing. Difficulty in investigation arises in the main
from the blurring of patterns due to overlap from adjacent dermatomes. A chart of dermatomes must
therefore be interpreted with flexibility. The following summary offers selected guidelines that are
clinically useful:
C1 No skin supply
C2 Occipital region, posterior neck and skin over parotid
C3 Neck
C4 Infraclavicular region (to manubriosternal junction), shoulder and above scapular spine
C5 Lateral arm
C6 Lateral forearm and thumb
C7 Middle fingers
C8 Little finger and distal medial forearm
T1 Medial arm above and below elbow
T2 Medial arm, axilla and thorax
T3 Thorax and occasional extension to axilla
T4 Nipple
T7 Subcostal angle
T8 Rib margin
T10 Umbilicus
T12 Lower abdomen, upper buttock
L1 Suprapubic and inguinal regions, penis, anterior scrotum (labia), upper buttock
L2 Anterior thigh, upper buttock
L3 Anterior and medial thigh and knee
L4 Medial leg, medial ankle and side of foot
L5 Lateral leg, dorsum of foot, medial sole
S1 Lateral ankle, lateral side of dorsum and sole
S2 Posterior leg, posterior thigh, buttock, penis
S3 Sitting area of buttock, posterior scrotum (labia)
S4 Perianal
S5 and Co Behind anus and over coccyx.

Segmental innervation of muscles
Most muscles are supplied equally from two adjacent segments of the spinal cord. Muscles sharing a
common primary action on a joint irrespective of their anatomical situation are all supplied by the
same (usually two) segments. Their opponents, sharing the opposite action, are likewise all supplied
by the same (usually two) segments and these segments usually run in numerical sequence with the
former. For a joint one segment more distal in the limb the spinal centre lies en bloc one segment
lower in the cord.
Thus there are in effect spinal centres for joint movements, and these centres tend to occupy
continuous segments in the cord. The upper one or two segments innervate one movement, and the
lower one or two innervate the opposite movement (although sometimes the same segment may
innervate both movements, but of course from different anterior horn cells). Thus the spinal centre for
the elbow is in C5, 6, 7, 8 segments; biceps, brachialis and brachioradialis (the prime flexors of the
elbow) are supplied by C5, 6 and triceps (the prime extensor of the elbow) is supplied by C7, 8.
The segments mainly responsible for the various limb joint movements are summarized in Figures
1.10 and 1.11. Flexion/extension at the hip, knee and ankle are the easiest to remember, for each
movement involves two segments in logical sequence for each joint, and for each more distal joint the

segments concerned are one segment lower:

Figure 1.10 Segmental innervation of movements of the lower limb.
 Figure 1.11 Segmental innervation of movements of the upper limb.

The above pattern enables the segmental innervation of a muscle to be determined, e.g.:
iliacus (flexes hip) L2, 3
biceps femoris (flexes knee) L5, S1
soleus (plantarflexes ankle) S1, 2.
The above are simple flexion–extension movements and, indeed, cover all knee- and ankle-moving
muscles. At the hip, however, movements other than flexion and extension are possible, but all are
innervated by the same four segments. Thus:
adduction or medial rotation (same as flexion) L2, 3
abduction or lateral rotation (same as extension) L4, 5.
For inversion and eversion of the foot the formulae are:
invert foot L4
evert foot L5, S1.
Tibialis anterior and tibialis posterior invert the foot and both are innervated by L4 segment. Tibialis
anterior is also a dorsiflexor and L4, 5 (from the formula already given for dorsiflexion) is its correct
segmental supply. Tibialis posterior, however, lies deep among the plantar flexors of the ankle (S1,
2), but its main action is inversion of the foot (it is the principal invertor) and, although it assists
plantar flexion, its segmental innervation is L4, 5.
The upper limb movements, with the segments involved (Fig. 1.11), are as follows:

Shoulder Abduct and laterally rotate C5
Adduct and medially rotate C6, 7, 8
Elbow Flex C5, 6
 Extend C7, 8
Forearm Supinate C6
Pronate C7, 8
Wrist only Flex C6, 7
Extend C6, 7
Fingers and thumb Flex C7, 8
(long tendons) Extend C7, 8
Hand T1.
(intrinsic muscles)

In the upper limb the two-and-two segment pattern is not as regular as in the lower limb, probably
because in the upper limb much more precise movements are constantly being employed, and the
spinal centres have broken up into separate nuclei to control these. Thus, below the elbow the plan
does not conform to the basic pattern of four spinal segments for each joint. Flexion and extension
share the same two segments; these are C6, 7 for the wrist and C7, 8 for the digits. But the rule holds
that the more distal joints are innervated from lower centres in the cord.
As a guide to the level of spinal cord injury it is useful to be aware of a muscle and a movement for
which a particular spinal cord segment is mainly responsible:
C4 Diaphragm. Respiration
C5 Deltoid. Abduction of the shoulder
C6 Biceps. Flexion of the elbow. Biceps jerk (see below)
C7 Triceps, Extension of the elbow. Triceps jerk (see below)
C8 Flexor digitorum profundus and extensor digitorum. Finger flexion and extension
T1 Abductor pollicis brevis representing small hand muscles. Abduction of the thumb
T7–12 Anterior abdominal wall muscles. Guarding. Abdominal reflex (see below)
L1 Lowest fibres of internal oblique and transversus abdominis. Guarding
L2 Psoas major. Flexion of the hip
L3 Quadriceps femoris. Extension of the knee. Knee jerk (see below)
L4 Tibialis anterior and posterior. Inversion of the foot
L5 Extensor hallucis longus. Extension of the great toe
S1 Gastrocnemius. Plantarflexion of the foot. Ankle jerk (see below)
S2 Small muscles of the foot
S3 Perineal muscles. Bladder (parasympathetic). Anal reflex (see below).

It is important to note that the term ‘root’ as used in root injuries may be taken to mean either the
nerve root proper, i.e. from the side of the spinal cord to the intervertebral foramen, or the roots of the
plexuses, i.e. anterior rami distal to the foramen. In lesions of the nerve roots proper, sweating in the
distribution of the appropriate nerves is normal, but in more peripheral lesions sweating is reduced,
because the postganglionic sympathetic fibres from the sympathetic trunk join the roots of plexuses
distal to the nerve roots proper (Fig. 1.12C).
 Figure 1.12 Examples of spinal reflex pathways: A the two neurons of a stretch reflex (tendon
jerk), which is monosynaptic; B a multisynaptic reflex arc—only one interneuron is shown but
there may be several; C the three neurons of a sympathetic reflex, the body of the preganglionic
cell is in the lateral horn of the spinal cord and that of the postganglionic cell in a sympathetic
ganglion (the preganglionic fibre runs in the white ramus communicans, the more distal connection
of the ganglion, and the postganglionic fibre in the proximal grey ramus); D the fusimotor neuron
loop; the γ efferent neuron, under the influence of higher centres, stimulates the muscle spindle
from which afferent fibres pass back to the spinal cord to synapse with the α motor neuron.

Spinal reflexes
What is commonly called the ‘knee jerk’ and similar tendon reflexes are typical examples of spinal
myotatic or stretch reflexes (deep tendon reflexes). They illustrate the simplest kind of reflex
pathway and involve only two neurons with one synapse (monosynaptic reflex arc, Fig. 1.12A);
indeed the tendon reflexes are the only examples of monosynaptic reflex arcs, for all other reflexes
involve two or more synapses (multisynaptic, Fig. 1.12B, C).
Tapping the tendon momentarily stretches the spindles within the muscle and this stimulates the
afferent (Ia) fibres of the nerve endings surrounding the intrafusal fibres, which pass into the spinal
cord by the posterior nerve root. These afferents synapse directly with the α motor neurons of the
anterior horn whose axons form the efferent side of the arc, so causing the extrafusal fibres to contract
and produce the ‘jerk’ at the joint.
For most practical purposes the segments mainly concerned with the reflexes most commonly tested
may be taken as: biceps jerk—C6; triceps jerk—C7; knee jerk—L3; ankle jerk—S1.
Diminution or absence of the jerk usually indicates some kind of interruption of the arc or muscular
defect, but exaggeration of the tendon reflexes is taken as evidence of an upper motor neuron lesion
due to alterations in the supraspinal control of the anterior horn cells which are rendered unduly
excitable. In this case the γ motor neurons of the anterior horn are stimulated by such fibres as the
reticulospinal and vestibulospinal. The pathway (Fig. 1.12D) is from the γ motor neuron to the
intrafusal muscle fibres of the spindle, then from the afferent fibres of the spindle to the α motor
neuron and so to the extrafusal fibres. This is the γ reflex loop or fusimotor neuron loop.
In addition to the above deep tendon reflexes, there are superficial skin reflexes which are
multisynaptic. Those most commonly tested are the plantar, abdominal and anal reflexes.
Firm stroking of the lateral surface of the sole of the foot (as with the end of a key) to elicit the
plantar reflex normally causes plantarflexion of the great toe and probably of the other toes as well.
Extension of the great toe—the extensor response (Babinski's sign)—indicates an upper motor
neuron lesion. In infants under 1 year old the extensor response is the normal response; only with
myelination of the corticospinal tracts during the second year does the normal plantar reflex become
flexor.

The abdominal reflex is elicited by lightly stroking across each quadrant of the anterior abdominal
wall. Normally there is contraction of the underlying muscles, but the reflexes are absent in upper
motor neuron lesions. Patients with paraplegia who are lying down may exhibit Beevor's sign: when
trying to lift the shoulders, the umbilicus is displaced upwards, due to weakness of the muscles below
the umbilicus.
The anal reflex (‘anal wink’) is a visible contraction of the external anal sphincter following
pinprick of the perianal skin and depends on intact sacral segments of the cord (mainly S3).

Autonomic nervous system
The motor part of the somatic nervous system is concerned with the innervation of skeletal muscle.
The cell bodies are either in the motor nuclei of cranial nerves or the anterior horn cells of the spinal
cord, and the nerve fibres which leave the central nervous system run uninterruptedly to the muscles,
ending as motor endplates on the muscle fibres. The motor part of the autonomic nervous system is
concerned with the innervation of cardiac and smooth muscle and glands, and the great difference
between this and the somatic system is that the pathway from nerve cells in the central nervous system
to the target organ is interrupted by synapses in a ganglion. There are thus two sets of neurons, which
are logically called preganglionic and postganglionic. The preganglionic cell bodies are always
within the central nervous system. If sympathetic, they are in the lateral horn cells of all the thoracic
and the upper two lumbar segments of the spinal cord; this is the thoracolumbar part of the autonomic
nervous system (the ‘thoracolumbar outflow’). If parasympathetic, they are in certain cranial nerve
nuclei and in lateral horn cells of sacral segments of the spinal cord; this is the craniosacral part of
the autonomic nervous system (the ‘craniosacral outflow’).
The postganglionic cell bodies are in ganglia in the peripheral nervous system. If sympathetic, the
ganglia are either in the sympathetic trunk or in autonomic plexuses situated in the abdomen and
pelvis (such as the coeliac ganglia). If parasympathetic, the ganglia are usually within the walls of the
viscera concerned, while in the head there are four ganglia which are some little distance from the
structures innervated.
Sympathetic nervous system
Having reached a sympathetic trunk ganglion, the incoming preganglionic fibres have one of three
possible synaptic alternatives. The most common is for them to synapse with cell bodies in a trunk
ganglion, either in the one they entered (Fig. 1.13A) or to run up or down the trunk to some other trunk
ganglion. The second alternative is to leave the trunk ganglion without synapsing and to pass to a
ganglion in an autonomic plexus for synapse (Fig. 1.13B). The third possibility (which applies only to
a small number of fibres) is that they leave the trunk (without synapsing) to pass to the suprarenal
gland, where certain cells of the medulla can be regarded as modified ganglion cells.

Figure 1.13 Visceral connections of sympathetic ganglia: A efferent pathway with synapse in a
sympathetic trunk ganglion; B efferent pathway with synapse in a peripheral ganglion; C afferent
pathway for pain fibres, passing through the trunk ganglion and into the spinal nerve by the white
ramus communicans.

Because there is no sympathetic outflow from the cervical part of the cord, nor from the lower lumbar
and sacral parts, those preganglionic fibres which are destined to synapse with cell bodies whose
fibres are going to run with cervical nerves must ascend in the sympathetic trunk to cervical ganglia,
and those for lower lumbar and sacral nerves must descend in the trunk to lower lumbar and sacral
ganglia.
The segmental levels of the preganglionic cell bodies concerned with the innervation of the different
regions of the body (via postganglionic neurons) are indicated in Figure 1.14. In general the body is
represented upright from head to perineum but with overlaps and individual variations.
 Figure 1.14 Spinal cord levels of sympathetic preganglionic cells. There may be considerable
individual variations, especially for the upper limb.

The sympathetic trunk extends alongside the vertebral column from the base of the skull to the coccyx.
Theoretically there is a ganglion for each spinal nerve, but fusion occurs, especially in the cervical
region where the upper four unite to form the superior cervical ganglion, the fifth and sixth form the
middle cervical ganglion, and the seventh and eighth fuse as the inferior cervical ganglion (and often
with the first thoracic ganglion as well to form the cervicothoracic or stellate ganglion). Elsewhere
there is usually one ganglion less than the number of nerves: 11 thoracic; 4 lumbar; and 4 sacral.
The fibres from the lateral horn cells of each segment of the spinal cord leave in the anterior nerve
root (with the axons of anterior horn cells) to reach the spinal nerve and its anterior ramus. The
connecting links from here to the sympathetic trunk and its ganglia are the rami communicantes. There
are normally two rami; the white ramus communicans is the more distal of the two, and this is the one
containing the preganglionic fibres (which are myelinated, hence called white). The other, the grey
ramus communicans, contains efferent postganglionic fibres (which are unmyelinated, hence grey).
The fibres in the grey ramus are those that are distributed via the branches of the spinal nerve to blood
vessels, sweat glands and arrector pili muscles (i.e. they are vasomotor, sudomotor and pilomotor).
Every spinal nerve receives a grey ramus. All the thoracic and the upper two lumbar nerves have both
white and grey rami connecting them to sympathetic ganglia. But the cervical, lower lumbar and
sacral nerves do not have white rami; the ganglia they are connected with receive preganglionic
fibres from the thoracolumbar outflow through the chain. Because of the fusion of ganglia, the superior
cervical ganglion gives off four grey rami, and the other cervical ganglia two each. Occasionally rami
(both grey and white) may be duplicated.
Each sympathetic trunk ganglion has a collateral or visceral branch, usually called a splanchnic
nerve in the thoracic, lumbar and sacral regions, but in the cervical region called a cardiac branch
because it proceeds to the cardiac plexus. The visceral branches generally arise high up and descend
steeply to form plexuses for the viscera (Fig. 1.13). Thus cardiac branches arise from the three
cervical ganglia to descend into the mediastinum to the cardiac plexus, which is supplemented by
fibres from upper thoracic ganglia. From the fifth and lower thoracic ganglia three splanchnic nerves
pierce the diaphragm to reach the coeliac plexus and other pre-aortic plexuses, which are also joined
by lumbar splanchnic nerves from the upper lumbar ganglia. Fibres from these plexuses, and
splanchnic nerves from the lower lumbar ganglia, descend to the superior hypogastric plexus and
thence to the left and right inferior hypogastric (pelvic) plexuses.
The sympathetic visceral plexuses thus formed are joined by parasympathetic nerves: vagus to the
coeliac plexus; and pelvic splanchnics (S2–4) to the inferior hypogastric plexuses. The mixed
visceral plexuses reach the viscera by direct branches and by branches that hitch-hike along the
relevant arteries.
In addition to the visceral branches, which supply not only the smooth muscle and glands of viscera
but also the blood vessels of those viscera, all trunk ganglia give off vascular branches to adjacent
large blood vessels. The cervical ganglia give branches to the carotid and vertebral arteries,
including (from the superior cervical ganglion) the internal carotid nerve, running upwards on the
artery of that name to form the internal carotid plexus on the artery as it enters the skull. The thoracic
and lumbar ganglia give filaments to the various aortic plexuses and from there to aortic branches
including the common iliac arteries, continued along the internal and external iliac arteries as far as
the proximal part of the femoral artery. Branches from the sacral ganglia pass to the lateral sacral
arteries. Limb vessels get their sympathetic innervation mainly from nerve fibres that run with the
adjacent peripheral nerves before passing to the vessels; the fibres do not run long distances along the
vessels themselves. Thus the nerve filaments to the vessels of the tip of a finger or toe run not with the
digital arteries but with the digital nerves, and only leave the nerves near the actual site of
innervation.
Afferent sympathetic fibres
Many afferent fibres hitch-hike along sympathetic efferent pathways. Some form the afferent limb for
unconscious reflex activities; others are concerned with visceral pain. All have their cell bodies in
the posterior root ganglia of spinal nerves (not in sympathetic ganglia), at approximately the same
segmental level as the preganglionic cells (Fig. 1.14). The afferent fibres reach the spinal nerve via
the white ramus communicans (Fig. 1.13C) and then join the posterior root ganglion, from which
central processes enter the spinal cord by the posterior nerve root (like any other afferent fibres).
Visceral pain fibres enter the posterior horn of the spinal cord, and thereafter the pain pathway is the
same as that for spinal nerve pain fibres. Others concerned with reflex activities may synapse with
interneurons in the cord or ascend to the hypothalamus and other higher centres by pathways that are
not defined.
Sympathectomy
For the control of excessive sweating and vasoconstriction in the extremities of the limbs, parts of the
sympathetic trunk with appropriate ganglia can be removed to abolish the normal sympathetic
influence. In upper thoracic ganglionectomy for the upper limb the second and third thoracic ganglia
with their rami and the intervening part of the trunk are resected; alternatively, the trunk is divided
below the third ganglion and the rami communicantes to the second and third ganglia are severed. The
first thoracic ganglion is not removed, as the preganglionic fibres for the upper limb do not usually
arise above T2 level (see above), and its removal would result in Horner's syndrome (see p. 408).
Upper thoracic ganglionectomy is described further on page 211.
For lumbar sympathectomy the third and fourth lumbar ganglia and the intervening trunk are removed.
The first lumbar ganglion should be preserved otherwise ejaculation may be compromised. Lumbar
sympathectomy is described further on page 282.

Parasympathetic nervous system
Although all parts of the body receive a sympathetic supply, the distribution of parasympathetic fibres
is wholly visceral and not to the trunk or limbs. However, not all viscera are so innervated: the
suprarenal glands and the gonads appear to have only a sympathetic supply.
The preganglionic fibres of cranial origin have their cell bodies in the accessory (Edinger–Westphal)
oculomotor nucleus, the superior and inferior salivatory nuclei of the seventh and ninth cranial nerves
respectively, and the dorsal motor nucleus of the vagus. The fibres of the first three nuclei synapse
with cells in the four parasympathetic ganglia, described below; the vagal fibres synapse with
postganglionic cell bodies in the walls of the viscera supplied (heart, lungs and gut).
The preganglionic fibres of sacral origin arise from cells in the lateral grey horn of sacral segments
2–4 of the spinal cord, and constitute the pelvic splanchnic nerves. Leaving the anterior rami of the
appropriate sacral nerves near the anterior sacral foramina, they pass forwards to enter into the
formation of the inferior hypogastric plexuses. From there they run to pelvic viscera and to the hindgut
as far up as the splenic flexure, and synapse around postganglionic cell bodies in the walls of these
viscera.
Cranial parasympathetic ganglia
The four ganglia—ciliary, pterygopalatine, submandibular and otic—are very similar in plan. Each
has parasympathetic, sympathetic and sensory roots, and branches of distribution. The roots and
branches are described in general terms below and illustrated in Figure 1.15; the topographical
details of each ganglion are dealt with in the regions concerned.

Figure 1.16 An embryo at the beginning of the second week. The trophoblast has differentiated into
an inner layer of cells with single nuclei (the cytotrophoblast) and an outer layer with multiple
nuclei but without distinct cell boundaries (the syncytiotrophoblast).

The parasympathetic root carries the preganglionic fibres from the cells of origin in a brainstem
nucleus. This is the essential functional root of the ganglion; its fibres synapse in it, whereas the fibres
of all other roots simply pass through the ganglion without synapse.
The sympathetic root contains postganglionic fibres from the superior cervical ganglion, whose
preganglionic cell bodies are in the lateral grey horn of cord segments T1–3.
The sensory root contains the peripheral processes of cell bodies in the trigeminal ganglion.
The branches of each ganglion carry the postganglionic parasympathetic fibres to the particular
structure(s) requiring this kind of localized motor innervation: ciliary muscle and sphincter pupillae
from the ciliary ganglion, salivary glands from the submandibular and otic ganglia, and lacrimal,
nasal and palatal glands from the pterygopalatine ganglion. The other fibres in the branches are
sympathetic fibres to the same structures (mainly for their blood vessels) and afferent fibres.
Ciliary ganglion (see p. 403)
Parasympathetic root. From the Edinger–Westphal part of the oculomotor nucleus by a branch from
the nerve to the inferior oblique muscle from the inferior division of the oculomotor nerve.
Sympathetic root. From the superior cervical ganglion by branches of the internal carotid plexus.
Sensory root. From a