Introductory Chapter: Lymphatic System Human Anatomy PDF

Summary

This chapter provides an introductory overview of the lymphatic system in humans. It details the structure and function of lymphatic capillaries and vessels, emphasizing their role in fluid balance, immune function, and absorption of fats. The relationship between the lymphatic system and other body systems is also discussed.

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Chapter

Introductory Chapter: Lymphatic
System Human Anatomy
Luca Facchetti and Gaia Favero

1. Introduction

1.1 Lymphatic system human anatomy

The lymphatic system modulates the interstitial fluid volume through a one-way
transport system. The residual interstitial fluid is a carriage from the soft tissue inter-
stitial space into the venous circulation through specific lympho-venous connections
[1, 2]. Along with the excess interstitial fluid, redundant proteins and “waste” are
transported back to the bloodstream by the lymphatic system. In detail, the lymphatic
system via a network of lymphatic channels transports through lymph nodes the
interstitial fluid, which is defined as lymph when it is inside the lymphatic channels
network, and discharges it into the blood circulation [3–5]. Lymph nodes filter the
interstitial flow and break down bacteria, viruses, and other cells and molecules.
The lymphatic system is also important in immune surveillance defending the body
against microorganisms and foreign particles. The lymphatic system encourages the
immune response [2, 6, 7]. The lymphatic system is, therefore, strictly correlated
to the circulatory system and immune system, but not only. In fact, the lymphatic
system has also an important role in the absorption of fat-soluble vitamins and fatty
substances at the gut level, through gastrointestinal tract’s specific lymphatic capil-
laries called lacteals, so dietary fat is transported into the venous circulation. In
addition, lymphatic vessels were recently identified in the brain meninges and the
meningeal lymphatic network is fundamental for the removal of toxins and also in
draining cerebrospinal fluid and immune cells from the central nervous system to the
peripheral lymphatic system [3, 8].
The lymphatic system is a highly complex system with a variable structure and
function between anatomical sites and between species. In humans, the lymphatic
system includes lymphatic capillaries, lymphatic vessels (afferent and efferent),
lymph nodes, and various lymphoid organs (such as the thymus and spleen) [2, 6, 9].
In this introductory chapter, we will focus our attention mainly on the description
of the hierarchy lymphatic channels network (lymphatic capillaries and lymphatic
vessels).
The organization of lymphatic networks within various organs depends on the
functional demands of the organ itself, leading to both common and unique morpho-
logical features of the lymph-venous connections and lymphatic channel network
[3, 10]. Interstitial fluid comes out of the blood capillary walls due to heart and/
or cell osmotic pressure and enters the lymphatic system through small and blind-
ended lymphatic capillaries. These capillaries, defined as initial lymphatics, form

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Lymphatic System – From Human Anatomy to Clinical Practice

a mesh-like network and gradually increase their diameter becoming pre-collector
vessels, collector vessels, lymphatic trunks, and finally ducts. When soft tissue
interstitial pressure increases, the interstitial fluid enters into the lymphatic capillar-
ies through openings in the endothelial layer; whereas, when the pressure inside the
lymphatic capillaries rises, the interstitial fluid entering flow is stopped. Lymphatic
capillaries are tiny, thin-walled, and blind-end channels that present a larger diameter
with respect to blood capillaries. In addition, the lymphatic capillaries are dissipated
among blood capillaries to facilitate interstitial fluid collection by the lymphatic capil-
lary network. The lymphatic capillaries endothelial cells overlap but shift to open the
capillary wall when interstitial fluid pressure is greater than intra-capillary pressure
so permitting interstitial fluid, lymphocytes, bacteria, cellular debris, plasma pro-
teins, and other cells to enter the lymphatic capillaries [3, 6, 11]. The interstitial fluid
inside the lymphatic channels network is defined as lymph. Lymph is composed of
interstitial fluid with variable amounts of lymphocytes, monocytes, plasma proteins,
and other cells. Lymph formation is organ-dependent and it is correlated to the vari-
ous organs/tissues morphostructural properties [2, 6].
The lymphatic capillaries form large networks of channels called lymphatic
plexuses and converge to form larger lymphatic vessels. Collecting vessels are further
divided into afferent (pre-nodal) and efferent (post-nodal) vessels depending on
their location relative to lymph nodes. Afferent lymphatic vessels transport the unfil-
tered lymph from tissues to the lymph nodes and efferent lymphatic vessels convey
filtered lymph from lymph nodes to subsequent lymph nodes or into the venous
system. Lymph flow generally occurs against a pressure gradient and therefore
requires both extrinsic forces, such as skeletal muscle movement and arterial pulsa-
tions, and intrinsic forces exerted by lymphatic vessels. In fact, the lymph is pumped
slowly by the contraction of the lymphatic vessels [2, 3, 12]. To prevent lymph flow
backward, collecting lymphatic vessels and larger lymphatic vessels presented a
series of one-way valves; notably, the one-way valves are not present in the lymphatic
capillaries. These lymphatic valves help the advancement of lymph flow through the
lymphatic vessels.
The anatomical structure of each component of the lymphatic vessel network and
its surroundings contribute to its function. Figure 1 reported a schematic representa-
tion of the lymphatic channel network.
The lymphatic channels gradually increased their diameter becoming finally the
main lympho-venous connection: the thoracic duct and the right lymphatic duct.
The right lymphatic duct is responsible for draining the lymph from the upper right
quadrant of the body (the right side of the head, neck, thorax and the right upper
limb) into the venous circulation at the junction between the right subclavian vein
and the right internal jugular vein. The right lymphatic duct is formed generally by
the convergence of the right bronchomediastinal trunk, jugular trunk, and subclavian
trunk. However, it is important to underline that its origin and ending presented a
changeable anatomy and morphology.
The thoracic duct, also known as the left lymphatic duct or van Hoorne’s canal,
drains the lymph of the body except for the territory drained by the right lymphatic
duct so it drains lymph from 80% to 90% of the body. The thoracic duct is a thin-
walled tubular lymphatic vessel (with 2–6 mm in diameter). The thoracic duct is the
largest and longest lymphatic duct in the body. This duct drains lymph at the junction
between the left internal jugular vein and the left subclavian vein [1, 2]. The thoracic
duct presents a high anatomical variability, but it typically arises in the abdomen as

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Introductory Chapter: Lymphatic System Human Anatomy
DOI: http://dx.doi.org/10.5772/intechopen.1004116

Figure 1.
Schematic representation of the lymphatic channel network showing lymphatic capillaries and vessels. The
yellow arrows represent the direction of lymph flow inside the lymphatic channels and the black arrows show the
interstitial fluid entering the lymphatic vessels.

cisterna chyli, which is an expanded lymphatic sac that forms at the convergence of
the intestinal lymphatic trunk and lumbar lymphatic trunk. The cisterna chyli is at
the level of the 12 thoracic vertebrae (T12). Notably, the cisterna chyli is pres-
ent in approximately 40–60% of the population and in people without this cisterna
the intestinal and lumbar lymphatic trunks communicate directly with the thoracic
duct. From the cisterna, the thoracic duct ascends running to the right of the
body midline and posterior to the aorta and it enters the thorax via the aortic hiatus.
The thoracic duct then rises in the thoracic cavity anteriorly and to the right of the
vertebral column, between the aorta and azygous vein. At about the level of the fifth
thoracic vertebra (T5), the thoracic duct crosses to the left of the vertebral column
and posterior to the esophagus. Finally, it ascends vertically and then releases the
drained lymph in the venous circulation [6, 15, 16].
There is so a continuous and dynamic exchanging circulation of extracellular fluid
passing back and forth from the bloodstream to the tissues and lymphatic system.
The occlusion of the lymphatic vessels downstream may promote the opening of new
lympho-venous connections, resulting in anatomo-morphological changes relevant in
both health and disease states [1, 5, 12].

2. Conclusion

The lymphatic system has a fundamental role in extracellular fluid drainage, but
it has also important immune functions. The lymphatic system has also a critical role
in a clinical context, because the lymphatic and vascular systems have numerous con-
nections, and tumor cell metastasis may pass from one circulatory system to the other.
The lymphatic system is a highly complex and dynamic system and the lymphatic
system of human anatomy is fundamental to modulate pathological changes which
are relatively unknown, but fundamental in clinical practice.

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Lymphatic System – From Human Anatomy to Clinical Practice

Acknowledgements

The authors sincerely thank Dr. Marzia Gianò (Anatomy and Physiopathology
Division, University of Brescia, Italy) for her assistance in drawing the figure.

Conflict of interest

The authors declare no conflict of interest.

Author details

Luca Facchetti1 and Gaia Favero2,3*

1 Department of Radiology 1st Division, ASST Spedali Civili of Brescia, Brescia, Italy

2 Anatomy and Physiopathology Division, Department of Clinical and Experimental
Sciences, University of Brescia, Brescia, Italy

3 Interdipartimental University Center of Research “Adaption and Regeneration of
Tissues and Organs -ARTO”, University of Brescia, Brescia, Italy

*Address all correspondence to: [email protected]

© 2024 The Author(s). Licensee IntechOpen. This chapter is distributed under the terms of
the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0),
which permits unrestricted use, distribution, and reproduction in any medium, provided
the original work is properly cited.
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Introductory Chapter: Lymphatic System Human Anatomy
DOI: http://dx.doi.org/10.5772/intechopen.1004116

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