Biology 218 – Human Anatomy

Lecture Outline
Adapted from Martini Human Anatomy7th ed. / Session:
Section:
Days / Time: Instructor: / FALL
52999
MW 5:00 PM – 9:20 PM
RIDDELL

Chapter 22

The Cardiovascular System: Vessels and Circulation

Introduction

There are two groups of blood vessels

Pulmonary circuit

Blood goes to and from the lungs

Systemic circuit

Blood goes to the rest of the body and back to the heart

Blood goes to both circuits at the same time with each heartbeat

Histological Organization of Blood Vessels

The walls of the vessels consist of three layers

Intima (innermost layer)

Media (middle layer)

Adventitia (outermost layer)

The layered walls give the vessels tremendous strength

Histological Organization of Blood Vessels

Intima (innermost layer)

Consists of two sublayers

Endothelial lining

Underlying layer of connective tissue

Arteries consists of a thick layer of elastic fibers giving the lining a “wavy” appearance

Histological Organization of Blood Vessels

Media (middle layer)

Consists of smooth muscle

When stimulated by sympathetic nerves, the muscles contract resulting in vasoconstriction

Relaxation of the smooth muscle results in vasodilation

Histological Organization of Blood Vessels

Adventitia (outermost layer)

Forms a connective sheath around the vessel

Composed of collagen fibers

Anchors the blood vessels in position

The walls of some vessels are too thick to obtain nutrients via diffusion so they have their own blood supply in vessels called vasa vasorum

Histological Organization of Blood Vessels

Distinguishing Arteries from Veins

Most arteries and veins run parallel to each other

Arteries carry blood away from the heart and veins carry blood toward the heart

Walls of arteries are thicker than veins

Arteries maintain their circular shape and veins
typically collapse when cut

Endothelial lining of an artery has pleated folds

Histological Organization of Blood Vessels

Arteries

As blood leaves the heart, it travels through:

Elastic arteries

Muscular arteries

Arterioles

Capillaries

Capillary beds

Histological Organization of Blood Vessels

Capillaries

Walls are thin enough to permit exchange of gases between the blood and the interstitial fluid

The diameter is about 8 microns

A red blood cell diameter is also about 8 microns

Fenestrated capillaries contain pores

Histological Organization of Blood Vessels

Capillaries (continued)

There are four mechanisms regarding the passage of material across the walls of capillaries

Material can diffuse across the endothelial lining

Material can diffuse through gaps between adjacent cells of the lining

Material can diffuse through pores

Material can move via endocytosis

Histological Organization of Blood Vessels

Capillary Beds

This is an interconnected network of capillaries

The capillary bed consists of vessels connecting arterioles with venules

There are precapillary sphincters involved in
regulating blood flow through the capillaries

Histological Organization of Blood Vessels

Capillary Beds (continued)

In areas such as the brain, heart, and stomach, a continuous, rich flow of blood is required

In these areas, more than one artery supplies a
specific area

These arteries (collateral arteries) typically fuse
forming an arterial anastomosis

If one arteriole is blocked, the other one will supply
blood to the capillary bed

Histological Organization of Blood Vessels

Capillary Beds (continued)

In areas such as the joints or visceral organs, blood flow through some vessels may be hindered due to body movement

In order to accommodate this, there must be a
direct connection between arterioles and venules

This direct connection is called an arteriovenous
anastomosis

Histological Organization of Blood Vessels

Veins

Veins collect blood from tissues and return the blood to the heart

As blood leaves the tissue and travels to the heart, it travels through the following vessels:

Capillary beds

Capillaries

Venules

Medium-sized veins

Large veins

Histological Organization of Blood Vessels

Blood in the veins returning to the heart from the lower extremities has to go against gravity

To assist in this process, many veins have valves (venous valves)

These valves compartmentalize the blood in the veins thus acting as one-way valves

If the venous valves do not close properly, varicose veins may occur

Histological Organization of Blood Vessels

The total blood volume is distributed unevenly within the vessels of the body

Arteries and capillaries contain 30–35% of the volume

Veins contain 65–70% of the volume

Veins are more distensible than arteries

Based on blood pressure, a vein can expand about 8 times as much as a parallel artery

Blood Vessel Distribution

Blood vessels can be divided into two circuits

Pulmonary circuit

Composed of arteries and veins that transport blood between the heart and the lungs

Arteries and veins travel relatively short distances

Systemic circuit

Composed of arteries and veins that transport oxygenated blood between the heart and all other tissues

Arteries and veins travel longer distances

Blood Vessel Distribution

There are functional and structural differences between the vessels in the two circuits

Blood pressure in the pulmonary circuit is lower than in the systemic circuit

Walls of the pulmonary arteries are thinner than the walls of systemic arteries

Blood Vessel Distribution Vessel Distribution

Functional patterns of the pulmonary and systemic circuits

The distribution of arteries and veins is the same on the left side of the body as it is on the right side of the body except for the venae cavae and the aorta

A single vessel will have different names according to specific anatomical boundaries

Arteries and veins often anastomose

Blood Vessel Distribution

The Pulmonary Circuit

Blood leaves the heart by passing through the pulmonary valve

Blood enters the pulmonary trunk

Blood enters the left and right pulmonary arteries

Blood arrives at the lungs to drop off carbon dioxide and pick up oxygen

Blood returns to the heart via the pulmonary veins

Blood enters the left atrium of the heart

Blood Vessel Distribution

The Systemic Circuit

Blood leaves the heart by passing through the aortic valve

Blood enters the ascending aorta and then the aortic arch and then it branches into:

Brachiocephalic trunk (then the right common carotid and right subclavian arteries)

Left common carotid artery

Left subclavian artery

Descending aorta

Coronary arteries

Blood Vessel Distribution

The Systemic Circuit (continued)

Ascending aorta

Begins at the aortic valve

Left and right coronary arteries branch off the base of the ascending aorta

Aortic arch

Forms an arch going toward the left and posterior side of the heart

Branching off the aortic arch are three elastic arteries

Blood Vessel Distribution

The Systemic Circuit (continued)

Branches of the aortic arch

Brachiocephalic trunk gives rise to the right
common carotid artery (supplies blood to the right side of the head and brain) and to the right subclavian artery (supplies blood to the right arm)

Left common carotid artery (supplies blood to the left side of the head and brain)

Left subclavian artery (supplies blood to the left arm)

Blood Vessel Distribution

The Systemic Circuit (continued)

The subclavian arteries

Give rise to the vertebral arteries

Give rise to the axillary arteries

Prior to forming the axillary arteries, the subclavians form three branches:

Thyrocervical trunk (supplies muscles of the neck, head, and upper back)

Internal thoracic artery (supplies the pericardium and anterior wall of the chest)

Vertebral artery (supplies the brain and spinal cord)

Blood Vessel Distribution

The flow of blood from the subclavians

Axillary artery

Branches to form the humeral circumflex artery

Brachial artery

Branches to form the deep brachial artery

Divides to form the radial and ulnar arteries

Arteries anastomose at the wrist forming the superficial palmar arch and deep palmar arch

Blood Vessel Distribution

The Carotid Arteries

The common carotids ascend the neck

Divide to form the internal carotids and external carotids

The carotid sinus is at the base of the internal carotid artery consisting of baroreceptors and chemoreceptors

Blood Vessel Distribution

The internal and external carotid arteries

External carotids supply the neck and outside of the skull

Internal carotids enter the skull to deliver blood to the brain

Internal carotid branches to form:

Ophthalmic artery (supplies the eyes)

Anterior cerebral artery (supplies frontal and parietal lobes of the brain)

Middle cerebral artery (supplies the midbrain and lateral surfaces of the brain)

Blood Vessel Distribution

Blood supply to the brain

Blood in the vertebral arteries go to the brain via:

Left and right vertebral arteries fuse to form the basilar artery

Basilar artery branches many times in the area of the pons

Basilar artery eventually forms the vessels of the cerebral arterial circle (circle of Willis)

Blood in the internal carotid arteries goes to the brain via:

Anastomosing with the cerebral arterial circle

Blood Vessel Distribution

The Descending Aorta

A continuation of the aortic arch

Divided into thoracic aorta and abdominal aorta

Blood Vessel Distribution

The Thoracic Aorta

Branches to form the following vessels:

Bronchial arteries

Pericardial arteries

Mediastinal arteries

Esophageal arteries

Intercostal arteries

Superior phrenic arteries

Blood Vessel Distribution

The Abdominal Aorta

Branches to form the following vessels:

Celiac trunk

Superior mesenteric artery

Inferior mesenteric artery

Inferior phrenic arteries

Suprarenal arteries

Renal arteries

Gonadal arteries

Lumbar arteries

Right and left common iliacarteries

Blood Vessel Distribution

The Celiac Trunk

Branches to form the left gastric artery

Supplies the stomach

Branches to form the splenic artery

Branches to form the left gastroepiploic artery to supply the stomach

Branches to form the pancreatic arteries to supply the pancreas

Blood Vessel Distribution

The Celiac Trunk (continued)

Branches to form the common hepatic artery

The common hepatic artery branches to form:

Hepatic artery proper to supply the liver

Right gastric artery to supply the stomach

Cystic artery to supply the gallbladder

Gastroduodenal artery to supply the duodenum

Blood Vessel Distribution

Inferior Mesenteric Artery

Branches to form the left colic and sigmoid arteries

Supply the terminal portions of the large intestine

Branches to form the rectal arteries

Supply the rectum

Blood Vessel Distribution

Arteries of the Pelvis

The common iliac arteries

Branch to form the internal iliac artery

Supplies the urinary bladder, walls of the pelvis, external genitalia, and the medial side of the thigh

Branches to form the external iliac artery

Supplies blood to the legs

Blood Vessel Distribution

Arteries of the Leg

External iliac arteries form the:

Femoral artery

The femoral artery continues to form the popliteal artery, and then splits to form the anterior tibial artery and posterior tibial artery

Deep femoral artery

Blood Vessel Distribution

Arteries of the Foot

The anterior tibial artery forms the dorsalis pedis artery

The posterior tibial artery forms the medial and
lateral plantar arteries

Blood Vessel Distribution

Systemic Veins

Veins collect blood from the body tissues and return it to the heart

Blood returns to the heart from the lower extremities via the inferior vena cava to the right atrium

Blood returns to the heart from the upper extremities via the superior vena cava to the right atrium

Blood returns to the heart from the lungs via the pulmonary veins to the left atrium

Blood Vessel Distribution

Venous Return from the Cranium

The superficial cerebral veins drain into:

Superior and inferior sagittal sinuses

Petrosal sinuses

Occipital sinus

Left and right transverse sinuses

Straight sinus

All of the venous sinuses drain into the internal jugular vein

The internal jugular drains into the brachiocephalic veins

Blood Vessel Distribution

Venous Return from the Cranium (continued)

The vertebral veins drain into the brachiocephalic veins

Blood Vessel Distribution

Venous Return from the Head

Veins from the head converge to form the:

Temporal vein

Facial vein

Maxillary veins

The temporal and maxillary veins drain into the
external jugular vein

The facial vein drains into the internal jugular vein

Blood Vessel Distribution

Venous Return from the Neck

Vessels in the neck drain into the external jugular vein

The external jugular vein drains into the subclavian vein

Blood Vessel Distribution

Venous Return from the Upper Limb

Blood returns to the heart from the hands in the
following sequence:

Digital veins

Superficial and deep palmar veins

The superficial palmar veins drain into the cephalic vein

Subclavian vein

Brachiocephalic vein

Superior vena cava

Right atrium

Blood Vessel Distribution

Venous Return from the Upper Limb

Blood can also return to the heart from the hands in the following sequence:

The superficial palmar veins drain into the cephalic vein

Median cubital vein

Basilic vein

Axillary vein

Subclavian vein

Brachiocephalic vein

Superior vena cava

Right atrium

Blood Vessel Distribution

Venous Return from the Upper Limb

Blood can also return to the heart from the hands in the following sequence:

The superficial palmar veins drain into the basilic vein

Axillary vein

Subclavian vein

Brachiocephalic vein

Superior vena cava

Right atrium

Blood Vessel Distribution

Venous Return from the Upper Limb

Blood can also return to the heart from the hands in the following sequence:

The deep palmar veins drain into the radial and ulnar vein

Those veins will unite to form the brachial vein

Axillary vein

Subclavian vein

Brachiocephalic vein

Superior vena cava

Right atrium

Blood Vessel Distribution

Venous Return from the Abdominal Area

The following veins drain into the inferior vena cava or the superior vena cava, which drains into the right atrium

Lumbar veins go superior and drain into the superior vena cava

Gonadal veins: the right gonadal vein drains into the inferior vena cava, the left gonadal vein drains into the left renal vein and then into the inferior vena cava

Hepatic veins drain into the inferior vena cava

Blood Vessel Distribution

Venous Return from the Lower Limb

Blood leaves the foot and returns to the heart via the following veins

Plantar veins

Drain into the anterior tibial, posterior tibial, and fibular veins

Popliteal vein

Femoral vein

Common iliac vein

Inferior vena cava

Right atrium

Blood Vessel Distribution

Venous Return from the Lower Limb

Blood also leaves the foot and returns to the heart via the following veins

Dorsal venous arch

Great saphenous vein

Femoral vein

External iliac vein

Common iliac vein

Inferior vena cava

Right atrium

Blood Vessel Distribution

Venous Return from the Hepatic Portal System

Blood in the inferior mesenteric, splenic, and superior mesenteric veins drains into the hepatic portal system

Liver sinusoids

Hepatic veins

Inferior vena cava

Right atrium

Cardiovascular Changes at Birth

The fetal cardiovascular system differs from the adult cardiovascular system

The fetal lungs are nonfunctional

The fetal digestive system is nonfunctional

All fetal nutritional and respiratory needs are provided by diffusion across the placenta

Blood in the fetal internal iliacs enters the umbilical arteries

Enters the umbilical cord

Enters the placenta

Cardiovascular Changes at Birth

All fetal nutritional and respiratory needs are provided by diffusion across the placenta (continued)

Blood leaves the placenta

Enters the umbilical vein

Enters the ductus venosus

Enters the fetal liver

Enters the inferior vena cava

Enters the fetal right atrium

Cardiovascular Changes at Birth

All fetal nutritional and respiratory needs are provided by diffusion across the placenta (continued)

Blood in the right atrium can pass through the
heart via the following methods:

Through the tricuspid valve to the right ventricle

Through the foramen ovale to the left atrium