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Head and neck anatomy
Head and neck anatomy focuses on the structures of the head and neck of the human body, including the brain, bones, muscles, blood vessels, nerves, glands, nose, mouth, teeth, tongue, and throat. It is an area frequently studied in depth by surgeons, dentists, dental technicians, and speech language pathologists.
Additional recommended knowledge
Dental students focus their studies on teeth and the support structures of teeth. However, there are no independent structures or systems of the body. An abscessed tooth may quickly spread pathogens to other body organs and systems. For example an infected tooth may lead to heart disease (Endocarditis) and kidney disease (Glomerulonephritis) if the pathogen is either a staphylococcus aureus (staph) or streptococcal (strep) bacterium.
The head is positioned upon the superior portion of the vertebral column, attaching the skull upon C-1, (the atlas). The skeletal section of the head and neck forms the superior segment of the axial skeleton and comprises skull, hyoid bone, auditory ossicles, and cervical spine. The skull can be further subdivided into:
As the fetus develops, the facial bones usually form into pairs, and then fuse together. As the cranium fuses, sutures are formed that resemble stitching between bone plates.
In a newborn, the junction of the paritial bones with the frontal and occipital bones, form the anterior (front) and posterior (back) fontanelle, or soft spots. The separation of the cranial bone plates at time of birth facilitate passage of the head of the fetus through the mother's birth canal, or pelvic girdle. The parietial bones, and occipital bone can overlap each other in the birth canal, and form the unusual looking "cone head" appearance in a newborn when delivered in a natural, or vaginal, delivery.
The occipital bone articulates with the atlas near the foramen magnum. The atlas articulates with the occipital condyle superiorly and the axis inferiorly. The spinal cord passes through the foramen magnum providing continuity for the central nervous system (CNS). Articulation (anatomy) of the neck includes: flexion, extension, hyperextension (nodding yes), and rotation (shaking head no).
Blood circulates from the upper systemic loop originating at the aortic arch, and includes: the brachiocephalic artery, left common carotid and left subclavian artery. The head and neck are emptied of blood by the subclavian vein and jugular vein.
The brachiocephalic artery or trunk is the first and largest artery that branches to form the right common carotid artery and the right subclavian artery. This artery provides blood to the right upper chest, right arm, neck, and head, through a branch called right vertebral artery. The right and left vertebral artery feed into the basilar artery and upward to the Posterior cerebral artery, which provides most of the brain with oxygenated blood. The posterior cerebral artery and the posterior communicating artery are within the circle of Willis.
The left subclavian artery and the right subclavian artery, one on each side of the body form the internal thoracic artery, the vertebral artery, the thyrocervical trunk, and the costocervical trunk. The subclavian becomes the axiliary artery at the lateral border of the first rib. The left subclavian artery also provides blood to the left upper chest and left arm.
The Blood-brain barrier (BBB) is semi-permeable membrane that controls the capillary leak potential of the circulatory system. In most parts of the body, the smallest blood vessels, called capillaries, are lined with endothelial cells. Endothelial tissue has small spaces between each individual cell so substances can move readily between the inside and the outside of the vessel. However, in the brain, the endothelial cells fit tightly together to create a tight junction and substances cannot pass out of the bloodstream. Some molecules, such as glucose, are transported out of the blood by active transport.
Specialized glial cells called astrocytes form a tight junction or protective barrier around brain blood vessels and may be important in the development of the BBB. Astrocytes may be also be responsible for transporting ions (electrolytes) from the brain to the blood.
Blood from the brain and neck flows from: (1) within the cranium via the internal jugular veins, a continuation of the sigmoid sinuses. The right and left external jugular veins drain from the parotid glands, facial muscles, scalp into the subclavian veins. The right and left vertebral veins drain the vertebrae and muscles into the right subclavian vein and into the superior vena cava, into the right atrium of the heart.
The lymphatic system drains the head and neck of excess interstitial fluid via lymph vessels or capillaries, equally into the right lymphatic duct and the thoracic duct.
Lymph nodes line the cervical spine and neck regions as well as along the face and jaw.
The tonsils also are lymphatic tissue and help mediate the ingestion of pathogens.
Together this set of lymphatic tissue is called the tonsillar ring or Waldeyer's ring.
The mouth is designed to support chewing, (mastication) and swallowing, (deglutition), and speech (phonation).
Two rows of teeth are supported by facial bones of the skull, the maxilla above and the mandible below.
A tooth is the toughest known substance in the body exceeding bones in density and strength. Tooth enamel lends great strength to the tooth structure. The formation of a developing tooth includes the process of dentin formation, (see: Dentinogenesis) and enamel formation, (see: amelogenesis. As the tooth breaks through the gum into the mouth, the process is called eruption. The formation of teeth begins in early fetal development and goes through six stages:
Tooth enamel is white initially but is susceptible to stains from coffee and cigarette usage. A tooth sits in a specialized socket called gomphosis. The tooth is held in location by a periodontal ligament, with the assistance of cementum.
The white visible part of a tooth is called the crown. The rounded upper projections of the back teeth are cusps. The hard white exterior covering of the tooth is the enamel. As the tooth tapers below the gumline, the neck is formed. Below the neck, holding the tooth into the bone, is the root of the tooth. The inner portions of the tooth consist of the dentin, a bonelike tissue, and the pulp. The pulp is a soft tissue area containing the nerve and blood vessels to nourish and protect the tooth, located within the pulp cavity.
There are various tooth shapes for different jobs. For example, when chewing, the upper teeth work together with the lower teeth of the same shape to bite, chew, and tear food. The names of these teeth are:
Adults have 32 permanent teeth, and children have 20 deciduous teeth.
There are three sets of salivary glands: the parotid, the submandibular and the sublingual glands. The (exocrine) glands secrete saliva for proper mixing of food and provides enzymes to start chemical digestion.
Saliva also helps to hold together the formed bolus which is swallowed after chewing.
The periodontium includes all of the support membranes of the dental structures surround and support the teeth such as the gums and the attachment surfaces and membranes.
It is attached to the hyoid bone.
Terms meaning tongue include "glosso" and "lingual."
The protective tissues of the oral cavity are continuous with the digestive tract are called mucosa or mucous membranes.
They line the oral, nasal, and external auditory meatus, (ear), providing lubrication and protection against pathogens.
This is a stratified squamous epithelium containing about three layers of cells.
The cells of the inner oral cavity are called the buccal mucosa.
The nervous system is composed of a central nervous system (CNS), brain and spinal cord, and the peripheral nervous system (PNS), cranial nerves and spinal nerves. The CNS is located within the dorsal cavity, and the PNS extends through the ventral cavity. The central nervous system provides control and coordination of all eleven body systems and utilizes the endocrine system to form hormone chemical messengers that transport through the blood to influence the activity of individual cells of the body and their associated tissues, organs and systems.
The CNS receives sensory (afferent) input from the PNS and directs the flow of information to association neurons (interneurons), located in the grey matter of the spinal cord and brain to create chemical synapse responses which in turn cause the formation of motor (efferent nerve) responses to stimulus.
The CNS is protected by the cranium, vertebral column, meninges, cerebrospinal fluid. The spinal cord, which is an extension of the brain, and brain stem are joined at the base of the cranium at the foramen magnum. Most of the functions of the head and neck are directly influenced by the brain and transmitted to the PNS via the cranial nerves and spinal nerves of the cervical portion of the spine.
The PNS has two subdivisions
Cranial nerves directly impact the sensing and processing of smell, olfactory nerve; the control and coordination of the eyes for movement and visual input, a complex task utilizing four cranial nerves, optic nerve, oculomotor nerve, trochlear nerve, and abducens nerve.
The control of the face and mouth also involves extensive coordination of cranial nerves. The face is controlled primarily by two nerves, trigeminal nerve which provides sensations to the face, and the facial nerve which controls facial expression and taste to two-thirds of the tongue, it also controls secretion of saliva and tears. Injury of the trigeminal nerve may result in loss of muscles of mastication. Injury to the facial nerve may result in paralysis of the facial muscles, Bell's palsy, loss of taste, and closure of the eyes.
The oral cavity control is also coordinated by three nerves; the glossopharyngeal nerve which also controls various sensations including taste and proprioception, salivary gland secretion, and muscles of the mouth and neck; accessory nerve that mediates swallowing movements and head positioning; and the hypoglossal nerve that controls the tongue muscles for speech and swallowing actions. Injury of the glossopharyngeal nerve may result in swallowing difficulty, reduction in saliva production, loss of sensation in the throat, and loss of taste. Injury of the accessory nerve may result in paralysis of the sternocleidomastoid muscle and the trapezius muscle, resulting in limited ability to produce shrugging movements with the shoulders and turning the head. Injury of the hypoglossal nerve may result in difficulty in chewing, speaking, and swallowing. The tongue may also be affected.
Hearing and balance are another control function the cranial nerves, the vestibulocochlear nerve, which transmits sound and balance sensory information from the inner ear to the brain. Injury to the vestibulocochlear nerve may result in ringing of the ears, tinnitis, deafness, and dizziness, vertigo.
The vagus nerve can also impact the head and neck. If the nerve pair is injured in the upper body, it may lead to difficulty in swallowing, possibly paralyzing the vocal cords, and interruption of sensations from many organs.
The spinal nerves arise from the spinal column. The top section of the spine is the cervical section, which contains nerves that innervate muscles of the head, neck and thoracic cavity, as well as transmit sensory information to the CNS.
The cervical spine section contains seven vertabrae, C-1 through C-7, and eight nerve pairs, C-1 through C-8.
There is the formation of an extensive network of nerve groups or tracts attaching to the spinal cord in arrangements called rami or plexus.
The sensory branches of spinal nerves include: lesser occipital, C-2, greater articular, (C-2 and C-3); transverse cervical, C-2 and C-3; and supraclavicular, C-3 and C-4. These nerve groups transmit afferent (sensory) information from the scalp, neck, and shoulders to the brain.
The motor branches of spinal nerves include: ansa cervicalis, dividing into a superior root, C-1, and an inferior root, C-2 and C-3, and the phrenic nerve, C-3 to C-5, the segmental nerve branches, C-1 to C-5. These nerve groups transmit efferent nerve (motor) information from the brain to muscle groups of the scalp, neck, diaphragm (anatomy), and shoulders.
Additionally there are: (C5-C8, and T1) Brachial plexus, providing the entire nerve supply of the shoulder and upper limb; and includes supraclavicular branches (dorsal scapular, suprascapular, long thoracic) lateral cord (musculocutaneous, lateral antibrachial cutaneous, lateral head of median nerve), medial cord (ulnar, medial head of median nerve, medial antibrachial cutaneous, medial brachial cutaneous), posterior cord (axillary, radial), controlling the arm.
Note: Damage to the spinal cord above C-5 may result in respiratory arrest and death if not medically treated.
The endocrine system is under the direct supervision of the nervous system, using the negative feedback principal of homeostasis, to create hormones which act as chemical instant messengers. The hypothalamus connects directly to the pituitary gland, both through the circulatory system and by direct connection of neurons. Also, within the cranium, the pineal gland, which attaches to the thalamus, controls the body's 24 hour rhythms circadian rhythm through the release of melatonin. Endocrine indicates that the secretion is used within the body. Endocrine glands are termed as ductless and release their secretions directly into the blood.
The pituitary gland is also called hypophysis, or master gland. It secretes hormones that directly impact the body as well as hormones that indirectly control body functions because they activate other endocrine glands, such as the adrenal cortex (ACTH) and the thyroid gland (TSH). These two glands when stimulated by pituitary hormones then release their own hormones. The pituitary gland has two lobes, the anterior lobe and the posterior lobe. The anterior lobe secretes: growth hormone (GH), Luteinizing hormone (LH), Follicle stimulating hormone (FSH), Adrenocorticotropic hormone (ACTH), Thyroid-stimulating hormone (TSH), Prolactin (PRL), and the posterior lobe secretes: Antidieuretic hormone (ADH), and Oxytocin (OT). There is an intermediate lobe, in adult humans it is just a thin layer of cells between the anterior and posterior pituitary, nearly indistinguishable from the anterior lobe. The intermediate lobe produces melanocyte-stimulating hormone (MSH).
In the neck are the thyroid and parathyroid glands, that secrete hormones that control metabolism and blood calcium levels. The four parathyroid glands are situated upon the dorsal (back) surface of the thyroid gland.
The respiratory System involves:
The critical pathway between the respiratory and digestive systems is the cartilage flap epiglottis which shuts during swallowing to prevent aspiration. The epiglottis is normally open to support respiration and shuts during swallowing to prevent food and fluids from enterng the trachea, activating the gag reflex or initiates the choking mechanism.
The respiratory system is involved in ventilation (physiology) and cellular respiration. Its functioning during oral procedures and surgery is essential to good patient care. If the patient stops breathing, heart failure will result within four to six minutes. The use of cardiopulmonary resuscitation (CPR) and rescue breathing may be required to revive the patient.
The epidermis is composed of stratified squamous epithelium and is divided into the following five sublayers or strata, listed in order from surface (superficial) to deep are:
Specialized sensory nerves are scattered throughout the epidermis and dermis allowing for a wide range of sensations to be detected by the sensation of touch.
Located within stratum basale are the most superficial nerves, free nerve endings, called tickle receptors.
Located just below the epidermis are Meissner's corpuscles which are very important in detecting subtle differences in texture, and Merkel cells monitor skin pressure.
The hair follicle endings detect hair movements, Krause corpuscles respond to pressure and cold, and are located on lips, tongue, and genitals.
The Pacinian corpuscles lay deep within the hypodermis, as do Ruffini ending, which detect heat. (See references below)
Within the deeper layers of the dermis and hypodermis, is a specialized type of connective tissue areolar connective tissue, which mediates the inflammatory response, or self-healing capacity of the body. The areolar tissue comprises collagen fibers and elastic fibers which contain several cells which are trapped within the tissue matrix. These cells, when disturbed by tissue damage, will release chemical and mechanical factors that signal the body's immune system to initiate clean-up, destruction of invading pathogens, and tissue repair. The cells involved are macrophages, mast cells, fibroblasts, and plasma cells.
The macrophages when disturbed by tissue trauma will devour as many invading pathogens as possible and perform cleaning of damaged tissue. The mast cells release histamine and heparin which help initiate the inflammatory response. The fibroblast help repair or replace damaged sections of matrix, and the plasma cells are capable of producing antibodies for pathogen destruction.
The inflammatory response system produces four distinct signs of activation: redness, swelling, heat, and pain (or itching). When these symptoms are confined to a specific site, it is termed as localized inflammation. In severe reactions involving a widespread inflammation response, or systemic inflammation (anaphylactic shock).
Anaphylactic shock requires advanced medical care immediately; but other first aid measures include rescue breathing (part of CPR) and administration of epinephrine using an EpiPen for immediate administration of epinephrine (adrenaline) to reverse swelling and to keep the respiratory airway (trachea) open.
Health care workers must exercise caution when performing care procedures on patients. The Universal precautions for health care workers are recommended by the Centers for Disease Control and Prevention (CDC) are the standard precaution for self protection.
Severe viral infections that affect the mouth, lips, or the oral cavity include:
Oral cancer may have a viral link.
Careful observation of the oral cavity, teeth and gums may reveal indicators of other medical conditions. For example, a person suffering from the eating disorder, Bulimia nervosa may show signs of excessive tooth and gum erosion.
Prior to any oral sedation methods being used on a patient, screening must be done to identify possible health concerns. Prevention is the best cure.
Identify any of the following that may apply:
A patient with any of these conditions must be evaluated for special procedures to minimize the risk of patient injury due to the sedation method.
In addition to the above mentioned precautions, patients should be interviewed to determine if they have any other condition that may lead to complications while undergoing treatment. Any head, neck, or spinal cord injuries should be noted as well as any diagnosis of osteoporosis.
|This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Head_and_neck_anatomy". A list of authors is available in Wikipedia.|