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Palatine tonsil | |
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Mouth (oral cavity).
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The Palatine tonsils with the soft palate, uvula, and tongue visible.
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Details | |
Precursor | pharyngeal arches[1] |
System | Immune system (Lymphatic system) |
Artery | tonsillar branch of the facial artery |
Nerve | tonsillary branches of lesser palatine nerves |
Identifiers | |
Latin | tonsilla palatina |
TA | A05.2.01.011 |
FMA | 9610 |
Anatomical terminology
[edit on Wikidata]
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Palatine tonsils, occasionally called the faucial tonsils,[2] are the tonsils on the left and right sides at the back of the throat, which can often be seen as flesh-colored, pinkish lumps. Tonsils only present as "white lumps" if they are inflamed or infected with symptoms of exudates (pus drainage) and severe swelling.
Tonsillitis is an inflammation of the tonsils and will often, but not necessarily, cause a sore throat and fever. In chronic cases tonsillectomy may be indicated.[3]
The palatine tonsils are located in the isthmus of the fauces, between the palatoglossal arch and the palatopharyngeal arch of the soft palate.
The palatine tonsil is one of the mucosa-associated lymphoid tissues (MALT), located at the entrance to the upper respiratory and gastrointestinal tracts to protect the body from the entry of exogenous material through mucosal sites. In consequence it is a site of, and potential focus for, infections, and is one of the chief immunocompetent tissues in the oropharynx. It forms part of the Waldeyer's ring, which comprises the adenoid, the paired tubal tonsils, the paired palatine tonsils and the lingual tonsils. From the pharyngeal side, they are covered with a stratified squamous epithelium, whereas a fibrous capsule links them to the wall of the pharynx. Through the capsule pass trabecules that contain small blood vessels, nerves and lymphatic vessels. These trabecules divide the tonsil into lobules.
The nerves supplying the palatine tonsils come from the maxillary division of the trigeminal nerve via the lesser palatine nerves, and from the tonsillar branches of the glossopharyngeal nerve. The glossopharyngeal nerve continues past the palatine tonsil and innervates the posterior 1/3 of the tongue to provide general and taste sensation. This nerve is most likely to be damaged during a tonsillectomy, which leads to reduced or lost general sensation and taste sensation to the posterior third of the tongue.
Blood supply is provided by tonsillar branches of five arteries: the dorsal lingual artery (of the lingual artery), ascending palatine artery (of the facial artery), tonsillar branch (of the facial artery), ascending pharyngeal artery (of the external carotid artery), and the lesser palatine artery (of the descending palatine artery). The tonsils venous drainage is by the peritonsillar plexus, which drain into the lingual and pharyngeal veins, which in turn drain into the internal jugular vein.
Palatine tonsils consist of approximately 15 crypts, which result in a large internal surface. The tonsils contain four lymphoid compartments that influence immune functions, namely the reticular crypt epithelium, the extrafollicular area, the mantle zones of lymphoid follicles, and the follicular germinal centers. In human palatine tonsils, the very first part exposed to the outside environment is tonsillar epithelium.
Tonsillar (relating to palatine tonsil) B cells can mature to produce all the five major Immunoglobulin (Ig, aka antibody) classes. Furthermore, when incubated in vitro with either mitogens or specific antigens, they produce specific antibodies against diphtheria toxoid, poliovirus, Streptococcus pneumoniae, Haemophilus influenzae, Staphylococcus aureus, and the lipopolysaccharide of E. coli. Most Immunoglobulin A produced by tonsillar B cells in vitro appears to be 7S monomers, although a significant proportion may be l0S dimeric IgA.
In addition to humoral immunity elicited by tonsillar and adenoidal B cells following antigenic stimulation, there is considerable T-cell response in palatine tonsils. Thus, natural infection or intranasal immunization with live, attenuated rubella virus vaccine has been reported to prime tonsillar lymphocytes much better than subcutaneous vaccination. Also, natural infection with varicella zoster virus has been found to stimulate tonsillar lymphocytes better than lymphocytes from peripheral blood.
Combined tonsillectomy and adenoidectomy had a profound detrimental effect on the local IgA response in the nasopharyngeal fluid against poliovirus. These immunological observations paralleled the increased incidence of paralytic poliomyelitis after this operation. Thus, it is obvious that the tonsils have an important role to play in the defense of the host against bacterial and viral infections, and the success of regional mucosal immunity induced by intranasal vaccines most likely depends on these immunocompetent tissues in the oropharynx and nasopharynx.
Altogether, therefore, several pieces of direct and indirect evidence indicate that the palatine tonsils are continuously engaged in local immune responses to microorganisms. If the tonsillar lymphocytes became overwhelmed with this persistent stimulation they may be unable to respond to other antigens; the immunological response, particularly in recurrent tonsillitis, may then be impaired. Once this immunological impairment occurs, the tonsil is no longer able to function adequately in local protection nor can it appropriately reinforce the secretory immune system of the upper respiratory tract.
Cytokines are humoral immunomodulatory proteins or glycoproteins which control or modulate the activities of target cells, resulting in gene activation, leading to mitotic division, growth and differentiation, migration, or apoptosis. They are produced by wide range of cell types upon antigen-specific and non-antigen specific stimuli. It has been reported by many studies that the clinic outcome of many infectious, autoimmune, or malignant diseases appears to be influenced by the overall balance of production (profiles) of pro-inflammatory and anti-inflammatory cytokines. Therefore, determination of cytokine profiles in tonsil study will provide key information for further in-depth analysis of the cause and underlying mechanisms of these disorders, as well as the role and possible interactions between the T- and B-lymphocytes and other immunocompetent cells.[4]
The cytokine network represents a very sophisticated and versatile regulatory system that is essential to the immune system for overcoming the various defense strategies of microorganisms. Through several studies, the Th1 and Th2 cytokines and cytokine mRNA are both detectable in tonsillar hypertrophy (or obstructive sleep apnea, OSA) and recurrent tonsillitis groups. It showed that human palatine tonsil is an active immunological organ containing a wide range of cytokine-producing cells. Both Th1 and Th2 cells are involved in the pathophysiology of TH and RT conditions. Indeed, human tonsils persistently harbor microbial antigens even when the subject is asymptomatic of ongoing infection. It could also be an effect of ontogeny of the immune system.
The pathogenesis of infectious/inflammatory disease in the tonsils most likely has its basis in their anatomic location and their inherent function as organ of immunity, processing infectious material, and other antigens and then becoming, paradoxically, a focus of infection/inflammation. No single theory of pathogenesis has yet been accepted, however. Viral infection with secondary bacterial invasion may be one mechanism of the initiation of chronic disease, but the effects of the environment, host factors, the widespread use of antibiotics, ecological considerations, and diet all may play a role.
In children, the tonsils are common sites of infections that may give rise to acute or chronic tonsillitis. However, it is still an open question whether tonsillar hypertrophy is also caused by a persistent infection. Tonsillectomy is one of the most common major operations performed on children. The indications for the operation have been complicated by the controversy over the benefits of removing a chronically infected tissue and the possible harm caused by eliminating an important immune inductive tissue.
The information that is necessary to make a rational decision to resolve this controversy can be obtained by understanding the immunological potential of the normal palatine tonsils and comparing these functions with the changes that occur in the chronically diseased counterparts.
Tonsillitis is the inflammation of tonsils. Acute tonsillitis is the most common manifestation of tonsillar disease. It is associated with sore throat, fever, and difficulty swallowing. The tonsils may appear normal sized or enlarged but are usually erythematous. Often, but not always, exudates can be seen. Not all these signs and symptoms are present in every patient.
Recurrent infection has been variably defined as from four to seven episodes of acute tonsillitis in one year, five episodes for two consecutive years or three episodes per year for 3 consecutive years.
Tonsillar hypertrophy is the enlargement of the tonsils, but without the history of inflammation. Obstructive tonsillar hypertrophy is currently the most common reason for tonsillectomy. These patients present with varying degrees of disturbed sleep which may include symptoms of loud snoring, irregular breathing, nocturnal choking and coughing, frequent awakenings, sleep apnea, dysphagia and/or daytime hypersomnolence. These may lead to behavioral/mood changes in patients and facilitate the need for a polysomnography in order to determine the degree to which these symptoms are disrupting their sleep.
Lymphatic system
The mouth cavity. The cheeks have been slit transversely and the tongue pulled forward.
Throat after tonsils removed (i.e. tonsillectomy).
Anterior photograph of the oral cavity showing palatine tonsils (inflamed) and uvula.
Open mouth with visible palatine tonsils.
Palatine tonsil
Anatomy of the mouth
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Lip |
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Cheek |
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Roof |
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Gums |
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Glands |
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Teeth |
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Tongue |
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Back of mouth |
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Organs of the lymphatic system
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Primary organs |
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Secondary organs |
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リンク元 | 「鰓弓」「口蓋扁桃」 |
関連記事 | 「palatine」 |
# | 鰓弓 | 神経 | 筋 | 骨格 | 動脈* |
1 | 顎弓(上顎隆起、下顎隆起) | CN V 三叉神経: 上顎枝、下顎枝(第一鰓弓の筋を支配) |
咀嚼筋(側頭筋、咬筋、内側翼突筋・外側翼突筋)、顎舌骨筋、顎二腹筋前腹、口蓋帆張筋と鼓膜張筋 | 上顎突起(顎前骨、上顎骨、頬骨、側頭骨の一部)、メッケル軟骨(下顎骨、キヌタ骨、ツチ骨、前ツチ骨靱帯、蝶下顎靱帯) | 消失し一部残存(顎動脈) |
2 | 舌骨弓 | CN VII 顔面神経 |
顔面表情筋(頬筋、耳介筋、前頭筋、広頚筋、口輪筋および眼輪筋)、顎二腹筋後腹、茎突舌骨筋、アブミ骨筋 | アブミ骨、茎状突起、茎突舌骨靱帯、舌骨小角と舌骨体の上部 | 消失し一部残存(舌骨動脈、アブミ骨動脈) |
3 | CN IX 舌咽神経 |
茎突咽頭筋 | 舌骨大角と舌骨体の下部 | 総頚動脈、内頚動脈の基部。外頚動脈が出芽 | |
4 | CN X 迷走神経 |
輪状甲状筋、口蓋帆挙筋 | 喉頭軟骨(甲状軟骨、輪状軟骨、披裂軟骨、小角軟骨、および楔状軟骨 | 大動脈弓の一部 | |
5 | 上喉頭神経(第四鰓弓支配神経) | 咽頭収縮筋 | 消失 | ||
6 | 反回神経(下喉頭神経)(第六鰓弓支配神経) | 喉頭内の筋 | 動脈管と肺動脈の基部 |
Henry Gray (1825-1861). Anatomy of the Human Body. 1918.
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