AnatomyDiseasesAnalytical, Diagnostic and Therapeutic Techniques and EquipmentPhenomena and ProcessesHealth Care
DeglutitionDeglutition DisordersHyoid BoneEsophageal Sphincter, UpperOropharynxBulbar Palsy, ProgressiveMasticationHypopharynxEpiglottisPharynxLarynxSphenoid BoneTongueDentition, MixedPharyngeal MusclesEsophageal StenosisFluoroscopyNasal BoneManometryCephalometryMouthEsophagusMandibleElectromyography
Deglutition
The act of taking solids and liquids into the GASTROINTESTINAL TRACT through the mouth and throat.
Deglutition Disorders
Difficulty in SWALLOWING which may result from neuromuscular disorder or mechanical obstruction. Dysphagia is classified into two distinct types: oropharyngeal dysphagia due to malfunction of the PHARYNX and UPPER ESOPHAGEAL SPHINCTER; and esophageal dysphagia due to malfunction of the ESOPHAGUS.
Hyoid Bone
A mobile U-shaped bone that lies in the anterior part of the neck at the level of the third CERVICAL VERTEBRAE. The hyoid bone is suspended from the processes of the TEMPORAL BONES by ligaments, and is firmly bound to the THYROID CARTILAGE by muscles.
Esophageal Sphincter, Upper
The structure at the pharyngoesophageal junction consisting chiefly of the CRICOPHARYNGEUS MUSCLE. It normally occludes the lumen of the ESOPHAGUS, except during SWALLOWING.
Oropharynx
The middle portion of the pharynx that lies posterior to the mouth, inferior to the SOFT PALATE, and superior to the base of the tongue and EPIGLOTTIS. It has a digestive function as food passes from the mouth into the oropharynx before entering ESOPHAGUS.
Bulbar Palsy, Progressive
A motor neuron disease marked by progressive weakness of the muscles innervated by cranial nerves of the lower brain stem. Clinical manifestations include dysarthria, dysphagia, facial weakness, tongue weakness, and fasciculations of the tongue and facial muscles. The adult form of the disease is marked initially by bulbar weakness which progresses to involve motor neurons throughout the neuroaxis. Eventually this condition may become indistinguishable from AMYOTROPHIC LATERAL SCLEROSIS. Fazio-Londe syndrome is an inherited form of this illness which occurs in children and young adults. (Adams et al., Principles of Neurology, 6th ed, p1091; Brain 1992 Dec;115(Pt 6):1889-1900)
Mastication
The act and process of chewing and grinding food in the mouth.
Hypopharynx
The bottom portion of the pharynx situated below the OROPHARYNX and posterior to the LARYNX. The hypopharynx communicates with the larynx through the laryngeal inlet, and is also called laryngopharynx.
Epiglottis
A thin leaf-shaped cartilage that is covered with LARYNGEAL MUCOSA and situated posterior to the root of the tongue and HYOID BONE. During swallowing, the epiglottis folds back over the larynx inlet thus prevents foods from entering the airway.
Pharynx
A funnel-shaped fibromuscular tube that conducts food to the ESOPHAGUS, and air to the LARYNX and LUNGS. It is located posterior to the NASAL CAVITY; ORAL CAVITY; and LARYNX, and extends from the SKULL BASE to the inferior border of the CRICOID CARTILAGE anteriorly and to the inferior border of the C6 vertebra posteriorly. It is divided into the NASOPHARYNX; OROPHARYNX; and HYPOPHARYNX (laryngopharynx).
Larynx
A tubular organ of VOICE production. It is located in the anterior neck, superior to the TRACHEA and inferior to the tongue and HYOID BONE.
Sphenoid Bone
An irregular unpaired bone situated at the SKULL BASE and wedged between the frontal, temporal, and occipital bones (FRONTAL BONE; TEMPORAL BONE; OCCIPITAL BONE). Sphenoid bone consists of a median body and three pairs of processes resembling a bat with spread wings. The body is hollowed out in its inferior to form two large cavities (SPHENOID SINUS).
Tongue
A muscular organ in the mouth that is covered with pink tissue called mucosa, tiny bumps called papillae, and thousands of taste buds. The tongue is anchored to the mouth and is vital for chewing, swallowing, and for speech.
Dentition, Mixed
The complement of teeth in the jaws after the eruption of some of the permanent teeth but before all the deciduous teeth are absent. (Boucher's Clinical Dental Terminology, 4th ed)
Pharyngeal Muscles
The muscles of the PHARYNX are voluntary muscles arranged in two layers. The external circular layer consists of three constrictors (superior, middle, and inferior). The internal longitudinal layer consists of the palatopharyngeus, the salpingopharyngeus, and the stylopharyngeus. During swallowing, the outer layer constricts the pharyngeal wall and the inner layer elevates pharynx and LARYNX.
Esophageal Stenosis
A stricture of the ESOPHAGUS. Most are acquired but can be congenital.
Fluoroscopy
Production of an image when x-rays strike a fluorescent screen.
Nasal Bone
Either one of the two small elongated rectangular bones that together form the bridge of the nose.
Manometry
Measurement of the pressure or tension of liquids or gases with a manometer.
Cephalometry
The measurement of the dimensions of the HEAD.
Mouth
The oval-shaped oral cavity located at the apex of the digestive tract and consisting of two parts: the vestibule and the oral cavity proper.
Esophagus
The muscular membranous segment between the PHARYNX and the STOMACH in the UPPER GASTROINTESTINAL TRACT.
Mandible
The largest and strongest bone of the FACE constituting the lower jaw. It supports the lower teeth.
Electromyography
Recording of the changes in electric potential of muscle by means of surface or needle electrodes.

Assessment of swallowing and referral to speech and language therapists in acute stroke. (1/693)

The best clinical assessment of swallowing following acute stroke, in order to decide whether to refer a patient to a speech and language therapist (SLT), is uncertain. Independently of the managing clinical team, we prospectively investigated 115 patients (51 male) with acute stroke, mean age 75 years (range 24-94) within 72 h of admission, using a questionnaire, structured examination and timed water swallowing test. Outcome variables included referral to and intervention by a speech and language therapist (SLT), dietary modification, respiratory complications and death. Of those patients in whom an SLT recommended intervention, 97% were detected by an abnormal quantitative water swallowing test; specificity was 69%. An SLT was very unlikely to recommend any intervention if the test was normal. Inability to perform a water test and/or abnormality of the test was associated with significantly increased relative risks of death, chest infection and dietary modification. A timed water swallowing test can be a useful test of swallowing and may be used to screen patients for referral to a speech and language therapist after acute stroke.  (+info)

Tachyarrhythmias triggered by swallowing and belching. (2/693)

Three cases with supraventricular tachyarrhythmias related to oesophageal transit are reported. A 61 year old man had episodes of atrial tachycardia on each swallow of food but not liquid; this has been reported only rarely. A 55 year old man had atrial fibrillation initiated by drinking ice cold beverages; this has not been described previously although atrial tachycardia triggered by drinking ice cold beverages has been described once. A 68 year old man had supraventricular tachycardia initiated by belching; this has not been described previously. These cases illustrate the diversity of atrial tachyarrhythmias that can be precipitated by oesophageal stimulation and suggest that what is regarded as a very rare phenomenon may be found more commonly when sought.  (+info)

Multifunctional laryngeal motoneurons: an intracellular study in the cat. (3/693)

We studied the patterns of membrane potential changes in laryngeal motoneurons (LMs) during vocalization, coughing, swallowing, sneezing, and the aspiration reflex in decerebrate paralyzed cats. LMs, identified by antidromic activation from the recurrent laryngeal nerve, were expiratory (ELMs) or inspiratory (ILMs) cells that depolarized during their respective phases in eupnea. During vocalization, most ELMs depolarized and most ILMs hyperpolarized. Some ILMs depolarized slightly during vocalization. During coughing, ELMs depolarized abruptly at the transition from the inspiratory to the expiratory phase. In one-third of ELMs, this depolarization persisted throughout the abdominal burst. In the remainder ("type A"), it was interrupted by a transient repolarization. ILMs exhibited a membrane potential trajectory opposite to that of type A ELMs during coughing. During swallowing, the membrane potential of ELMs decreased transiently at the onset of the hypoglossal burst and then depolarized strongly during the burst. ILMs hyperpolarized sharply at the onset of the burst and depolarized as hypoglossal activity ceased. During sneezing, ELMs and ILMs exhibited membrane potential changes similar to those of type A ELMs and ILMs during coughing. During the aspiration reflex, ELMs and ILMs exhibited bell-shaped hyperpolarization and depolarization trajectories, respectively. We conclude that central drives to LMs, consisting of complex combinations of excitation and inhibition, vary during vocalization and upper airway defensive reflexes. This study provides data for analysis of the neuronal networks that produce these various behaviors and analysis of network reorganization caused by changes in dynamic connections between the respiratory and nonrespiratory neuronal networks.  (+info)

Swallowing function after stroke: prognosis and prognostic factors at 6 months. (4/693)

BACKGROUND AND PURPOSE: Swallowing dysfunction (dysphagia) is common and disabling after acute stroke, but its impact on long-term prognosis for potential complications and the recovery from swallowing dysfunction remain uncertain. We aimed to prospectively study the prognosis of swallowing function over the first 6 months after acute stroke and to identify the important independent clinical and videofluoroscopic prognostic factors at baseline that are associated with an increased risk of swallowing dysfunction and complications. METHODS: We prospectively assembled an inception cohort of 128 hospital-referred patients with acute first stroke. We assessed swallowing function clinically and videofluoroscopically, within a median of 3 and 10 days, respectively, of stroke onset, using standardized methods and diagnostic criteria. All patients were followed up prospectively for 6 months for the occurrence of death, recurrent stroke, chest infection, recovery of swallowing function, and return to normal diet. RESULTS: At presentation, a swallowing abnormality was detected clinically in 65 patients (51%; 95% CI, 42% to 60%) and videofluoroscopically in 82 patients (64%; 95% CI, 55% to 72%). During the subsequent 6 months, 26 patients (20%; 95% CI, 14% to 28%) suffered a chest infection. At 6 months after stroke, 97 of the 112 survivors (87%; 95% CI, 79% to 92%) had returned to their prestroke diet. Clinical evidence of a swallowing abnormality was present in 56 patients (50%; 95% CI, 40% to 60%). Videofluoroscopy was performed at 6 months in 67 patients who had a swallowing abnormality at baseline; it showed penetration of the false cords in 34 patients and aspiration in another 17. The single independent baseline predictor of chest infection during the 6-month follow-up period was a delayed or absent swallowing reflex (detected by videofluoroscopy). The single independent predictor of failure to return to normal diet was delayed oral transit (detected by videofluoroscopy). Independent predictors of the combined outcome event of swallowing impairment, chest infection, or aspiration at 6 months were videofluoroscopic evidence of delayed oral transit and penetration of contrast into the laryngeal vestibule, age >70 years, and male sex. CONCLUSIONS: Swallowing function should be assessed in all acute stroke patients because swallowing dysfunction is common, it persists in many patients, and complications frequently arise. The assessment of swallowing function should be both clinical and videofluoroscopic. The clinical and videofluoroscopic features at presentation that are important predictors of subsequent swallowing abnormalities and complications are videofluoroscopic evidence of delayed oral transit, a delayed or absent swallow reflex, and penetration. These findings require validation in other studies.  (+info)

Identification of the cerebral loci processing human swallowing with H2(15)O PET activation. (5/693)

Lesional and electrophysiological data implicate a role for the cerebral cortex in the initiation and modulation of human swallowing, and yet its functional neuroanatomy remains undefined. We therefore conducted a functional study of the cerebral loci processing human volitional swallowing with 15O-labeled water positron emission tomography (PET) activation imaging. Regional cerebral activation was investigated in 8 healthy right handed male volunteers with a randomized 12-scan paradigm of rest and water swallows (5 ml/bolus, continuous infusion) at increasing frequencies of 0.1, 0.2, and 0.3 Hz, which were visually cued and monitored with submental electromyogram (EMG). Group and individual linear covariate analyses were performed with SPM96. In five of eight subjects, the cortical motor representation of pharynx was subsequently mapped with transcranial magnetic stimulation (TMS) in a posthoc manner to substantiate findings of hemispheric differences in sensorimotor cortex activation seen with PET. During swallowing, group PET analysis identified increased regional cerebral blood flow (rCBF) (P < 0.001) within bilateral caudolateral sensorimotor cortex [Brodmann's area (BA) 3, 4, and 6], right anterior insula (BA 16), right orbitofrontal and temporopolar cortex (BA 11 and 38), left mesial premotor cortex (BA 6 and 24), left temporopolar cortex and amygdala (BA 38 and 34), left superiomedial cerebellum, and dorsal brain stem. Decreased rCBF (P < 0.001) was also observed within bilateral posterior parietal cortex (BA 7), right anterior occipital cortex (BA 19), left superior frontal cortex (BA 8), right prefrontal cortex (BA 9), and bilateral superiomedial temporal cortex (BA 41 and 42). Individual PET analysis revealed asymmetric representation within sensorimotor cortex in six of eight subjects, four lateralizing to right hemisphere and two to left hemisphere. TMS mapping in the five subjects identified condordant interhemisphere asymmetries in the motor representation for pharynx, consistent with the PET findings. We conclude that volitional swallowing recruits multiple cerebral regions, in particular sensorimotor cortex, insula, temporopolar cortex, cerebellum, and brain stem, the sensorimotor cortex displaying strong degrees of interhemispheric asymmetry, further substantiated with TMS. Such findings may help explain the variable nature of swallowing disorders after stroke and other focal lesions to the cerebral cortex.  (+info)

Electromyographic activity from human laryngeal, pharyngeal, and submental muscles during swallowing. (6/693)

The durations and temporal relationships of electromyographic activity from the submental complex, superior pharyngeal constrictor, cricopharyngeus, thyroarytenoid, and interarytenoid muscles were examined during swallowing of saliva and of 5- and 10-ml water boluses. Bipolar, hooked-wire electrodes were inserted into all muscles except for the submental complex, which was studied with bipolar surface electrodes. Eight healthy, normal, subjects produced five swallows of each of three bolus volumes for a total of 120 swallows. The total duration of electromyographic activity during the pharyngeal stage of the swallow did not alter with bolus condition; however, specific muscles did show a volume-dependent change in electromyograph duration and time of firing. Submental muscle activity was longest for saliva swallows. The interarytenoid muscle showed a significant difference in duration between the saliva and 10-ml water bolus. Finally, the interval between the onset of laryngeal muscle activity (thyroarytenoid, interarytenoid) and of pharyngeal muscle firing patterns (superior pharyngeal constrictor onset, cricopharyngeus offset) decreased as bolus volume increased. The pattern of muscle activity associated with the swallow showed a high level of intrasubject agreement; the presence of somewhat different patterns among subjects indicated a degree of population variance.  (+info)

Continuous haemodynamic monitoring in an unusual case of swallow induced syncope. (7/693)

A 69 year old man is described with a 12 year history of intermittent syncope associated with ingesting solid food, mainly after having fasted. He was taking enalapril, propranolol, bendrofluazide (bendroflumethiazide), omeprazole, finasteride, and aspirin. Detailed investigations, including gastrointestinal evaluation, measurement of various gut hormones, and autonomic testing, indicated no abnormality. A liquid meal, performed before fasting, failed to elicit an episode. However, a solid meal after an overnight fast provoked near-syncope. Continuous non-invasive haemodynamic monitoring (with a Portapres II) indicated a short lived rise in blood pressure and heart rate, followed by severe hypotension, a fall in stroke volume and cardiac output, and then bradycardia. This favoured an initial increase in sympathetic activity, followed by vasodepression due to sympathetic withdrawal or activation of humoral vasodilatatory mechanisms, with bradycardia secondary to impaired cardiac filling. Withdrawal of enalapril abolished the episodes. The unusual nature of this case, in which haemodynamic recordings continuously were made during and after swallow syncope, induced soon after food ingestion, is discussed.  (+info)

Cheek and tongue pressures in the molar areas and the atmospheric pressure in the palatal vault in young adults. (8/693)

The pressures acting on the maxillary and mandibular posterior teeth from the tongue and cheeks were measured in 24 adults aged 22-29 years. In addition, the pressure in the palatal vault was recorded. The pressure at two maxillary (buccal and lingual) and two mandibular (buccal and lingual) measuring points, and in the palatal vault was recorded simultaneously. Repeated recordings of the pressures at rest, and during chewing and swallowing were made. The pressures at rest were of similar magnitude (about 2 g/cm2) at the buccal and lingual sides of the mandibular posterior teeth. The median resting pressure at the maxillary posterior teeth was 2.7 g/cm2 on the buccal side and 1.0 g/cm2 on the lingual side. The difference in the maxilla was significant, but not in the mandible. It was concluded that the equilibrium of tooth position is maintained by the pressure from the cheeks and the tongue. During chewing and swallowing the pressures on the lingual side of the teeth were greater than those on the buccal side. At rest about half of the subjects had a negative pressure at the palatal vault, but no correlations between the resting pressure at the palatal vault and the resting pressures on the teeth were found.  (+info)

Deglutition is the physiological process of swallowing, involving orally, pharyngeally, and esophageally coordinated steps to safely transport a bolus from the mouth to the stomach.

Deglutition is the medical term for swallowing. It refers to the process by which food or liquid is transferred from the mouth to the stomach through a series of coordinated muscle movements and neural responses. The deglutition process involves several stages, including oral preparatory, oral transit, pharyngeal, and esophageal phases, each of which plays a critical role in ensuring safe and efficient swallowing.

Dysphagia is the medical term for difficulty with swallowing, which can result from various underlying conditions such as neurological disorders, structural abnormalities, or muscular weakness. Proper evaluation and management of deglutition disorders are essential to prevent complications such as aspiration pneumonia, malnutrition, and dehydration.

Deglutition disorders are conditions characterized by abnormal swallowing function, including difficulties in preparing, transporting, or propelling the swallowed material through the pharynx and esophagus, which can lead to complications such as malnutrition, dehydration, and aspiration pneumonia.

Deglutition disorders, also known as swallowing disorders, are conditions that affect the ability to move food or liquids from the mouth to the stomach safely and efficiently. These disorders can occur at any stage of the swallowing process, which includes oral preparation (chewing and manipulating food in the mouth), pharyngeal phase (activating muscles and structures in the throat to move food toward the esophagus), and esophageal phase (relaxing and contracting the esophagus to propel food into the stomach).

Symptoms of deglutition disorders may include coughing or choking during or after eating, difficulty initiating a swallow, food sticking in the throat or chest, regurgitation, unexplained weight loss, and aspiration (inhaling food or liquids into the lungs), which can lead to pneumonia.

Deglutition disorders can be caused by various factors, such as neurological conditions (e.g., stroke, Parkinson's disease, multiple sclerosis), structural abnormalities (e.g., narrowing or blockage of the esophagus), muscle weakness or dysfunction, and cognitive or behavioral issues. Treatment for deglutition disorders may involve dietary modifications, swallowing exercises, medications, or surgical interventions, depending on the underlying cause and severity of the condition.

The hyoid bone is an U-shaped, highly mobile, and unique bone in the human body, located in the anterior neck, superior to the thyroid cartilage, that functions as a attachment point for various muscles involved in swallowing, respiration, and speech, and is not connected to any other bones but suspended in the neck by strong muscular and ligamentous attachments.

The hyoid bone is a U-shaped bone located in the anterior neck, superior to the thyroid cartilage. It does not articulate with any other bones and serves as an attachment point for various muscles, including those involved in swallowing, breathing, and speaking. The unique structure of the hyoid bone allows it to support the tongue and contribute to the stability of the airway.

The upper esophageal sphincter (UES), also known as the cricopharyngeus, is a specialized ring-like muscle located at the upper end of the esophagus, forming a high-pressure zone that maintains a one-way barrier to prevent air from entering the digestive tract while permitting the passage of food from the pharynx into the esophagus during swallowing.

The upper esophageal sphincter (UES) is a band of muscle fibers located at the upper end of the esophagus, where it meets the throat or pharynx. The UES acts as a physiological barrier between the pharynx and the esophagus, helping to prevent the reflux of gastric contents into the upper airway.

During swallowing, the UES relaxes to allow the passage of food from the mouth into the esophagus, and then contracts again to prevent the backflow of food or stomach acid into the throat. The UES also plays a role in protecting the airway during activities such as coughing, sneezing, or vomiting, by closing to prevent the entry of foreign materials or fluids into the lungs.

Abnormalities in UES function can contribute to various swallowing disorders and respiratory symptoms, such as aspiration, coughing, and choking.

The oropharynx is the part of the pharynx that lies posterior to the oral cavity, extending from the soft palate anteriorly to the epiglottis and including the tonsils, palatine and lingual pillars, and base of tongue.

The oropharynx is the part of the throat (pharynx) that is located immediately behind the mouth and includes the back one-third of the tongue, the soft palate, the side and back walls of the throat, and the tonsils. It serves as a passageway for both food and air, and is also an important area for the immune system due to the presence of tonsils.

Progressive Bulbar Palsy (PBP) is a form of neurodegenerative disorder, specifically a motor neuron disease, characterized by the deterioration of the bulbar muscles that control swallowing, speaking, chewing, and sometimes breathing, due to the degeneration of lower brainstem nerve cells, often progressing to significant disability and shortened lifespan.

Progressive bulbar palsy (PBP) is a form of motor neuron disease (MND), also known as Amyotrophic Lateral Sclerosis (ALS). It is characterized by the progressive degeneration of the motor neurons in the brainstem, which control vital functions such as swallowing, speaking, chewing, and breathing.

In PBP, these symptoms gradually worsen over time, often resulting in severe disability and ultimately death due to respiratory failure. The progression of the disease can vary from person to person, but it typically advances more slowly than other forms of ALS. There is currently no cure for PBP or any other form of MND, and treatment is focused on managing symptoms and maintaining quality of life.

Mastication is the primarily oral process of manually breaking down food into smaller pieces through repetitive chewing movements, facilitated by the rhythmic contractions of jaw muscles, for enhanced swallowing and digestion.

Mastication is the medical term for the process of chewing food. It's the first step in digestion, where food is broken down into smaller pieces by the teeth, making it easier to swallow and further digest. The act of mastication involves not only the physical grinding and tearing of food by the teeth but also the mixing of the food with saliva, which contains enzymes that begin to break down carbohydrates. This process helps to enhance the efficiency of digestion and nutrient absorption in the subsequent stages of the digestive process.

The hypopharynx is the lower part of the pharynx, extending from the level of the hyoid bone to the lower border of the cricoid cartilage, and it serves as a passageway for both food and air during swallowing and breathing processes.

The hypopharynx is the lower part of the pharynx, which is the muscular tube that extends from the back of the nasal cavity and mouth to the esophagus and trachea. The hypopharynx lies posterior to the larynx and is divided into three regions: the pyriform (or piriform) sinuses, the postcricoid area, and the posterior pharyngeal wall. It serves as a passageway for both food and air, and any abnormalities or diseases in this region can lead to swallowing difficulties, aspiration, and other serious medical conditions.

The epiglottis is a leaf-shaped structure, composed of elastic cartilage, located at the root of the tongue and covered by mucous membrane, which functions to direct food into the esophagus and protect the larynx during swallowing.

The epiglottis is a flap-like structure located at the base of the tongue, near the back of the throat (pharynx). It is made of elastic cartilage and covered with mucous membrane. The primary function of the epiglottis is to protect the trachea (windpipe) from food or liquids entering it during swallowing.

During normal swallowing, the epiglottis closes over the opening of the larynx (voice box), redirecting the food or liquid bolus into the esophagus. In this way, the epiglottis prevents aspiration, which is the entry of foreign materials into the trachea and lungs.

Inflammation or infection of the epiglottis can lead to a serious medical condition called epiglottitis, characterized by swelling, redness, and pain in the epiglottis and surrounding tissues. Epiglottitis can cause difficulty breathing, speaking, and swallowing, and requires immediate medical attention.

The pharynx is a musculocartilaginous tube that serves as a common passageway for food and air, extending from the base of the skull to the cricoid cartilage where it bifurcates into the larynx and esophagus. (Aerospace Medical Association - AsMA)

The pharynx is a part of the digestive and respiratory systems that serves as a conduit for food and air. It is a musculo-membranous tube extending from the base of the skull to the level of the sixth cervical vertebra where it becomes continuous with the esophagus.

The pharynx has three regions: the nasopharynx, oropharynx, and laryngopharynx. The nasopharynx is the uppermost region, which lies above the soft palate and is connected to the nasal cavity. The oropharynx is the middle region, which includes the area between the soft palate and the hyoid bone, including the tonsils and base of the tongue. The laryngopharynx is the lowest region, which lies below the hyoid bone and connects to the larynx.

The primary function of the pharynx is to convey food from the oral cavity to the esophagus during swallowing and to allow air to pass from the nasal cavity to the larynx during breathing. It also plays a role in speech, taste, and immune defense.

The larynx is the complex, ring-like, superior part of the airway in the neck, containing the vocal cords and functioning primarily for voice production, protecting the lower airway during swallowing, and controlling the diameter of the trachea during breathing. (26 words)

The larynx, also known as the voice box, is a complex structure in the neck that plays a crucial role in protection of the lower respiratory tract and in phonation. It is composed of cartilaginous, muscular, and soft tissue structures. The primary functions of the larynx include:

1. Airway protection: During swallowing, the larynx moves upward and forward to close the opening of the trachea (the glottis) and prevent food or liquids from entering the lungs. This action is known as the swallowing reflex.
2. Phonation: The vocal cords within the larynx vibrate when air passes through them, producing sound that forms the basis of human speech and voice production.
3. Respiration: The larynx serves as a conduit for airflow between the upper and lower respiratory tracts during breathing.

The larynx is located at the level of the C3-C6 vertebrae in the neck, just above the trachea. It consists of several important structures:

1. Cartilages: The laryngeal cartilages include the thyroid, cricoid, and arytenoid cartilages, as well as the corniculate and cuneiform cartilages. These form a framework for the larynx and provide attachment points for various muscles.
2. Vocal cords: The vocal cords are thin bands of mucous membrane that stretch across the glottis (the opening between the arytenoid cartilages). They vibrate when air passes through them, producing sound.
3. Muscles: There are several intrinsic and extrinsic muscles associated with the larynx. The intrinsic muscles control the tension and position of the vocal cords, while the extrinsic muscles adjust the position and movement of the larynx within the neck.
4. Nerves: The larynx is innervated by both sensory and motor nerves. The recurrent laryngeal nerve provides motor innervation to all intrinsic laryngeal muscles, except for one muscle called the cricothyroid, which is innervated by the external branch of the superior laryngeal nerve. Sensory innervation is provided by the internal branch of the superior laryngeal nerve and the recurrent laryngeal nerve.

The larynx plays a crucial role in several essential functions, including breathing, speaking, and protecting the airway during swallowing. Dysfunction or damage to the larynx can result in various symptoms, such as hoarseness, difficulty swallowing, shortness of breath, or stridor (a high-pitched sound heard during inspiration).

The sphenoid bone is an unpaired, irregularly shaped bone in the middle cranial fossa and base of the skull that forms part of the orbit, nasal cavity, and pterygoid processes.

The sphenoid bone is a complex, irregularly shaped bone located in the middle cranial fossa and forms part of the base of the skull. It articulates with several other bones, including the frontal, parietal, temporal, ethmoid, palatine, and zygomatic bones. The sphenoid bone has two main parts: the body and the wings.

The body of the sphenoid bone is roughly cuboid in shape and contains several important structures, such as the sella turcica, which houses the pituitary gland, and the sphenoid sinuses, which are air-filled cavities within the bone. The greater wings of the sphenoid bone extend laterally from the body and form part of the skull's lateral walls. They contain the superior orbital fissure, through which important nerves and blood vessels pass between the cranial cavity and the orbit of the eye.

The lesser wings of the sphenoid bone are thin, blade-like structures that extend anteriorly from the body and form part of the floor of the anterior cranial fossa. They contain the optic canal, which transmits the optic nerve and ophthalmic artery between the brain and the orbit of the eye.

Overall, the sphenoid bone plays a crucial role in protecting several important structures within the skull, including the pituitary gland, optic nerves, and ophthalmic arteries.

The tongue is a muscular, sensory organ in the oral cavity responsible for taste perception, speech articulation, and manipulation of food during swallowing and mastication.

In medical terms, the tongue is a muscular organ in the oral cavity that plays a crucial role in various functions such as taste, swallowing, and speech. It's covered with a mucous membrane and contains papillae, which are tiny projections that contain taste buds to help us perceive different tastes - sweet, salty, sour, and bitter. The tongue also assists in the initial process of digestion by moving food around in the mouth for chewing and mixing with saliva. Additionally, it helps in forming words and speaking clearly by shaping the sounds produced in the mouth.

Mixed dentition is a transitional stage of dental development during which both deciduous (primary) and permanent teeth are present in the oral cavity.

Mixed dentition is a stage of dental development in which both primary (deciduous) teeth and permanent teeth are present in the mouth. This phase typically begins when the first permanent molars erupt, around the age of 6, and continues until all of the primary teeth have been replaced by permanent teeth, usually around the age of 12-13.

During this stage, a person will have a mix of smaller, temporary teeth and larger, more durable permanent teeth. Proper care and management of mixed dentition is essential for maintaining good oral health, as it can help to prevent issues such as crowding, misalignment, and decay. Regular dental check-ups and proper brushing and flossing techniques are crucial during this stage to ensure the best possible outcomes for long-term oral health.

'Pharyngeal muscles' are a group of voluntary and involuntary muscles that form the walls and constrictors of the pharynx, responsible for swallowing, speaking, and respiration.

The pharyngeal muscles, also known as the musculature of the pharynx, are a group of skeletal muscles that make up the walls of the pharynx, which is the part of the throat located just above the esophagus and behind the nasal and oral cavities. These muscles play a crucial role in several vital functions, including:

1. Swallowing (deglutition): The pharyngeal muscles contract in a coordinated sequence to propel food or liquids from the mouth through the pharynx and into the esophagus during swallowing.
2. Speech: The contraction and relaxation of these muscles help shape the sounds produced by the vocal cords, contributing to the production of speech.
3. Respiration: The pharyngeal muscles assist in maintaining an open airway during breathing, especially during sleep and when the upper airways are obstructed.

The pharyngeal muscles consist of three layers: the outer circular muscle layer, the middle longitudinal muscle layer, and the inner inferior constrictor muscle layer. The specific muscles that make up these layers include:

1. Superior constrictor muscle (outer circular layer)
2. Middle constrictor muscle (middle longitudinal layer)
3. Inferior constrictor muscle (inner inferior constrictor layer)
4. Stylopharyngeus muscle
5. Salpingopharyngeus muscle
6. Palatopharyngeus muscle
7. Buccinator muscle (partially contributes to the middle longitudinal layer)

These muscles work together to perform their various functions, and any dysfunction in these muscles can lead to problems like swallowing difficulties (dysphagia), speech impairments, or respiratory issues.

Esophageal stenosis is a medical condition characterized by the narrowing or stricture of the esophageal lumen, causing difficulty in swallowing solid or liquid substances, and potentially leading to food impaction, pain, or weight loss.

Esophageal stenosis is a medical condition characterized by the narrowing or constriction of the esophagus, which is the muscular tube that connects the throat to the stomach. This narrowing can make it difficult to swallow food and liquids, leading to symptoms such as dysphagia (difficulty swallowing), pain or discomfort while swallowing, regurgitation, and weight loss.

Esophageal stenosis can be caused by a variety of factors, including:

1. Scarring or fibrosis due to prolonged acid reflux or gastroesophageal reflux disease (GERD)
2. Radiation therapy for cancer treatment
3. Ingestion of corrosive substances
4. Eosinophilic esophagitis, an allergic condition that affects the esophagus
5. Esophageal tumors or cancers
6. Surgical complications

Depending on the underlying cause and severity of the stenosis, treatment options may include medications to manage symptoms, dilation procedures to widen the narrowed area, or surgery to remove the affected portion of the esophagus. It is important to seek medical attention if you experience any difficulty swallowing or other symptoms related to esophageal stenosis.

Fluoroscopy is a medical imaging technique that uses X-rays to obtain real-time moving images of the internal structures of a patient, allowing physicians to visualize and assess various body systems and guide minimally invasive procedures.

Fluoroscopy is a type of medical imaging that uses X-rays to obtain real-time moving images of the internal structures of the body. A continuous X-ray beam is passed through the body part being examined, and the resulting fluoroscopic images are transmitted to a monitor, allowing the medical professional to view the structure and movement of the internal organs and bones in real time.

Fluoroscopy is often used to guide minimally invasive procedures such as catheterization, stent placement, or joint injections. It can also be used to diagnose and monitor a variety of medical conditions, including gastrointestinal disorders, musculoskeletal injuries, and cardiovascular diseases.

It is important to note that fluoroscopy involves exposure to ionizing radiation, and the risks associated with this exposure should be carefully weighed against the benefits of the procedure. Medical professionals are trained to use the lowest possible dose of radiation necessary to obtain the desired diagnostic information.

The nasal bone is a small paired bone in the middle of the upper part of the face that forms the bridge of the nose and articulates with the frontal, maxilla, lacrimal and inferior nasal conchae bones.

The nasal bones are a pair of small, thin bones located in the upper part of the face, specifically in the middle of the nose. They articulate with each other at the nasal bridge and with the frontal bone above, the maxillae (upper jaw bones) on either side, and the septal cartilage inside the nose. The main function of the nasal bones is to form the bridge of the nose and protect the nasal cavity. Any damage to these bones can result in a fracture or broken nose.

Manometry is a diagnostic technique that measures muscle pressures in various parts of the digestive system to evaluate motility disorders, using an intraluminal catheter equipped with pressure sensors.

Manometry is a medical test that measures pressure inside various parts of the gastrointestinal tract. It is often used to help diagnose digestive disorders such as achalasia, gastroparesis, and irritable bowel syndrome. During the test, a thin, flexible tube called a manometer is inserted through the mouth or rectum and into the area being tested. The tube is connected to a machine that measures and records pressure readings. These readings can help doctors identify any abnormalities in muscle function or nerve reflexes within the digestive tract.

Cephalometry is a radiographic method used in orthodontics and maxillofacial surgery for the analysis of the dental and skeletal relationships within the head, typically involving the measurement of angles and distances between specific landmarks on a cephalometric radiograph.

Cephalometry is a medical term that refers to the measurement and analysis of the skull, particularly the head face relations. It is commonly used in orthodontics and maxillofacial surgery to assess and plan treatment for abnormalities related to the teeth, jaws, and facial structures. The process typically involves taking X-ray images called cephalograms, which provide a lateral view of the head, and then using various landmarks and reference lines to make measurements and evaluate skeletal and dental relationships. This information can help clinicians diagnose problems, plan treatment, and assess treatment outcomes.

'Mouth' is anatomically defined as the oral cavity, consisting of the lips, vestibule, teeth, hard and soft palates, tongue, floor of the mouth, and oropharynx, which serves as the initial site for ingestion, digestion, speech, and respiration.

In medical terms, the mouth is officially referred to as the oral cavity. It is the first part of the digestive tract and includes several structures: the lips, vestibule (the space enclosed by the lips and teeth), teeth, gingiva (gums), hard and soft palate, tongue, floor of the mouth, and salivary glands. The mouth is responsible for several functions including speaking, swallowing, breathing, and eating, as it is the initial point of ingestion where food is broken down through mechanical and chemical processes, beginning the digestive process.

The esophagus is the muscular tubular structure that transports food and liquids from the pharynx to the stomach through peristaltic movements, and is composed of an inner mucous membrane, a middle submucosal layer, an outer muscular layer, and an adventitial covering.

The esophagus is the muscular tube that connects the throat (pharynx) to the stomach. It is located in the midline of the neck and chest, passing through the diaphragm to enter the abdomen and join the stomach. The main function of the esophagus is to transport food and liquids from the mouth to the stomach for digestion.

The esophagus has a few distinct parts: the upper esophageal sphincter (a ring of muscle that separates the esophagus from the throat), the middle esophagus, and the lower esophageal sphincter (another ring of muscle that separates the esophagus from the stomach). The lower esophageal sphincter relaxes to allow food and liquids to enter the stomach and then contracts to prevent stomach contents from flowing back into the esophagus.

The walls of the esophagus are made up of several layers, including mucosa (a moist tissue that lines the inside of the tube), submucosa (a layer of connective tissue), muscle (both voluntary and involuntary types), and adventitia (an outer layer of connective tissue).

Common conditions affecting the esophagus include gastroesophageal reflux disease (GERD), Barrett's esophagus, esophageal cancer, esophageal strictures, and eosinophilic esophagitis.

The mandible is the lower and larger of the two bones that make up the human jaw, articulating with the skull at the temporomandibular joint and consisting of a horizontal body and two perpendicular rami, involved in crucial functions such as mastication, speech, and respiration. (27 words)

The mandible, also known as the lower jaw, is the largest and strongest bone in the human face. It forms the lower portion of the oral cavity and plays a crucial role in various functions such as mastication (chewing), speaking, and swallowing. The mandible is a U-shaped bone that consists of a horizontal part called the body and two vertical parts called rami.

The mandible articulates with the skull at the temporomandibular joints (TMJs) located in front of each ear, allowing for movements like opening and closing the mouth, protrusion, retraction, and side-to-side movement. The mandible contains the lower teeth sockets called alveolar processes, which hold the lower teeth in place.

In medical terminology, the term "mandible" refers specifically to this bone and its associated structures.

Electromyography (EMG) is a diagnostic procedure that evaluates the electrical activity of muscles at rest and during contraction, recorded via needle or surface electrodes, to detect neuromuscular abnormalities, muscle disorders, or nerve injuries.

Electromyography (EMG) is a medical diagnostic procedure that measures the electrical activity of skeletal muscles during contraction and at rest. It involves inserting a thin needle electrode into the muscle to record the electrical signals generated by the muscle fibers. These signals are then displayed on an oscilloscope and may be heard through a speaker.

EMG can help diagnose various neuromuscular disorders, such as muscle weakness, numbness, or pain, and can distinguish between muscle and nerve disorders. It is often used in conjunction with other diagnostic tests, such as nerve conduction studies, to provide a comprehensive evaluation of the nervous system.

EMG is typically performed by a neurologist or a physiatrist, and the procedure may cause some discomfort or pain, although this is usually minimal. The results of an EMG can help guide treatment decisions and monitor the progression of neuromuscular conditions over time.

DisordersRespirationPhase of deglutitionPrinciples of DeglutitionDysphagiaIngestionBolusParkinson'sAspirationSwallowingPeristalsisReflexInvoluntaryMalnutritionElderlyPhysiologyComplicationsInvolvesDigestiveOccurPainMuscleAffectImproveMedicalProcess
Disorders5
  • Principles of Deglutition: A Multidisciplinary Text for Swallowing and its Disorders. (uky.edu)
  • 1. Disorders like dysphagia can disrupt the smooth process of deglutition. (betterwordsonline.com)
  • 25. Disorders of deglutition can be caused by structural abnormalities, neurological conditions, or muscle weakness. (betterwordsonline.com)
  • 12, Supplement( July, 1944) 118 download Principles of Deglutition: A Multidisciplinary Text for Swallowing and its Disorders Cowles Commission Paper, New Series, b CrossRefGoogle ScholarHood, Wm. (global-apa.com)
  • There were no deglutition or sphincter disorders or difficulty breathing. (who.int)
Respiration1
  • Paralysis may affect phonation, respiration, and deglutition, and food and fluids may be aspirated into the trachea. (msdmanuals.com)
Phase of deglutition4
  • 8. The oral phase of deglutition involves forming a bolus of food. (betterwordsonline.com)
  • Receptors in the posterior pharynx are then activated to initiate the involuntary phase of deglutition, which involves carefully sequenced contraction of numerous head and neck muscles. (nature.com)
  • Once this oropharyngeal phase has served to propel the bolus into the esophagus, the esophageal phase of deglutition takes over. (nature.com)
  • The reader is referred to other comprehensive reviews for detailed discussion of the physiology of the LES and oropharyngeal phase of deglutition. (nature.com)
Principles of Deglutition1
  • A download Principles of Deglutition: A Multidisciplinary Text for between multiple and structural member-states new to the l of innovative Seeing here discussed threatened enabled by Orcutt( 1952). (global-apa.com)
Dysphagia1
Ingestion2
  • Difficulties with ingestion, deglutition and low energy were associated with assisted eating, and low energy with malnutrition (Paper III). (avhandlingar.se)
  • Discharge to institutional care was explained by living alone before admission, ingestion difficulties at discharge, male gender and high age (Paper V). It is of great importance to assess and take systematic measures for each of the three categories of eating difficulties, i.e. ingestion, deglutition and energy to improve eating abilities. (avhandlingar.se)
Bolus1
  • The UES opens almost immediately upon activation of the deglutition reflex, allowing the food bolus to pass through. (nature.com)
Parkinson's2
  • 19. Certain medical conditions can affect deglutition, such as Parkinson's disease. (betterwordsonline.com)
  • Deep-brain-stimulation does not impair deglutition in Parkinson's disease. (mpg.de)
Aspiration2
Swallowing2
  • 11. Deglutition difficulties may require modified diets and swallowing exercises. (betterwordsonline.com)
  • 24. The study of deglutition involves assessing the anatomy and physiology of the swallowing process. (betterwordsonline.com)
Peristalsis2
  • Esophageal peristalsis can be initiated by deglutition ("primary" peristalsis) or local distention ("secondary" peristalsis). (nature.com)
  • We studied the genesis of isolated LES relaxation in anesthetized opossums by observing the response of four components of the deglutition reflex (mylohyoid electrical activity, pharyngeal contraction, esophageal peristalsis, and LES relaxation) to pharyngeal tactile stimulation, electrical stimulation of superior laryngeal nerve (SLN) afferents or cervical vagal efferents, and to balloon distention of the esophageal body. (jci.org)
Reflex2
  • 18. Infants have to learn how to control their deglutition reflex. (betterwordsonline.com)
  • Deglutition is one of the most complex reflex neural activities. (nature.com)
Involuntary1
Malnutrition1
Elderly1
  • 22. Elderly people may experience difficulty with deglutition due to age-related changes. (betterwordsonline.com)
Physiology1
Complications3
  • In the postoperative period, an early evaluation was performed, analyzing local and systemic complications and late (average 5.6 y) analyzing deglutition. (scielo.br)
  • Cervical esophagogastric anastomosis by means of mechanical suture is more proper than the manual with lower incidence of local complications and, in the long-term evaluation, regular deglutition was acquired in both suture techniques in equal quality. (scielo.br)
  • The goals of laceration repair of the tongue are to attain adequate closure, stop bleeding, minimize complications, preserve mobility, and optimize articulation and deglutition. (medscape.com)
Involves1
Digestive1
Occur1
  • A full four-component deglutition sequence was most likely to occur at the higher frequencies of SLN electrical stimulation. (jci.org)
Pain2
Muscle1
  • and actively assisted muscle strengthen- improve the outcome of adverse events There were no deglutition or sphinc- ing and functional work. (who.int)
Affect1
Improve1
Medical1
Process2

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