Structure and Function of the Human Tongue
This study will use magnetic resonance imaging (MRI) and ultrasound to examine changes in tongue volume and blood circulation during tongue exercises that require the use of different tongue muscle movements and contractions. More information on the structure and function of the human tongue is needed to develop better treatments for people with certain diseases affecting speech and swallowing.
Normal volunteers between 21 and 80 years old who live in the metropolitan Washington, D.C., area may be eligible for this study. Candidates will be screened with a brief medical history and physical examination, including suitability for MRI testing, and a brief examination of tongue, lip and jaw movements.
Participants will undergo ultrasound and MRI studies. During both tests, they will perform tongue exercises, such as holding a soft round object on the tongue or exerting tongue pressure against the back of the throat or roof of the mouth.
During the ultrasound, the subject lies on a flattened dental chair. A small transducer is placed under the chin to take images of the tongue during the exercises. A thin rubber strip with air-filled pressure bulbs is attached to the roof of the mouth (with dental adhesive) to measure tongue pressure.
For the MRI, the subject lies on a table that slides inside a donut's machine containing a magnetic field. MRI coils-special padded sensors that improve image quality-are placed around the head and neck. A pressure cuff placed around the arm measures blood pressure. The subject wears earplugs to muffle loud thumping noises that occur during electrical switching of the magnetic fields. The subject is in constant visual contact with the researchers and MR technologist and may request to stop the study at any time.
Participants may undergo another procedure, called magnetic resonance diffusion tensor imaging, to examine how the fluid (water) in the tongue tissue shifts during tongue maneuvers. This procedure is essentially the same as the first MRI study, but two small round coils are placed in the mouth (one on each side) between the cheeks and the teeth.
|Official Title:||Task-Induced Physiological and Biomechanical Changes of the In Vivo Human Tongue|
|Study Start Date:||December 2000|
|Estimated Study Completion Date:||April 2007|
As an organ unparalleled in anatomical architecture, the tongue has the versatility to effect regional deformations and positional changes with multiple potential degrees of freedom. Despite an abundance of studies on the tongue and its functions, as well as numerous proposed tongue models over the years, much of the anatomical and biomechanical details of the in vivo human tongue remain poorly understood. Physiologically based biomechanical modeling of the tongue in swallowing is the ultimate objective of this protocol. However, before such modeling can be accurately pursued, a substantial database must be established, and several important, unaddressed issues regarding lingual anatomy and biomechanics must be resolved. These issues include: (1) the compressibility of the human tongue and its common, yet untested, reference as a muscular hydrostat; (2) task induced interactions between lingual musculature and vasculature and region-specific vascular demands; (3) changes in lingual fiber orientation, length, and strain distribution as a function of contraction tasks; and (4) effects of normal aging, disease processes, and task training on lingual myoarchitecture as well as the integration between structure and function. Using advanced 3D MRI, Doppler ultrasonography, and other MR imaging techniques (e.g., tagged MRI, diffusion tensor MRI), this protocol proposes to quantitatively address these issues and contribute to a better understanding of the functional biomechanical as well as myoarchitectural intricacies of the in vivo human tongue.
Please refer to this study by its ClinicalTrials.gov identifier: NCT00007137
|United States, Maryland|
|National Institutes of Health Clinical Center, 9000 Rockville Pike|
|Bethesda, Maryland, United States, 20892|