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THERAPUTIC MANAGEMENT OF LARYNGETOMY
Introduction
The goal of speech therapy for a laryngectomized patient is to find an appropriate
source of sound production that can be articulated for communication purposes. The
most efficient and effective type of sound source depends on:
Degree of tissue loss, the degree of esophageal stenosis, level of hearing loss, orother physical limitations of the patient. The noise level of the environment in
which the patient needs to communicate.
The patients level of motivation in learning an alternative method ofcommunication.
The personal preference of the patient.Fortunately, there are a variety of devices and procedures that can provide a new
source of sound. The patient can then use his or her articulators to produce the sounds of
speech.
There are two general categories of sound restoration:
Mechanical speech aids includes the pneumatic and electronic artificial soundsources.
Alternative natural sound sources include esophageal tracheoesophageal speech,other surgically implanted prostheses and surgically created structures.
The various mechanical speech aids and voice prostheses are discussed in the
following sections
MECHANICAL SPEECH AIDS
I. PNEUMATIC DEVICES
A. Description
Pneumatic speech devices were among the first to be used as replacements for
voice production and are still in use today. They usually consist of a piece that fits over
the stoma, a small unit with a reed inside to provide sound, and tubing that carries the
sound to the mouth. The patient places the tube in the corner of his or her mouth as
exhalatory air from the lungs drives the reed to produce sound that is resonated in the
usual way in the patients oral cavity and shaped into words by the action of the
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articulators. Hand held models do not require valving mechanisms since they can be
lifted from the stoma to allow the patient to breathe.
B. Specific Types
1. Dutch speech DSPB speech aid
In this device, the vibrator is housed within the tubing. It is rather inexpensive
(about $ 90 US).
2. Tokyo artificial larynx
This has been described by Bloom & Mowrer & Case. This device is an
inexpensive unit (about $ 50.00) and is supplied with an additional oral tube, stoma
cushion, and training tape. It has been demonstrated that patient using this device under
optimal condition can achieve a 95% intelligibility level. The modified version consists
of swivel-joint connector on the tracheostoma cover and a mouth tube constructed of
curved stainless steel tubing capped by a plastic mouth piece.
3. Osaka artificial larynx:
It is very similar to Tokyo artificial larynx. It consists of a tracheostoma cover, a
vibrating reed and a mouth piece. It differs from Tokyo artificial larynx in that it is made
up of light weight plastic.
C. Advantages
The two major advantages of a pneumatic device are that it does not have a
buzzing electronic sound and it uses the patients own pulmonary air supply. Phonation
can be easily coordinated with respiration and loud voice can be produced. The patient
can use his or her normal phrasing and flow of speech without the need to turn an
oscillator on and off.
D. Disadvantages
There are several problems with the pneumatic devices. First, they require access
to the stoma for placement of the instrument. Most patients typically wear some kind of
covering over the stoma, making access to it awkward. Second, they require the use of
one hand thus limiting the patients ability to perform tasks requiring the use of both
hands. Third, they are visually distracting to the listener. Some believe that they are a
sign of patients disabilities rather than their abilities. Other problems include the lack of
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pitch control and the low fundamental frequency which may be a problem for a female
user.
II. Electronic Devices
A. Description
These devices use electric power to drive a vibrator that provides the sound
source. Two versions of these devices are available.
Tube-in-the-mouth-type instruments: Consists of a tube attached to theelectrically powered hand held transducer. The tube fits inside the mouth in much
the same way as the pneumatic devices. Electronically generated sound is
delivered to the oral cavity via the tube which is articulated in the normal way.
Handheld type instrument consists of a hand held vibrator that is designed todeliver the sound through the skin when placed on the neck.
There are numerous manufacturers who produce electronic speech aids powered
by batteries. The differences among the aids are appearance, size, quality of sound,
ability to change pitch and loudness characteristics and the types of batteries required.
B. Specific types
1. Tube-in-the-mouth-type instruments:
a. Cooper-Rand Electronic Speech AidThis device is a battery powered sound source that directs the sound into the oral
cavity via a small tube placed in the mouth. It is the only instrument that is designed to
be used exclusively as an oral device. Oral placement may be advantageous immediately
after surgery because the patient can use it without interfering with neck healing or
causing discomfort. The unit is lightweight (about 7 oz) and can be carried in a shirt or
blouse pocket. An extra long cord (40 in) permits placing the device in other locations as
well, such as on a table or a bed. The unit is controlled from the push button on the tone
generator to which the oral tube is attached.
b. Ticchioni pipe artificial larynx:
Looks like a smokers pipe with the battery attached to the base of the pipe bowl.
The tone is generated in the pipe bowl and conducted to the patients mouth via the pipe
stem.
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II. Hand held type instrument
a. Jedcom electrolarynx
This device is a neck held electric sound source with a built in pitch and volume
control and a convenient on-off switch and safety cord. It is powered by a rechargeable
battery.
b. Neovox
This device is a neck held electro larynx with a single button control for volume
and contains a safety strap. It uses a rechargeable battery.
c. Romet speech aid
This device is a small, lightweight (5 oz), neck held electronic sound source that
uses rechargeable batteries. The unit is held against the neck, a button is depressed to
turn it on, and the sound is articulated by the patient. The unit is equipped with a volume
control as well as a pitch control.
d. Servox Intonation Control
This device is an electronic, neck held sound source. The unit is tubular and
sealed in a scratch resistant case. It has an electronic volume control that reduces power
consumption and has rechargeable batteries. intonation control that varies the pitch and
sound of the unit during speech to permit some type of inflection control. An intraoral
connector is also available to permit the use of the instrument immediately after surgery
or if the patient prefers to use it in this manner.
e. SPKR
This device is another electronic, hand held sound source that is placed against the
neck to direct sound through the skin into the vocal tract. It features a dual tone rocker
switch to volume control, an external pitch adjustment and an oral adaptor. It uses
rechargeable batteries and has a safety strap.
f. Western Electric Artificial Larynx
It is the most popular one and is available in models that are pitched differently
for males (model 5B) and females (5A). This device is a neck held, 9 volt battery
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powered device. It is lightweight, can be carried on a pocket or purse, or hung around the
neck. The unit is activated by a single switch controlled by the patients thumb. This is
probably the lowest priced unit available (under $300), and it offers pitch and volume
controls.
Advantages
The major advantages of the electric powered speech aids (and to some degree the
pneumatic devices) is the ability to offer a rapidly learned means of communication. The
devices can be demonstrated prior to surgery and require little effort to use immediately
after surgery. They are easily portable. Some permit a limited ability to vary the
fundamental frequency (FF) of the voice during speech to achieve some measure of pitch
inflection. Many are available with an intraoral adapter. The adapter fits over the
membrane or vibrator and usually uses a small plastic tube to direct the sound into the
vocal tract. This adapter permits the use of the instrument immediately after surgery
when the neck wound is healing. Patients experience an immediate restoration of their
ability to communicate. After wound healing is complete, patients may use the device in
either manner, for example, against the skin of the neck or as an oral unit.
D. Disadvantages
All of these devices tend to produce a mechanical sound that may be distracting
to a listener and may interfere with communication. Most require the use of one hand,
limiting the ability of the patient to use both hands when talking. Most have very limited
control of fundamental frequency which limits normal pitch inflection of the patients
speech. In addition, it may be cumbersome to use the pitch altering mechanisms that are
available. There are some operating expenses, because the batteries wear out, and
mechanical devices may need occasional repair.
Indications for use
1) An oral type of instrument can be used effectively soon after surgery, regardless of the
type of alaryngeal speech the patient will choose to pursue.
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2) An electronic speech aid may be a preferred primary means of communication for
some persons. Patients who are elderly and infirm and whose life style involves minimal
communication may choose an instrument.
3) A person who is very eager to speak and cannot tolerate the frustration or demands for
practicing of esophageal speech may be happy with an instrument.
4) The person who cannot master esophageal speech and does not wish to undergo further
surgery may choose to use an electronic instrument.
5) All laryngectomees should have an instrument and know how to use it as a backup or
insurance policy in case of emergency.
ALTERNATIVE NATURAL SOURCES
I. ESOPHAGEAL SPEECH
A. Description
Esophageal speech involves the production of a voice source within the
esophagus using air supplied by the patient. The esophagus is a muscular tube that
begins just behind the larynx. The most inferior portion of the inferior constrictor
muscle, called the cricopharyngeus, extends from the cricoid cartilage to insert on
portions of the pharynx posteriorly and into the esophagus. Surgeons attempt to leave
this muscle intact during laryngectomy so it can be used to constrict the esophagus and
permit the trapping of air inferiorly. When the air is expelled through a narrow
constriction in the esophagus created by the cricopharyngeus muscle, the narrowed
segment (the pharyngeal esophageal or PE segment) will vibrate, producing sound. The
patient has the capability of producing periodic sound at the beginning of the vocal tract
similar to that produced in normal speech.
B. Anatomy of esophageal speech
Surgical alterations
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Surgery for laryngeal carcinoma may involve only the larynx itself (and
associated extrinsic muscles), or it may require the extirpation of other structures and
muscles in the neck. In the simplest case, the patient may have lost only the larynx. This
means, of course, that the source of sound for speech is missing. The larynx and the
hyoid bone are typically removed during a routine laryngectomy. The trachea is sutured
to the front of the neck where a permanent opening called the tracheostoma is created.
On the left are the normal anatomical relationships among the larynx, esophagus, pharynx
and oral and nasal cavities. On the right are the surgical alterations to this anatomy.
There are, of course, little or no surgical changes to the esophagus during the procedure.
However, esophageal speech depends on the ability of the esophagus to constrict at a
region. This region is known as the pharyngeal esophageal segment (or simply the PE
segment).
PE Segment
This refers to that portion of the pharynx and esophagus where muscle fibers fro
the inferior constrictor, cricopharyngeus (or the lower portion of the inferior constrictor),
and the esophagus blend together. This creates a potential sphincter that can decrease the
cross sectional area of the esophagus. Although most of the esophagus is composed of
muscle fibers not under voluntary control, the muscle fibers in the upper portion of the
esophagus are under voluntary control. Thus, an individual can exert conscious control of
the upper esophagus. The cricopharyngeus muscle extends posteriorly from the cricoid
cartilage of the larynx and blends with the muscle fibers of the esophagus. During
surgery for a laryngectomy, the anterior fibers of the cricopharyngeus are sutured
together, creating a complete muscle sphincter around the esophagus. The shape and
length of the PE segment varies depending on the exact surgical alterations to the
anatomy of the region. However, shape or size of the PE segment does not appear to be
factors in predicting successful acquisition of esophageal speech. Of even greater
importance is the degree of tonicity of the segment. If the resistance of the PE segment to
dilation or oscillation is high, it may be difficult for the patient to insufflate the esophagus
to produce good esophageal vibrations.
Air Supply
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Esophageal speakers have a much lower air reservoir (less than 100 cc) than is
available to laryngeal speakers from the lungs (>5 liters). However, efficient esophageal
as well as laryngeal speakers typically require a very small amount of air to produce
vibration. The small air supply will limit the esophageal speakers ability to produce
long utterances on a single charge of air.
Air flow rates are also somewhat variable in esophageal speakers and depend on:
the volume of air in the esophagus the pressure within the esophagus, and the resistance of the PE segment (Diedrich, 1991)
Air discharge
Air is thought to be expelled from the esophagus as a result of mechanisms
similar to exhalation of air from the lungs. That is, increased thoracic pressure creates a
force on the esophagus (which passes through the thorax on its way to the stomach). The
esophageal walls within the thorax are constricted forcing the air within to move up the
esophagus and out them out. Interestingly, there is evidence (Kahrilas et al. 1986) that in
laryngeal speakers, during a belch, the pressure in the upper portion of the esophagus is
lower than in the lower portion of the esophagus. This suggests that the resistance to
opening the upper portion of the esophagus is less than the lower portion, permitting
easier release of air upward into the pharynx rather than downward into the stomach.C. Techniques for obtaining an air supply
1) Injection
In this method, air injected from mouth into esophagus via the tongue and
pharynx. The tongue acts like a piston to force air back into pharynx and esophagus.
There are 2 stages in this sequence.
First, the tongue pushes the air into in the mouth back to the pharynx (the so
called glosso press).
Second, the back of the tongue and pharynx force the air down into esophagus
(glossopharyngeal press).
a) The glossal press is produced by the tongue tip contacting the alveolar ridge. The
midportion of the tongue may elevate to contact the hard palate. Air is trapped behind
the tongue and moved posteriorly by the backward movement of the tongue. The tongue
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does not make actual contact with the posterior pharyngeal wall. However, the soft
palate is elevated to prevent escape of the air through the nose. The lips may or may not
be closed because the tongue tip traps the air needed for injection.
b) In the glossopharyngeal press, tongue movement is similar to that seen in the glossal
press, but the tongue continues to move backward to contact the pharyngeal wall. Again,
velopharyngeal closure is necessary, but lip closure is not. Tongue and pharynx force air
down into esophagus.
2) Inhalation Method
It is based on the principle that air will enter the esophagus if the PE segment is
sufficiently relaxed when pulmonary inhalation occurs. To accomplish this, the patient
must be able to relax the PE segment; otherwise, air cannot flow downward. Typically,
the intraesophageal pressure is between -4 and -15 mm Hg (Diedrich, 1991) below
atmospheric pressure. When the PE segment opens, air in the mouth and pharynx which
is typically at atmospheric pressure (+14 mm Hg) will naturally flow from the region of
higher pressure to the region of lower pressure, that is, in the esophagus. The reduction
of pressure within the esophagus is a by-product of the normal inhalation of pulmonary
air. That is, when the speaker inhales air, the pressure within the esophagus becomes
even more negative relative to the atmosphere (as much as -15 mm Hg), creating an even
greater sucking force to pull the air into the esophagus).
3) Swallowing
At one time or another, each of us has swallowed air into the stomach and has, at
a later time, burped. But, swallowing air is not advantageous for creating an air supply
for esophageal speech for a variety of reasons.
a) Swallowing is a reflex that requires a bolus of some type to trigger the reflexaction. In the absence of a trigger it is often difficult to initiate a swallow.
b) It is not possible to dry swallow quickly and repetitively as required forspeech.
c) Voluntary control of the air supply from the stomach may be very difficult toachieve, if not impossible.
4) Consonantal injection:
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It is an efficient method of getting air into the esophagus as it allows air to be
injected in to the esophagus during intra phrase intervals as well as during rest unlike
other methods. Because air can be injected when the tongue is positioned for releasing a
consonant of word, air for subsequent esophageal production is usually injected into the
esophagus simultaneously with the release of articulator. Teach the patient to produce
intraoral whispers of plosive consonants (p); patient should be able to feel the
compressed air inside the mouth moving towards the throat during the production of
sound. Once the patient is able to produce crispy /p/ ask him to produce other plosives,
fricative and affricates followed by monosyllables and polysyllables with pressure
consonants.
E. Advantages
Esophageal speech may offer a number of advantages over other forms of
communication.
There are no external, visually distracting devices necessary. The sound of esophageal speech is more natural and nearly like that
produced by the vocal folds (although usually of much lower fundamental
frequency).
The patient is able to achieve some measure of pitch and loudness controland good esophageal speakers are able to vary these dynamically duringspeech.
There are no batteries that run down or devices that break down. Both hands are free during the speech act.
F. Disadvantages
1) Grimacing and excessive body tension:Patients may clench his lips tightly together,
produce unusual facial contortions or bend head during insufflations.
2) Excessive stoma noise due to forceful movement of air through stoma during
inhalation of exhalation which competes with the esophageal speech intensity.
3) Klunking and other extraneous noise when attempting to forceful injection of air using
glossopharyngeal press or swallow method.
4) In the course of insufflating the esophagus a certain amount of air is swallowed into
the stomach. Patients will complaint of bloated feeling and frequent burps.
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5) Esophageal speech must be learned and may take a long time to master. Some patients
may never learn to produce functional esophageal speech even after much effort.
6) A persons ability to articulate clearly must be excellent; otherwise the intelligibility of
esophageal speech may be poor. The patient may have difficulty being heard above
background noise. There are speech amplifiers (Voicette, rand Voice Amplifier, or
AddVox (Figure 4-7) see Appendix B) that may increase loudness but these must be
carried with the patient and may be visually distracting.
I. Indications for use of Esophageal Speech
1) Most patients are potential esophageal speakers. The exceptions to this might be
patients with extensive pharyngeal, esophageal, lingual, and / or mandibular resection;
patients whose medical status is otherwise compromised, patients with significant hearing
loss patients who have chosen to have a Tracheoesophageal fistulization and patients
who have no desire to learn esophageal speech.
2) Patients can use esophageal speech and electronic speech aids interchangeably,
depending on the environmental noise level or situation.
3) Teaching Esophageal Speech
The teaching of esophageal speech requires skill, understanding of the anatomy
and physiology of esophageal sound production, patience, sensitivity to the psychological
impact of the process on the patient, and the ability to be supportive. It is extremely
helpful for the clinician to have acquired the ability to produce esophageal sound. Often
demonstration of its production can be more instructive than verbal explanations.
For the patient, the learning of esophageal speech requires a high degree of
motivation, a willingness to learn to produce a sound voluntarily that has always had a
negative stigma, patience, the physical integrity necessary to produce esophageal sound,
emotional stability, and a host of other factors that are difficult to itemize.
There are a variety of methods for teaching patients and the following sections are
based on clinical experience with methods that have proven effective as well as
discussion of less successful methods.
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The clinician should listen carefully for any involuntary production ofesophageal sound. Some patients will inflate or charge the esophagus
unconsciously as they attempt to produce whispered speech. Even if the
clinician does not hear evidence of such sounds during the first session,
patients should be asked if they have made any sounds involuntarily since
their surgery, and if so, to describe when it happened.
Ask the patient to make a burping sound. It is always good for the clinician tobe able to demonstrate production of a burp. This may make the patient
more comfortable about producing a sound that has been considered socially
unacceptable. Some patients will be able to produce such a sound with ease.
The clinician should carefully observe the manner in which the patient
attempts to produce the burp, whether successful or not. It is especially
important to note whether the patient is working hard at swallowing during the
attempt. If that is the case, it is a behavior that should not be encouraged or
reinforced. If the patient seems to be injecting air into the esophagus
appropriately and producing sound, the clinician should continue with
additional trials during which the patients attention is directed at determining
how the sound is being produced.
The clinician should demonstrate injection of air in an audible manner and askthe patient to produce a similar sound. The sound is typically referred to as a
klunk, and should be audible but not excessively loud.
Try to trigger esophageal sound production using plosive consonants. The patient can learn to manipulate the air trapped in the mouth by puffing the
cheeks out and by moving the air around in the mouth from side to side and
forward.
In addition to using the voiceless stop plosive/vowel combinations notedabove to trigger esophageal sound production, there are a number of words
that often trigger sound production.
As a last resort, after having tried and retried all of the above methods to teachinjection, the idea of swallowing in a controlled way may be introduced.
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Extending sound production into speech early in the process is helpful topatients, but should not be rushed.
II. GASTRIC SPEECH:
A successful pharyngolaryngoesophagectomy with pharyngogastric anastomosis
the so-called gastric pull-up-surgery-involves a variety of postoperative functional
alterations, including alimentation and speech.
Surgical procedure
Under general anesthesia, a secondary TG fistula was created, using a Groningen
tracheal puncture forcep. With the patient in a supine position, a rigid esophagoscope
was placed into the cervical stomach via the oral cavity. The esophagoscope was turned
180 degrees to expose the beveled edge toward the penetration site, which was within the
visible lumen of the stoma. Considerable force was required to puncture through the
gastricwall. Immediately following the puncture, the voice prosthesis was inserted. The
fistula site was placed at the level of the inferior margin of the stoma.
Disadvantages:
Although the problems involved in solving the postoperative difficulties of
swallowing and digestive processes have been discussed extensively restoration of voice
and speech in these patients has been largely unsuccessful. For example, of the 136
cases of gastricpull-up performed at the Queen Mary Hospital in Hong Kong, speechrehabilitation was highly unsatisfactory, with only 9 patients (6.6 percent) able to produce
audible whisper, and 6 patients (4.4 percent) able to use an electro larynx. This occurred
despite the fact that 87 percent of patients satisfactory alimentary.
Functions, Nonetheless, speech restoration for all types of pharyngeoesophageal
reconstruction was not considered to be satisfactory, and involved single word utterances
or was achieved only with the aid of an electronic device. Although better speech quality
Was obtained for the gastric pull-up group than for the other categories, since these
patients were able to inject air transorally and generate neoesophageal sound, the
functional scores for speech were still poor. Of the 101 gastric pull-up surgeries
performed in England by Harrison and his colleagues, acquisition an adequate voice was
possible only in a small number of patients, in contrast to the number who regained
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trouble-free eating ability. Patients who were able to produce voice did so by manual
compression of the cervical stomach, or when experiencing pharyngogastric fistulas.
III. VOICE USING SURGICALLY CREATED STRUCTURE OR SURGICALLY
CREATED PROSTHESIS
A. Description
The rationale of these approaches has been that a patient who is given
replacement of excised vocal folds would then be able to use pulmonary air to speak
effortlessly soon after surgery without the necessity for extensive speech training.
B. Types:
1) Tracheoesophageal air shunt approaches:
Modern interest in surgical reconstruction of laryngectomized patient began in the
late 1950s for shunting air to the esophagus for the production of voice. Although these
techniques resulted in the production of a satisfactory voice, the procedures were
discontinued because patients frequently experienced a leakage of fluids of esophagus
into the trachea via the shunt during swallowing and because it was difficult to maintain
the airway due to stenosis.
2) Asai Technique:
It is an early attempt to surgically create a tracheoesophageal air shunt and a
vibratory source for voicing purpose. The multi-staged surgical procedure consisted of
connecting the trachea with the hypo pharynx with a dermal tube. To phonate, the
patient would occlude the stoma with a finger and pulmonary air would force through
the dermal tube and into the hypo pharynx, causing the pharyngeal end of the tube to
vibrate. Although the voice produced was adequate, many patients experienced problems
like tube stenosis and air growth on dermal tube.
3) Air bypass approaches:
Here surgery is done to design a method by which pulmonary air from the
tracheostoma can be diverted via a chest-mounted or neck-mounted air shunt into the
esophagostoma that has been surgically created specifically for this type of prosthesis.
The method by which voice produced would on which type of air bypass prosthesis is
used.
4) The staffieri approach:
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Developed by Staffieri, this approach consists of creating a muscle and mucosal
neoglottis between the trachea ands the esophagus. This procedure needs frequent
surgical revisions to prevent closure of the neoglottis.
5) Tracheoesophageal fistulization / puncture:
Tracheoesophageal fistulization / puncture is a surgical procedure in which a
small puncture (fistula) is made through the tracheal wall into the esophagus. The
surgery may be performed at the time of the laryngectomy, or it may be performed at a
later date. It is a relatively simple procedure and is relatively free of any major
complications. The opening allows the insertion of a prosthesis that acts as a conduit, or
shunt to direct the air into the esophagus. This air moves up through the PE segment and
in so doing creates sound. The sound in the esophagus travels into the pharynx and oral
and nasal cavities where it is resonated and articulated to produce speech.
a) Description of Surgical Procedure
Tracheoesophageal fistulization puncture may be performed under general or
local anesthesia, and a puncture or fistula of the Tracheoesophageal wall is surgically
created. Maintaining this surgically created fistula until it has healed is accomplished by
placing a catheter through the puncture site. The catheter is subsequently removed by the
surgeon or speech-language pathologist at the time of the fitting of the voice prosthesis.
b) Voice Prosthesis
The voice prosthesis is a short length (1.8 3.6 cm) of medically sage material
(usually silicone) with a valve (slit or hinge type) at the distal end. The anterior or front
and has an opening through which pulmonary air enters, and a small collar separates that
part which is inserted into the esophagus from that which is in the trachea.
Air pressures required to force open the slit range between 2 and 25 cm H2O and
depend on the rate of airflow from the lungs and the type of device used (Weinberg &
Moon, 1984). Some patients may have considerable difficulty producing these pressures.
In these cases, lower resistance prosthesis may be suitable, allowing for greater ease of
sound production.
c) Mechanisms of TEF/TEP Sound Production
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To produce sound with the voice prosthesis in place, the patient uses his or herown air supply from the lungs. To do so, the patient occludes the stoma,
usually with a finger or thumb, and inhales. Air from the lungs enters the
prosthesis and is released into the esophagus through the slit. This air passes
through the PE segment where sound is produced.
The sound produced enters the oral cavity where it is articulated and shapedinto words. With practice, the patient learns to produce complete sentences
with normal rate and phrasing. Special valves are available to eliminate the
need to occlude the stoma manually. These valves close automatically when
greater than normal thoracic pressures are present as when, for example, the
patient wishes to produce speech.
C) Advantages
This technique can provide the most rapid restoration of near normal speech for
most laryngectomized patients. After normal healing has been complete, the prosthesis
can be fitted easily by the physician / speech pathologist team. After appropriate
instruction, the patient should be able to remove and reinsert the device. The prosthesis
is inexpensive (less than $ 20.00) and is available in a variety of sizes to accommodate
variations in stoma size ands fistulae size.
The other major advantage is that normal pulmonary air is used t drive the PEsegment, freeing the patients hands and permitting near-normal speech production.
Experience with surgical prosthetic voice restoration has demonstrated a very high
success rate in the acquisition of functional speech.
D. Disadvantages
1) As with any surgery, there are risks. The possibility of complications that may
compromise the airway or the fistula is present.
2) Occasionally, the fistula may stenose, preventing the insertion of the device. This
usually occurs if the fistula has been allowed to remain totally unstinted or if the
prosthesis has been improperly fitted.
3) There is a slight risk of aspiration of the prosthesis if it becomes dislodged from its
placement.
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4) Other complications include stoma stenosis, infection due to poor hygiene, radiation-
induced fistula closure, granulation buildup, prolapse, or leakage around the prosthesis
with subsequent aspiration.
E) Teaching Tracheoesophageal Speech:
a) Patient Selection
Patient selection for primary fistulization is often determined by the surgeon, who
is primarily concerned with the success of the surgery and the fewest complications. The
speech-language pathologist should ideally be involved in selecting. TEF patients and
should consider the factors discussed below (with the exception of esophageal
insufflation testing).
Healing from previous surgery should be complete. Radiation treatment or other forms of treatment should have been completed. The patient should have had an adequate interval of being free of disease. The patient should be medically stable in areas other than the laryngectomy.
Patients with major respiratory problems must be carefully assessed to ensure
they will have adequate air volume and adequate ability to generate air
pressures required to move the air through the prosthesis and generate sound.
The tracheostoma must be of adequate size (1.5 cm minimum) to house theprosthesis, and it must be above the jugular notch at the manubrium. If thestoma has a tendency to close, the patient may need to be fitted with a
prosthesis that is built into a tracheostoma tube. An excessively large stoma
may be difficult for the patient to occlude with the thumb.
There must be a healthy common wall between the trachea and the esophagus. The patient should display emotional stability sufficient to undergo another
surgical procedure followed by fitting of a device and training in its use.
Dependence on drugs or alcohol would serve to eliminate the patient fromconsideration.
The patients should display a degree of motivation sufficient to followthrough with the full program of voice restoration.
The patients eyesight, manual dexterity and control, habits of generalhygiene and general alertness must be considered.
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The prospective candidate for TEF, having passed all of the above tests,should then have insufflation testing. This procedure is within the scope of
practice of the speech-language pathologist who has the appropriates
competencies. This involves the transnasal insertion of a rubber catheter into
the esophagus, introduction of air through that catheter, and production of
sound. A judgement of the adequacy and quality of the sound that is elicited
must be made.
b) The Blom-Singer Insufflation Test Kit is available and includes complete
instructions for its use. The test kit contains a measured section of 14 Fr. (French) red
rubber catheter attached to a tracheostoma adapter and housing. This is affixed to the
stomal area of the neck. The catheter must be passed transnasally as far as the marker at
the 25 cm point, which should rest at the nasal tip. If the catheter is not inserted up to this
marker, the test may be invalid. With the catheter and the stomal housing in place in
patient is instructed to inhale, to cover the stoma adapter with his or her finger, and thus,
to self-insufflates the esophagus. The patient should be able to produce sound easily.
Ideally, production of a vowel should be sustained for 8 sec. or longer, and the patient
should be able to count to 15. The patient must attempt easy sound production without
excessive strain and tension. He or she should neither swallow air nor attempt to pump
air in. Either maneuver will not allow the pulmonary air to be released. When the initialtest is unsuccessful, repeated trials may be needed.
Unsuccessful insufflation testing should lead to referral for further exploration of
the cause for failure. This may involve a videoradiographic study and / or injection of
lidocaine to produce a pharyngeal plexus nerve block that induces relaxation of the PE
segment.
Preoperative recording of intraesophageal peak pressure levels have been
proposed by Lewin, Baugh, and Baker (1987) as a procedure that can predict the success
of fistulization more objectively. It reported to be more than 90% accurate. Patients
found to have intermediate or high intraesophageal pressures required myotomy to
become fluent tracheoesophageal speakers.
c) Fitting of the Voice Prosthesis
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The timing for fitting the voice prosthesis may be different for each patient.For the patient with primary TEF (at the time of surgery) fitting of the
prosthesis may be delayed for as long as 3 weeks or until surgical sites show
adequate healing. Fitting of the prosthesis for the patient with secondary
fistulization (after the primary surgery) may take place anywhere from 36
hours to 1 week or more after the procedure. The fistula must be healed well
prior to the fitting.
To remove the red rubber catheter, it may be necessary to remove the suturesthat were put in at the time of surgery. The area must then be carefully
cleaned, and a clean catheter is reinserted and may be held in place by tape.
Whenever a catheter or prosthesis is not in place, the patient is cautioned not
be swallow. This should not occur for more than seconds at a time.
To test the phonatory mechanism with the least possible resistance, ask thepatient to inhale, occlude the stoma, and exhale. This should result in sound
production. A few trials may be necessary. If no sound is produced after
several trials, the catheter should be replaced, or a dummy prosthesis may be
used, and the fitting should be postponed for a few days to allow more time
for healing and reduction of swelling.
A sizing device, available from the manufacturers, is used to measure thelength of the prosthesis required. The catheter is removed and the measuring
probe is inserted. It is possible to feel when that probe impinges on the
posterior pharyngeal wall. The clinician should gently retract the probe until
the flange is at the anterior esophageal wall and resistance to further
movement is felt. At that point where the sizing device is comfortably within
the esophageal lumen, neither abutting against the posterior esophageal wall
nor too snugly pulled against the anterior esophageal wall, the measurement
should be taken. It is better to measure too long than too short in this early
stage of sizing. If it is too short, the surgically produced track may begin to
close. It is sometimes helpful to leave the instrument in place for a minute or
two to see what happens to the position of the prosthesis when the patient
swallows. On occasion, the probe will be pushed forward slightly by the
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swallow. It may be more comfortable for the patient to fit the prosthesis
allowing for the adjustment as long as the prosthesis is in the esophagus and is
sufficiently long to maintain an open tract. The anterior end of the prosthesis
should lie fairly flush against the puncture aperture.
If the prosthesis cannot be inserted easily, the lumen of the fistula may betight and require easy dilation. Catheters of increasing dimension may be
used to dilate the fistula. This should be done gradually and carefully to allow
for ease of insertion as well as a well fitting seal around the prosthesis.
Insert the prosthesis using the insertion tool to demonstrate the process to thepatient. The patient is instructed to attend to the sensation when the collar
flange is released in the esophagus. The outer flange or strap is released from
the insertion too, and the tool itself is gently rotated as it is pulled forward and
removed. Tape the outer strap to the neck.
With the prosthesis in place, check for any signs of leakage around the fistulaby having the patient swallows small amounts of water or other liquid.
Observing the swallow with a light directed into the stoma should make it
possible to detect leakage. If it is noted, the patient will need to allow further
time for the puncture to close down around a 14 Fr catheter. If leakage occurs
through the prosthesis itself, a new prosthesis should be inserted. The patient should then be instructed to inhale and attempt to phonate while
the clinician occludes the stoma. It is important that the entire stoma be
occluded but that the pressure against it is gentle. On these initial trials, it is
not unusual for the patient to inhale too deeply thereby over inflating the
esophagus, or not activate the airflow correctly due to excess tension. Either
of these will inhibit the production of sound.
The patient should then be taught to occlude the stoma. If the stoma is toolarge for the patient to be able to occlude digitally, creative ingenuity must be
used to solve this problem. For example, the housing and the stoma adapter
that come with the insufflation kit can be used to removing the catheter and
plugging the attachment port. The housing is affixed to the peristomal area as
it would be for the insufflation test.
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The patient is now ready to attempt speech by inhaling, occluding the stoma,and producing either a sustained sound or words, such as counting. When
patients are successful in this, they are instructed to practice frequently
throughout the day. As the patient becomes comfortable with the device and
proficient in the act of occluding the stoma, the speech usually becomes
increasingly fluent and effortless.
Removal and reinsertion of the prosthesis must be learned properly. Althoughit may not be necessary for the patient to remove the prosthesis until a return
visit to the speech language pathologist or doctor, he or she should know how
to remove, clean, and reinsert the prosthesis or a dummy prosthesis or the red
catheter, should it become necessary to do so. This should be taught in a
slow, step-by-step process.
1) Arrange a clean, well lit area with a mirror and the equipment required.2) The patient is instructed to remove the prosthesis by firmly pulling it forward by
the outer flange or strap. It must be remembered that, if the prosthesis is to be out
for any period of time, the catheter or a dummy prosthesis must be inserted. The
patient is shown how to do this and given the opportunity to practice.
3) The prosthesis is cleaned according to manufacturer instructions.4)
The patient is then shown how to place the prosthesis on the insertion tool and isgiven the opportunity to do this.
Patients undergoing radiation therapy after being fitted with prosthesismay find a temporary disruption in their ability to speak during the course
of the radiation treatments because of swelling and inflammation of the
tissues. Speech should return naturally as those problems resolve.
Candida deposits on or in the prosthesis may interfere with soundproduction. A solution for this involves having more than one prosthesis,
changing prostheses every day or two, and soaking one prosthesis in
hydrogen peroxide.
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Granulation tissue formation may occur as a result of inflammationassociated with infrequent prosthesis removal. The obvious solution to
this problem is more frequent removal and cleaning of the prosthesis.
Difficulty in producing voice that occurs after a time of initial success mayhave a number of causes. The prosthesis valve should be checked to make
sure that it is not stuck. If the prosthesis was incorrectly fitted and is too
short, or if it was not fully inserted, secondary tract closure may have
occurred. This will require dilation of the tract and reinsertion of a longer
prosthesis.
d) The Tracheostoma Valve
The tracheostoma valve eliminates the need for digital occlusion of the stoma for
speech production. Patients must be selected and fitted appropriately with the valve. The
design of the valve allows quiet breathing to be unimpeded. A thin diaphragm responds
to the natural increase in air pressure for speech by closing. There is a flexible housing
or collar (similar to that used in the insufflation test) which must be sealed on the
peristomal skin. This is done with the use of double-faced tape and a liquid adhesive. A
tight seal is essential for the valve to function. The valve is inserted into the housing and
can be quickly removed. If necessary, leaving the housing in place. Patients with
significant respiratory problems may not be good candidates for use of the valve.Similarly, patients who experience excessive mucous discharge and secretions find the
valve problematic. All other patients should be given a trial with the valve to determine
its efficacy for them.
1) Patients should be speaking effectively using digital stoma occlusion beforethe valve is attempted.
2) The peristomal area should be clean and dry. The prosthesis should be place.The outer strap of the prosthesis should be shortened by approximately in.
prior to its insertion.
3) The double-sided tape or a foam disc is affixed to the housing. The liquidadhesive is spread thinly around the stoma and allowed to dry before affixing
the housing. This is often the most troublesome part of valve fitting. Unless
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the neck around the stoma is flat and smooth which is rarely the case, an
attempt must be made to fit the flexible housing so that it fits the neck
contour. Because of the frequency of this problem, foam discs are now
available that can be helpful in counteracting the irregularity of the neck
anatomy (See Appendix C for a list of suppliers). The opening of the housing
should ideally be slightly below the lower edge of the stoma. It is necessary
to seal the contact between housing and skin manually, or with the use of a
blunt ended instrument, rubbing firmly around the housing. All air bubbles
must be pressed out.
4) The valve is inserted into the housing. Valves with three different weightshave been available. Each required slightly greater air pressure to close.
More recently, a single variable weight valve has been designed that can
replace the previous individually weighted valves. When the valve is in place,
the patient should be allowed to sit quietly briefly to be reassured that
breathing is unimpaired.
5) The patient is then instructed to produce easy speech using a quick exhalationto close the valve. If the housing seal is firm, the valve diaphragm should be
head to close and speech should be produced. If the diaphragm does not
close, make certain that air is not leaking around the housing. Allow the
patient several trials. It may be necessary and advisable to use a low pressure
prosthesis when using a valve. The valve must shut easily for speech yet be
sufficiently resistant to remain open during increased physical exertion.
6) As with the prosthesis, the patient must be instructed in affixing the housingand inserting the valve. The latter is particularly.
7) Important because of the need to remove the valve during or after coughing,or at any other time that it may need cleaning. It is important that patients
grasp the outer edge of the valve to remove it and not the bar that may go
across the top. The function of that bar is simply to keep clothing away from
the valve.
8) Patients may need short-term therapy to lean to use the valve effectively.Attention should be given to easy speech production with minimal strain,
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length of utterances consistent with pulmonary air supply, appropriate
phrasing, and good coordination of exhalation and speech.
Advantages and disadvantages of each form of alaryngeal speech are presented in
Table. The various mechanical speech aids and voice prostheses are discussed in the
following sections
Table: Comparison of alaryngeal speech modes
Type of speech Advantages Disadvantages
Pneumatic speech aid Natural non electronic
sound, easy to learn,
intelligible speech
inexpensive operating cost
(no batteries)
Bulky size, requires access
to stoma, sometimes
difficult to maintain seal at
stoma
Electronic speech and
(neck type)
Easy to learn, fits in pocket
or purse, volume and pitch
controls for individual
preference. Adequate
volume to be heard in noisy
places, intelligible speech
when used well.
Noisy electronics sound,
cannot be used with heavily
scanned or erythematous
neck, moderate initial cost,
low operating cost for
renewed batteries,
occasional extra cost forrepair, requires very clear
articulation skills.
Type of speech Advantages Disadvantages
Electronic speech aid (oral
type)
Easy to learn to use, fits in
pocket or purse but may be
larger than neck type,
volume and pitch controls
for individual preference.
Adequate volume to be
heard in noisy places, may
be less noisy than neck
Electronic sound very
obvious to all observers
clumsy feeling initially to
talk with tube in mouth,
moderate initial purchase
cost, occasional additional
cost or repairs, requires
very clear articulation for
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types, can be used soon
after surgery evening
presence of much scar
tissue, intelligible when
used well.
easy intelligibility.
Esophageal speech Natural non-electronic
sound, requires no
dependence on mechanical
instrument or other device,
sound of the voice does not
call attention to itself (may
be perceived as having a
child)
A period of therapy
required for most people,
may be difficult for one
third or more of patients to
learn well enough to be
easily intelligible, difficult
to hear in noisy
environments, requires
excellent articulation skills,
and may exacerbate
symptoms of hiatal hemia
condition.
Type of speech Advantages Disadvantages
Tracheoesophageal
speech
Natural non-electronic
sound requires short
learning period, smooth,
fluent speech using long
sentences because of
availability of pulmonary
air, smooth, clear sound for
most patients, flexibility of
If not done as primary
procedure, requires another
surgical procedure, requires
maximum manual dexterity,
visual activity and levels of
alertness to care for,
requires use of finger to
occlude stoma or daily
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loudness and pitch
variations, and sound of
voice does not call attention
to itself.
affixing of valve to
peristomal area, occasional
aspiration due to poorly
seated prosthesis, or poorly
functioning prosthesis,
buildup of Candida deposits
requiring frequent cleaning
may need to remove valve
when coughing or to clean
after coughing.
THERAPY:
General Considerations:
A few broad areas apply to all alaryngeal speech modes; however, some are most
relevant to the learning to esophageal speech. These include initiation of therapy, group
versus individual therapy, frequency of therapy, involvement of family and / or friends in
the therapy session, practice and pace of therapy, prognostic factors, and when to
terminate therapy. Issues of reimbursement are too complex and changeable to be
discussed here.A. Timing of Speech Therapy
1) We advocate the earliest possible initiation of speech therapy. Patients are strongly
encouraged to begin speech therapy as soon after discharge from the hospital as possible.
It is important for them to begin the rehabilitation process promptly because the longer
the time between the surgery and the beginning of therapy, the poorer are the prospects
for a good result. Many patients will have to undergo a course of radiation therapy, a
difficult period often lasting 5 to 6 weeks. Many have physical reactions to the radiation
treatment that may retard or interrupt the process of speech therapy during that time. It is
important for them to have acquired some form of communication (other than writing)
prior to radiation. Furthermore, lack of involvement in the rehabilitation process for a
period of 1 to 2 months (or more), particularly in the absence of a viable means of
communication, can lead to feelings of isolation, depression, and frustration.
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a) Patients are usually ready to begin esophageal speech trainingshortly after they
begin to take food by mouth. The beginning of oral feeding suggests that wound healing
has progressed to the point where attempts to produce sound will not jeopardize further
recovery.
b) Use of an oral type of electronic speech aid can often begin within days after
laryngectomy surgery assuming the patients progress is without complications. The
extent of the lesion and of the surgery must be considered when judging the patients
readiness for using an electronic speech aid.
c) Use of a neck-held electronic speech aid can begin as soon as healing of the
surgical suture lines is complete and swelling has resolvedsufficiently to obtain good
transcutaneous transmission of sound.
d) In the case of TEF,readiness for initiation of speech with a prosthesis depends on
the healing of the puncture site.
2) Early use of speech aidcan decrease feelings of isolation, depression, and frustration.
In uncomplicated cases, an oral type of electronic speech aid can be introduced on the
fourth to seventh post surgical day along with instruction in its use.
B. Group Versus Individual Therapy
Each approach has its advantages and disadvantages and may be determined by
the type of alaryngeal speech to be pursued, patient preference, clinician style, and
scheduling constraints. The fitting of prosthesis is best done individually, as is the initial
instruction in producing tracheoesophageal speech. For those patients who will pursue
either esophageal speech training or the use of an electronic speech aid, or both, the
choice of group versus individual therapy can be considered.
1) Individual therapy of course, provides the patient with the full and undividedattention of the speech-language pathologist. The amount of time given directly
to the individual patient is greater than can be provided to any one individual in a
group setting. Some patients become anxious and self-conscious in the pressure
of a group and may not learn as fast or as well as when alone.
2) Group therapy on the other hand, exposes the individual to others who are inthe same boat thus lessening the feelings of isolation. It allows for interchange
among group members about shared concerns other than speech. Newly
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laryngectomized persons benefit from the models presented by others in the group
who are further along in the process.
C) Involvement of Family and / or Friends in Therapy Sessions
Involvement of significant others is always encouraged. It is especially important
during the initial session, at the very least, so that family and / or friends can gain a basic
understanding of the rehabilitation process, and specifically speech rehabilitation. Of
course, the amount of involvement must always be tempered by sensitivity to the
relationship between the persons involved. Supportive family members or close friends
can be a major source of help for the patient and can be more effective when they
understand the process.
D) Prognostic Factors
There is no clear way to determine how quickly or how well functional
alaryngeal communication will be acquired. A statement of prognosis is a well educated
guess.
1) The prognosis for Tracheoesophageal speech following fistulization in probablymost easily and reliably determined. Because the learning time for that type of
speech is very short it is possible to judge relatively quickly how well the patient
will do. However, caution must be exercised in making the judgment too soon
because the healing process may result in stricture or stenosis that may have a
negative effect on speech production even after an initially positive outcome. If
this is suspected, the patient should be encouraged to see the surgeon.
Furthermore, a small percentage of patients have difficulty in producing speech
following fistulization and may require additional workup and treatment.
2) Prognosis for the patient who chooses to use an electronic speech aid for purposesof communication can also be assessed with fairly good accuracy. As a person
begins to use the instrument, the ability to articulate clearly and place the
instrument appropriately in quite obvious.
3) Prognosis for the acquisition of functional esophageal speech is problematicbecause it involves the learning of new skills that are more difficult to acquire
than for either of the other two methods. Factors such as viability of the
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pharyngeoesophageal segment, time elapsed since surgery, age, extent of surgery,
hearing acuity, and personality must be considered. Even taking all those factors
into account, the most skilled and experienced clinician can still make incorrect
judgements. It may be best to err on the side of giving the patient the benefit of
the doubt as long as he or she is motivated and making the effort to learn.
1) J Voice.2004 Dec;18(4):567-77
Aerodynamic characteristics of laryngectomees
breathing quietly and speaking with the
electrolarynx.Liu H,Wan M,Wang S,Niu H.
The primary purpose of this study was to investigate the aerodynamiccharacteristics of laryngectomees under two conditions: breathing quietly andspeaking with electrolarynx. Twenty male adult subjects, 8 normal speakers, and12 laryngectomees participated the experiment. Airflow, pressure, and speechdata were obtained simultaneously. The acceptability of electrolarynx speechunder different conditions was also evaluated by 20 listeners (14 men, 6 women).Results indicated a higher peak expiration airflow and pressure among the
laryngectomees as compared with the normal during breathing. Three differentbreathing patterns appeared among the laryngectomees when speaking with theelectrolarynx: holding breath, exhaling, and breathing. Four long-timeelectrolarynx users held breath during speaking. Seven of 12 laryngectomees keptexhaling, whereas only 1 could breathe during speech production. In addition, (1)the acceptability of electrolarynx speech was the highest when speakingbreathlessly; (2) no significant difference was found in the acceptability betweenthe patterns of exhaling and breathing smoothly; and (3) the acceptabilitydecreased if breathing quickly during phonation with the electrolarynx. It alsosuggests that the laryngectomees who can breathe during speaking may be moreappropriate to use the new electrolarynx controlling the pitch by expirationpressure.
2)IEEE Trans Biomed Eng.2004 Feb;51(2):325-32
Design and implementation of a hands-free
electrolarynx device controlled by neck strap
muscle electromyographic activity.
http://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Liu%20H%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Liu%20H%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wan%20M%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wan%20M%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wan%20M%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wang%20S%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wang%20S%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wang%20S%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Niu%20H%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Niu%20H%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Niu%20H%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Niu%20H%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wang%20S%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Wan%20M%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlushttp://www.ncbi.nlm.nih.gov/sites/entrez?Db=pubmed&Cmd=Search&Term=%22Liu%20H%22%5BAuthor%5D&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_RVAbstractPlus -
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Goldstein EA,Heaton JT,Kobler JB,Stanley GB,Hillman RE.The electrolarynx (EL) voice prosthesis is widely used, but suffers from theinconvenience of requiring manual control. Therefore, a hands-free EL triggered by neckmuscle electromyographic (EMG) activity was developed (EMG-EL). Signal processingcircuitry in a belt-mounted control unit transforms EMG activity into control signals for
initiation and termination of voicing. These control signals are then fed to an EL heldagainst the neck by an inconspicuous brace. Performance of the EMG-EL was evaluatedby comparison to normal voice, manual EL voice, and tracheo-esophageal (TE) voice in aseries of reaction time experiments in seven normal subjects and one laryngectomypatient. The normal subjects produced voice initiation with the EMG-EL that was as fastas both normal voice and the manual EL. The laryngectomy subject produced voiceinitiation that was slower than with the manual EL, but faster than with TE voice. Voicetermination with the EMG-EL was slower than normal voice for the normal subjects, butnot significantly different than with the manual EL. The laryngectomy subject producedvoice termination with the EMG-EL that was slower than with TE or manual EL. TheEMG-EL threshold was set at 10% of the range of vocal-related EMG activity above
baseline. Simulations of EMG-EL behavior showed that the 10% threshold was notsignificantly different from the optimum threshold produced through the process of errorminimization. The EMG-EL voice reaction time appears to be adequate for use in a day-to-day
3) J Voice.2001 Dec;15(4):592-9
Functional characteristics of a new electrolarynx
"Evada" having a force sensing resistor sensor.
Choi HS,Park YJ,Lee SM,Kim KM.
Electrolarynxes have been used as one of the rehabilitation methods forlaryngectomees. Earlier electrolarynxes could not alter frequency and intensitysimultaneously during conversation. Recently, we developed an electrolarynxnamed "Evada" (prototype so far) using a force sensing resistor (FSR) sensor thatcan control both frequency and intensity simultaneously during conversation.
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Employing three types of electrolarynxes (Evada, Servox-inton, Nu-vois), thisstudy was undertaken to examine the functional characteristics of Evada for thenormal control group and for laryngectomess. Five laryngectomees and fivenormal adults were asked to express three sentences (declarative sentence, "Youstay here.", interrogative sentence, "You stay here?", and imperative sentence,
"You! Stay here.") using three types of electrolarynxes. Frequency and intensitychanges between the first and last vowels in the three sentences were calculatedand analyzed statistically by paired t test. The frequency changes in theinterrogative and imperative sentences were more prominent in Evada than inServox-inton and Nu-vois. The intensity changes in the interrogative andimperative sentences were also more prominent in Evada than in Servox-intonand Nu-vois. Evada controls frequency and/or intensity by having the subjectpress the control button(s). Therefore, Evada appears to be better at producingintonation and contrastive stress than Nu-vois and Servox-inton.
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KUNNAMPALLIL GEJO JOHN,BASLP, MASLP