A cquired D ysarthria w ithin the C ontext o f  the Four-level Fram ew ork o f  Speech Sensorim otor Control 67

ACQUIRED DYSARTHRIA WITHIN THE CONTEXT OF THE FOUR-LEVEL 
FRAMEWORK OF SPEECH SENSORIMOTOR CONTROL

Alexandra Stipinovich and Anita van der Merwe

Department o f  Communication Pathology 
University o f  Pretoria

ABSTRACT

The Four-Level Framework o f  speech sensorimotor control (Van der Merwe, 1997) complicates the traditional view o f  dysarthria 
as a purely motor execution disorder. According to this framework, hypokinetic, hyperkinetic and ataxic dysarthria are program- 
ming-execution dysarthrias, while fla ccid  dysarthria is the only execution dysarthria. This preliminary study aimed to differentiate 
programming-execution dysarthria from  execution dysarthria by examining variability o f  the temporal control o f  speech. Six p a r­
ticipants and fiv e  control participants repeated 15 stimulus words ten times. Voice onset time, vowel duration, vowel steady state 
duration and vowel form ant transition duration were measured acoustically. The coefficient o f  variation o f  the temporal parame­
ters, and the correlation coefficient between the durational parameters, were calculated and analysed using descriptive statistics. 
The coefficient o f  variation revealed that the speakers with dysarthria were more variable than the control speakers. All partici­
pants, except those with fla ccid  dysarthria, showed similar patterns o f  intra-subject variability. Those with fla ccid  dysarthria ex­
hibited greater intra-subject variability o f  voice onset time. The correlation analysis did not reveal differences between dysarthria 
type, or between the dysarthric speakers and the controls. Differences fo u n d  in the patterns o f  variability may support the hy­
pothesis that individuals with programming-execution dysarthria resort to a different level o f  control than those with execution 
dysarthria. Further research in this fie ld  is necessary.

Key Words: flaccid dysarthria, hypokinetic dysarthria, ataxic dysarthria, temporal variability, motor programming, motor execu­
tion, Four-Level Framework o f speech sensorimotor control.

INTRODUCTION

The traditional classification of dysarthria as a motor execution 
disorder (Darley, Aronson & Brown, 1975) is challenged by 
recent advances in theoretical models o f the sensorimotor con­
trol o f speech. One such model is the FLF of speech sensorimo­
tor control (Van der Merwe, 1997; 2007). This framework has 
recently been described as ‘possibly the most detailed and com­
prehensive attempt to explain impairments in the speech pro­
duction process, relating sub-components to underlying neural 
structures, diagnosis of motor speech disorders, and principled 
development o f treatment strategies for such disor­
ders’ (Ballard, Granier & kobin, 2000 p. 972). According to 
the FLF (Van der Merwe, 1)997; 2007), neural structures such 
as the basal ganglia (implicated in hypokinetic and hyperkinetic 
dysarthria), and the lateral1 cerebellum (implicated in ataxic 
dysarthria), are involved inj both the programming of move­
ments and the execution o f movements. Areas o f the cerebel­
lum other than the lateral cerebellum, as well as the lower mo­
tor neurons, are involved in motor execution. Dysarthrias asso­
ciated with damage to the basal ganglia or lateral cerebellum 
are thus likely to show signs of both programming and execu­
tion difficulties and may therefore exhibit similar trends that 
would differentiate them from pure motor execution disorders. 
Thus, when viewed within the context of the FLF (Van der 
Merwe, 1997; 2007), the traditional classification o f dysarthria 
as a disorder of motor execution may need to be revised. In a 
recent publication, Duffy and Kent (2001) acknowledged the 
challenges that the FLF (Van der Merwe, 1997) poses to future 
research and the classification o f dysarthria.

Models based on the normal process of language and 
speech production should guide the classification and under­
standing of the underlying nature o f communication disorders. 
Until recently, the most accepted model o f speech production 
has been a three-level model proposed by various authors (e.g.

Darley et al., 1975; Itoh & Sasanuma, 1984). The origin o f this 
three-level model may be traced back to the three hierarchical 
stages involved in motor skill, namely the planning (encoding), 
programming and execution of movements (Brooks, 1986; 
Magill, 2007). While speech production is a motor act and 
therefore likely to entail the same phases o f motor planning, 
programming and execution as other forms o f movement, ver­
bal communication also entails the linguistic planning of the 
utterance to be made. A pre-motor phase therefore needs to be 
distinguished from the three motor phases o f planning, pro­
gramming and execution. According to Van der Merwe (1997), 
linguistic planning is equated with motor planning for speech 
by the three-level model o f speech production. This lack of 
differentiation between linguistic planning and the three phases 
involved in the preparation and production of the speech act 
has led to an inadequate formulation o f the true nature of the 
motor planning, motor programming and execution of speech 
(Van der Merwe, 1997). In view of the above-mentioned limi­
tations of the three-level model, Van der Merwe proposed the 
FLF o f speech sensorimotor control in 1997. This framework 
consists o f one pre-motor stage, namely linguistic-symbolic 
planning, and three motor stages, namely motor planning, mo­
tor programming and motor execution. According to the FLF 
(Van der Merwe, 1997; 2007), aphasia constitutes a breakdown 
in linguistic-symbolic planning. Apraxia of speech is consid­
ered to reflect a breakdown primarily in speech motor plan­
ning, although motor programming may also be compromised. 
The dysarthrias constitute a breakdown in programming and 
execution, or in execution only (Van der Merwe, 1997; 2007).

According to the FLF (Van der Merwe, 1997; 2007), a 
coalition o f neural structures is involved in the control o f ver­
bal communication, many of which are active during more than 
one stage o f processing. For example, the temporal-parietal 
areas and Broca’s area are involved in linguistic-symbolic 
planning. Broca’s area, together with other cortical motor ar­

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68 A lexandra Stipinovich and A nita van der M erwe

eas, is also involved in speech motor planning. Furthermore, 
speech motor programming is controlled by the basal ganglia, 
the lateral cerebellum, the supplementary motor area (SMA), 
the motor cortex and the fronto-limbic system. However, the 
cerebellum, SMA and basal ganglia are also involved in the 
control o f speech execution (Van der Merwe, 1997). This co­
involvement o f neural structures on more than one level of 
processing complicates the accurate differentiation of break­
down on the various levels. The current study is a first attempt 
to differentiate between disorders on both a speech motor pro­
gramming and execution level, from disorders in speech execu­
tion only.

Given the above description of the involvement o f neu­
ral structures such as the basal ganglia and lateral cerebellum in 
both the programming and execution of speech movements, the 
possibility o f dual symptomatology in dysarthrias such as hy­
pokinetic dysarthria and ataxic dysarthria is strong. Only those 
dysarthrias caused by damage to the areas of the cerebellum 
other than the lateral cerebellum, as well as due to lower motor 
neuron disorders, are seen to display pure deficits in motor 
execution and are termed flaccid dysarthria (Van der Merwe,
1997). Hypokinetic dysarthria and ataxic dysarthria may there­
fore constitute programming-execution dysarthrias, while flac­
cid dysarthria may constitute execution dysarthria.

Motor programming for speech is defined in the FLF 
(Van der Merwe, 1997; 2007) as the specification and sequenc­
ing of motor programmes for the movements o f the muscles of 
the articulatory structures. Motor programmes specify muscle 
tone, velocity, direction and range o f movement (Brooks, 
1986). According to the FLF (Van der Merwe, 1997; 2007), a 
disorder at the level o f motor programming would result in the 
impairment of muscle tone, velocity, direction and range of 
movements. The repeated initiation and feed-forward of co­
occurring and successive motor programmes to the lower mo­
tor centers would also be impaired. Speech symptoms associ­
ated with such deficits may include sound distortion, abnor­
malities in speech rate, and/or problems with the initiation of 
movements for speech. Motor programming difficulties may 
occur in the absence of hypo- or hypertonia or involuntary 
movements which are traditionally associated with dysarthria 
and which cause the breakdown in execution (Van der Merwe, 
1997; 2007).

The execution o f movement is mediated at the lowest 
level of the motor hierarchy and is set in motion by sub- 
programmes that are conveyed from the middle levels to the 
lower motor centres, namely the spinal levels (Brooks, 1986). 
Flaccid paralysis is caused by damage to the nuclei, the axons 
or the neuromuscular junctions that make up the lower motor 
neuron (Duffy, 2005). All signals to produce movement arising 
in the central nervous system must pass through the final com­
mon pathway (which includes the lower motor neuron). As a 
result, all types o f movement (voluntary, automatic and reflex­
ive) are impaired in the case o f motor execution difficulties 
(Hageman, 1997).

Four issues complicate the differentiation between the 
signs associated with a pure motor execution disorder and a 
programming-execution disorder. Firstly, it is to be expected 
that all types o f dysarthria (flaccid, spastic, ataxic etc.) will 
differ in terms of their signs and speech motor characteristics 
as the underlying nature of the associated neuromotor disorder 
and its effect on muscle tone and movement characteristics 
differs. Secondly, there is likely to be some similarity between 
the signs and motor speech characteristics of the different types 
o f dysarthria as velocity, direction and range o f movements are 
affected to some degree in all types of dysarthria. Thirdly, the

possibility of certain motor characteristics, such as spasticity, 
masking a programming disorder must also be taken into ac­
count when attempting to differentiate between a pure execu­
tion difficulty and a programming-execution difficulty (Van 
der Merwe, 1997). Finally, the study of neuromotor speech 
disorders is complicated by the interaction o f motor impair­
ment and motor control compensations in response to that im­
pairment (Kent, Netsell & Abbs, 1991). Symptoms of dy- 
sarthric speech may thus not solely reflect the role o f the disor­
dered neurological area in the regulation o f speech, but also 
what the speech motor control system can do in the face of 
such damage. Signs exhibited by dysarthric speakers may thus 
be the result o f compensatory techniques that have involved the 
adjustment o f motor programmes (Hixon, Putnam & Sharp, 
1983). From the above discussion it is clear that, to differenti­
ate between a speech motor programming-execution disorder 
and a speech motor execution disorder, an index or parameter 
of motor control, which will reveal any possible differences 
between these two types of dysarthria, needs to be identified.

Variability o f motor speech performance is frequently 
regarded as a key to the nature o f the speech disturbance 
(Seddoh, Robin, Sim, Hageman, Moon & Folkins, 1996). Ac­
cording to McHenry (2004), the implications of variability for 
speech production are not yet clear. For example, the complex­
ity o f most skilled behaviours requires the ability to accomplish 
a goal in different ways. This capacity of a motor system to 
accomplish the same final product despite considerable varia­
tion in the individual components is referred to as motor 
equivalence (Hughes & Abbs in Abbs, 1986). However, should 
the variation within the individual components exceed the 
boundaries o f equivalence, the end product will be speech that 
is perceived as unstable or inconsistent and distorted (Van der 
Merwe, 1997). Thus, on the one hand, variability may reflect 
inherent flexibility o f a motor system. On the other hand, tem­
poral variability in motor performance is seen to suggest insta­
bility in motor control (e.g. Gerratt, 1983; McHenry, 2004; 
Munhall, 1989; Seddoh et al., 1996). If the latter is true, then 
the nature of variability o f the temporal control o f speech may 
reveal the underlying motor control disorder.

Acoustic and physiological investigations have sug­
gested that in communicatively impaired individuals, disrup­
tions in temporal control reflect a disrupted motor control sys­
tem (Duffy, 2005; Seddoh et al., 1996). Temporal aspects of 
speech include voice onset time, vowel duration, vowel steady 
state duration, vowel formant transition duration, and speech 
rate. All of these are potential sources of variation' in speech 
(Forest & Weismer, 1997; Pols, 1986). Vowel duration and 
vowel steady state duration may be representative of what 
Levelt (1989) refers to as intrinsic timing. According to Levelt 
(1989), ‘segment durations are in some way globally speci­
fied’ (p. 442) and ‘such syllable-specific durational properties 
are part o f the stored syllable program’ (p. 442). Intrinsic dura­
tion is thus determined before execution starts, when viewed 
within the context of the FLF (Van der Merwe, 1997; 2007). 
Levelt (1989) also distinguishes extrinsic timing. According to 
Levelt (1989, p.436), ‘the duration o f moving from one pho­
netic target to the next depends only on the mechanical proper­
ties of the musculature involved’, i.e. on executive factors be­
yond the phonetic plan. When viewed within the context of the 
FLF (Van der Merwe, 1997; 2007), vowel steady state duration 
and vowel duration may be determined by the planning and 
programming levels while vowel formant transition duration 
(extrinsic timing) may be determined on the execution level. 
Due to the possible differential breakdown in the durational 
parameters of vowels, both these aspects o f duration were ex­

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A cquired D ysarthria w ithin the C ontext o f  the Four-level Fram ew ork o f  Speech Sensorim otor C ontrol 69

amined in this study.
Voice onset time is an index of the temporal coordina­

tion o f the movements of the vocal folds and the oral structures 
and thus reflects interarticulatory synchronization (Van der 
Merwe, 1997). Increased variability of voice onset time may 
reflect a disruption o f this aspect of temporal control o f speech 
movements and was therefore also examined in this study. Ac­
cording to the FLF (Van der Merwe, 1997; 2007), the potential 
for interarticulatory synchronization is created on the motor 
planning level o f the speech production process, before motor 
programming and execution occur. Although abnormalities of 
VOT may result from disorders of planning, programming and 
execution, the possibility exists that the nature o f the distur­
bance o f VOT may differ for the different types o f dysarthria.

In describing variability of movement, the form or type 
o f variability must be taken into account in addition to the 
amount or magnitude of variability (Munhall, 1989). For 
skilled activities, such as speech, there must be some stability 
in the internal timing relations between the muscle events that 
underlie the phonetic percept (Harris, Tuller & Kelso, 1986). 
The nature o f the correlation between the durational parameters 
may reflect the speaker’s ability to maintain the internal timing 
relations between the durational parameters in order to achieve 
accurate production of the target words. Thus, in addition to 
measuring the degree o f variability of the above temporal pa­
rameters, the correlation between the durational parameters was 
also calculated.

Variability of motor speech control has been examined 
in different types of dysarthria. For example, according to Her- 
trich and Ackerman (1999), individuals with ataxic dysarthria 
are expected to exhibit increased variability of target positions 
and segmental durations. According to Reed and Franks 
(1998), individuals with Parkinson’s Disease (and associated 
hypokinetic dysarthria) display increased on-line adjustments 
to movement as movement complexity increases, leading to 
increased variability in motor performance. Turner and Tjaden 
(2000) found that individuals with spastic-flaccid dysarthria 
caused by Amyotrophic Lateral Sclerosis (ALS) display longer 
and more variable vowel durations than normal speakers. Previ­
ous research has also established that variability o f speech pro­
duction depends on the severity of the dysarthria under investi­
gation (McHenry, 2003). However, despite previous research 
into the variability o f the temporal control o f speech exhibited 
by individuals with dysarthria, the nature of these differences 
has not been compared across the different dysarthria types.
This is a preliminary study] which aimed to differentiate be­
tween programming-execution dysarthria and execution dy­
sarthria by examining variability of the temporal control of 
speech. Different patterns o f temporal control errors exhibited 
by the participants with programming-execution dysarthria as 
opposed to the participants with execution dysarthria may 
strengthen the hypothesis presented by the FLF (Van der 
Merwe, 1997; 2007) that programming-execution dysarthria 
should be differentiated from pure execution dysarthria. On the 
other hand, similar patterns o f errors for the different dyarthrias 
under investigation may suggest that the level o f impairment 
contributing to the timing disturbance in the three populations 
is the same.

METHOD 

Aims
I

The aim of this study was to examine the variability of tempo­
ral parameters during speech production of participants with

flaccid dysarthria, representative of execution dysarthria, and 
participants with hypokinetic dysarthria and ataxic dysarthria, 
representative o f programming-execution dysarthria.

The following sub-aims were formulated to facilitate 
achievement o f the main aim of this study:
• to determine and compare the degree o f variability of the 

temporal control of voice onset time (VOT) as well as the 
durational parameters o f vowel duration (VD), vowel 
steady state duration (VSSD), and vowel formant transition 
duration (VFTD) of the speech o f participants with flaccid 
dysarthria, hypokinetic dysarthria and ataxic dysarthria and 
their matched control participants across repeated produc­
tion of stimulus words

• to determine and compare the nature of the correlation be­
tween the durational parameters (VD, VSSD, VFTD) ex­
hibited by participants with flaccid dysarthria, hypokinetic 
dysarthria, ataxic dysarthria and their matched control par­
ticipants across repeated production o f the stimulus words 
as an index to the nature of the internal timing relations 
between the durational parameters

Research Design

A descriptive, non-experimental quantitative research design 
was selected for this study (Leedy, 1997). This type of research 
involves making careful descriptions o f observed phenomena, 
as well as the exploration o f possible relationships between 
these phenomena (Leedy, 1997). In achieving the first sub-aim 
of the study, the focus o f observation was on the variability of 
the temporal parameters of speech. In the second sub-aim, the 
extent to which differences in one durational parameter (e.g. 
duration of VSSD) were related to differences in another dur­
ational parameter was determined.

Participants

The participants were required to present with acquired flaccid 
dysarthria, hypokinetic dysarthria or ataxic dysarthria. The 
locus of the disease or damage was to be restricted to a single 
neurological structure so that the results obtained would reflect 
the pathology under investigation. The disease process dis­
played by each participant was required to have been diagnosed 
by a neurologist and the presence o f dysarthria confirmed by a 
qualified speech-language therapist experienced in the field of 
neuromotor speech disorders. The minimum and maximum age 
criteria were based on the processes related to the effects of age 
on the motor performance. The minimum age criterion was set 
at 18 years. A maximum age criterion o f 75 years was set. This 
study was not confined to members of a specific gender. The 
participants were required to be either first-language English or 
Afrikaans speakers as these are the languages in which the re­
searcher is proficient. The participants were required to have 
no abnormalities of the oral-facial structures other than those 
associated with the disease process responsible for dysarthria. 
All participants were to have a negative history of previous 
neurological, respiratory, speech or voice disorders. All partici­
pants were required to present with adequate comprehension, 
as determined through spontaneous conversation, so as to un­
derstand the instructions given, as well as adequate vision so as 
to be able to read the target phrases.

Six individuals were selected, by means o f non­
probability sampling (Leedy & Ormrod, 2005) to participate in 
this study. The sample was confined to six participants owing 
to the limited availability o f individuals with pure ataxic, hy­
pokinetic or flaccid dysarthria; and also due to the detailed data

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70 A lexandra Stipinovich and A nita van der M erwe

collection and analysis procedures followed. The participants 
are referred to as FD1, FD2, HD1, HD2, ADI and AD2, re­
spectively; where FD refers to flaccid dysarthria, AD to ataxic 
dysarthria and HD to hypokinetic dysarthria. A description o f 
the participants is provided in Table 1. Included in Table 1 is a 
description o f the perceptual speech characteristics o f each 
participant and an indication o f which participant from each 
dysarthria group presented perceptually with the more severe 
dysarthria. As indicated in Table 1, Participant FD1 was diag­
nosed with Amyotrophic Lateral Sclerosis (ALS). ALS is a 
form o f Motor Neuron Disease and is associated with damage 
to the upper motor neurons and lower motor neurons, typically 
resulting in a mixed form of dysarthria with bulbar (flaccid) 
and pseudobulbar (spastic) features (Duffy, 2005). Participant 
FD1 was included in this study as he presented with predomi­
nantly lower motor neuron signs. The muscle tone o f Partici­
pant F D l's speech structures was reduced and he exhibited 
decreased reflexes. The mixed nature o f ALS was, however, 
taken into consideration during the interpretation o f results.

T a b le  1: D escription o f  participants

Not one of the participants was receiving speech therapy at the 
time o f data collection. Each participant was asked to list the 
medications he or she was taking as well as the dosage thereof. 
The possible side-effects o f this medication were taken into 
account in the interpretation o f the results.

Five matched control participants were used to control 
for the effects o f age, gender and language. The control partici­
pants presented with perceptually normal speech, no structural 
or functional abnormalities of the oral-facial structures, and no 
history o f neurological, respiratory, speech, hearing and voice 
problems. The controls are referred to as CFD1, CFD2, CHD1, 
CHD2, CADI and CAD2. CFD1 and CHD1 is the same person 
as he could be matched with both Participant FD1 and Partici­
pant HD1. The matching o f one control participant to two par­
ticipants was not deemed problematic, as in no instances were 
the results o f the participants or control participants grouped 
together. Instead, the performance o f each of the participant 
was compared to that o f a matched control.

FD1 FD2 HD1 HD2 AD1 AD2

Etiology A m yo tro p h ic Lat­
eral Sclerosis

Ideopathic atro p h y o f low er 
m otor neuron N XII and NX

Ideopathic Parkin­
son’s D isease

Post-encephalitic 
Parkinson’s Dis­
ease

A ssa u lt to head 
w ith dam age to 
cerebellum .

G unshot 
w ound: occipi­
tal and cerebel­
lar atrophy.

Age 72 years 73 years 81 years 67 years 20 years 39 years

1 1 
Age at onset 64 years 72 years 68 years 55 years 19 years 38 years

Gender Male M ale Male Fem ale Male Fem ale

Language English Afrikaans English Afrikaans English A frikaans

Oral-facial
examination

|

G eneral w eakness. 
Predom inant low er 
m otor neuron 
sym ptom s. Re­
duced oral reflexes

D eviation o f tongue to left. 
A tro p hy and fasciculations 
o f left side o f tongue. Re­
duced range and rate of 
tongue m ovem ent.

Mild right-sided 
facial and tongue 
w eakness. Involun­
ta ry grim acing and 
spasm s o f the 
face. Mouth 
breathing.

Normal sym m etry. 
Popping o f TM 
joint. T re m ulou s­
ness and mild de­
viation o f tongue to 
right.

Right-sided facial 
and tongue 
w eakness. Pop­
ping o f TM joint. 
Associated ja w  
m ovem ents dur­
ing lateralization 
o f tongue.

R ate jof tongue 
and lip m ove­
m ents m ildly 
reduced.

i

Perceptual
characteristics

Poor intelligibility. 
Slow ed, laboured 
speech. D istorted 
consonants and 
vow els. H yperna­
sal. Low-pitched, 
harsh voice. M ono­
pitch and m ono­
loudness. Pro­
longed phonem es. 
Inappropriate si­
lences.

Less dysarthric than F D 1. 
Im precise lingual conso­
nants. Mild distortion o f 
velar consonants. Voice 
soft and breathy.

R educed stress. 
A ccelerated, dys- 
fluent speech. 
Im precise conso­
nants. Bilabial 
plosives produced 
as labiodental 
fricatives. M ono­
pitch and m ono­
loudness. Un­
steady, breathy 
voice. Mild flu ctu at­
ing nasality.

Less dysarthric 
than HD1. M ono­
pitch and m ono­
loudness and re­
duced stress. 
Breathy, trem ulous 
voice. Rapid rate. 
T endency to speak 
on residual air.

S low  rate. Harsh 
vocal quality. 
Periods o f apho­
nia. M ono-pitch 
and m ono­
loudness. Ex­
cess and equal 
stress. Im precise 
consonants. 
A rticulatory 
breakdown. Fluc­
tuating n a s a l i t y /

Less dysarthric 
th a n A D I. 
Excess and 
equal stress. 
S low  speech 
rate. Prolonged 
phonem es. 
C on so n an t and 
vowel distor­
tions.

Medication, 
dosage and time 
taken prior to 
data collection

Lanzor: 15mg daily 
(m ornings: 1 hour 
before data collec­
tion)
Xanor: 0.5 mg and 
C ipram il 20mg 
da ily (evenings)

C o-D iovan: 80mg, Lipitor: 
10 mg and Disprin: 150mg 
daily (m ornings: 1 hour 
before data collection) 
Diovan: 80m g, Aricpet: 5- 
10mg and Hytrin: 5-1 Omg 
daily (evenings)

M adopar: 
(levadopa 200m g; 
benserazide HCI 
50m g) Vi tablet 
every tw o hours. 
(Taken 30 m inutes 
before data collec­
tion)

Sinem et: 100mg 3x 
per day (Taken 1 
hour before d a t a ' 
collection)

None None.

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A cquired D ysarthria w ithin the C ontext o f the Four-level Fram ew ork o f Speech Sensorim otor Control 71

Ethical considerations

The study was cleared by the Faculty Research Proposal and 
Ethics Committee o f the University o f Pretoria. A letter ex­
plaining the aims and nature o f the study was presented to the 
potential participants. This letter was supplemented with a ver­
bal explanation o f the nature o f the study and the procedures 
involved in data collection. An informed consent form was at­
tached to the letter. The participants were asked either to sign 
this form, or to give verbal consent if unable to sign due to mo­
tor involvement.

Material used for data collection

The test material consisted o f 15 consonant-vowel-consonant 
(CVC) words embedded within the carrier phrase. ‘It’s a ....’ for 
English and, ‘Dit is ‘n ...’ for Afrikaans to accommodate speak­
ers o f both languages. By matching the participants with control 
participants, the impact o f possible differences in language was 
minimized to a large extent. Carrier phrases made it possible to 
elicit the target words in continuous speech while at the same 
time controlling the phonetic and phonological context. Each o f 
the target words had either a voiceless bilabial, alveolar or velar 
stop consonant in word-initial position so that variability o f the 
temporal parameters o f VOT and VFTD could be determined. 
The vowels /A, a, i, e, ae, u, o and a1 were included within the 
target words and represented the nucleus o f the stressed syllable 
of the utterance. Each sentence was printed on white cardboard 
in size 22 font. The form in which these words were presented to 
each subject is presented in Table 2. The meaning o f the Afri­
kaans words is indicated in brackets.

A CP 430 Stereo Marantz tape recorder and an AKG D 1200 E 
short distance, directional microphone were used to record the 
speech of the subjects. TDK IEC 1 / TYPE 1 cassettes were 
used for the recordings.

Apparatus used for data analysis

The CP 430 Stereo Marantz tape recorder was used to send the 
speech signal to the Computerized Speech Laboratory (CSL 
4300B) from the KAY Elemetrics Corporation. This signal was 
captured and analyzed by the digital signal processor. The speech 
signal was monitored with two JBL Pro 3 loudspeakers. The 
speech signal was presented on a NEC Multisync 2 display 
screen, where the time cursors and time axes were used to obtain 
the measurements on a dual display o f soundwave and wideband 
spectrogram.

Data collection procedures

Recordings were made by the first author in a soundproof envi­
ronment. The AKG D 1200 E short distance, directional micro­
phone was positioned within 15 cm of the participant’s mouth. 
The sentences were presented and read to the participants to fa­
miliarize them with the words and to answer any questions that 
they may have had. The participants were asked to read each sen­
tence 10 times at a comfortable rate, pausing between repetitions 
so that the final energy o f the target word did not run into the 
initial energy o f the first word of the next sentence. The utter­
ances were thus self-initiated and not imitated. Each sentence 
was held in front o f the participant. The researcher counted the 
number o f repetitions and indicated to the participant when ten 
repetitions were reached.

I
Acoustic analysis procedures

Acoustic Analysis o f  Voice Onset Time
Voice onset time (VOT) is defined as the interval be­

tween the release burst of the stop consonant and the appearance 
o f periodic modulation for a following sound (Kent & Read, 
1992). VOT was thus measured from the start o f the energy burst 
(indicating release of the stop closure) to the start o f the first full 
glottal (periodic) pulse of the vowel o f the target utterance. 
Forrest and Weismer (1997) define the first full glottal pulse o f a 
vowel as showing energy through at least the first two formants.

Acoustic Analysis o f  Vowel Formant Transition Duration
Vowel formant transition duration (VFTD) was measured 

after VOT was measured. A formant transition is defined as the 
segment o f the formant beginning at the burst release, and ending 
at the onset o f the steady state portion o f the vowel (Forrest & 
Weismer, 1997). In this study, the transition o f the vowel for­
mants was measured from the onset o f the vowel to the steady 
state portion o f the vowel. Only information pertaining to the 
vowel was obtained from this measurement. Thus, the term 
‘vowel formant transition duration’ is used in this study, and not 
‘consonant-vowel transition duration’. Both Formant 1 (F I) and 
F2 were taken into consideration when measuring the VFTD. 
Specific attention was paid to F2 transitions, as this formant ap­
pears to be most sensitive to the changes in the shape o f the vocal 
cavities (Gerratt, 1983). In certain cases where it was difficult to 
establish VFTD based on FI and F2, F3 was considered as well.

Acoustic Analysis o f  Vowel Steady State Duration
Vowel steady state duration (VSSD) was measured from 

the end o f the FI and F2 transition to the onset o f the VC-formant 
transition at the end o f the target word. According to Kewley- 
Port (1982), the onset of the steady state begins in that frame 
where frequency change falls to less than 10Hz per 5 millisecond 
frame.

T able 2: T arget phrases used in data collection

E n g lis h  p h ra s e s A frik a a n s  p h ra s e s

It’s a pet D it is ‘n pet (It is a cap)

It’s a pit D it is ‘n pit (It is a pip)

It’s a puck
i
D it is ‘n pak (It is a packet / suit)

It’s'a  pup ’D it is pap (It is porridge)

It’s a putt D it is ‘n pad (It is a road)

It’s a tack jDit is ‘n tek (short for technical college)

It’s a tick :Dit is ‘n tiek (It is a tic)

It’s a tip •Dit is ’n tip (It is a tip)

It’s a top D it is ‘n top (It is a top)

It’s a tuck Dit is ‘n tak (It is a branch)

It’s a cook D it is ‘n koek (It is a cake)

It’s a cop D it is ‘n kop (It is a head)

It’s a cu ff Dit is kaf (It is nonsense)

It’s a cup D it is ‘n kap (It is a hood)

It’s a cut D it is ‘n kat (It is a cat)

Apparatus used for data collection

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72 A lexandra Stipinovich and A nita van der Merwe

Acoustic Analysis o f  Vowel Duration
Vowel duration (VD) was measured from the onset o f the 

vowel, (from the first full glottal pulse) to the last full glottal 
pulse. This final glottal pulse showed periodic energy through 
the first and second formants as suggested by Forrest and Weis- 
mer (1997).

Reliability and Validity

To ensure reliability, 15% (every third repetition) o f the data was 
re-analyzed by the first author. According to Seddoh et al. 
(1996), a difference o f 3 msecs between the original value and 
the value obtained during the reliability check is considered reli­
able. In a study performed by Smith and Kenney (1994), an av­
erage difference o f 4 msecs (with a range o f 2 msecs to. 10 
msecs) was considered acceptable. In this study, a difference o f 
10 msecs or less was considered reliable for the durational meas­
urements. A difference of 5 msecs or less was deemed reliable 
for the temporal parameter o f VOT. The following formula was 
used to calculate the reliability o f data analysis for each partici­
pant (Shriberg & Kent, 1982):

N um ber o f  units scored similarly 
Percentage o f  agreem ent = Total num ber o f  units scored

Overall, 93% (range: 88% - 99%) agreement was ob­
tained. A researcher who has a master’s degree in the field of 
acoustic analyses was consulted for assistance whenever prob­
lematic analyses arose and, in so doing, functioned as the second 
analyser.

Controlling the environment in which data collection took 
place enhanced the internal validity of the study. In addition, all 
possible factors, which may have influenced the results obtained 
(for example the use o f medication by certain participants and 
the relative severity o f the dysarthria), were taken into account in 
the interpretation o f the results (Leedy & Ormrod, 2005). Partici­
pants who were representative o f individuals with ataxic, hy­
pokinetic and flaccid dysarthria were selected ensure external 
validity o f the study (Leedy & Ormrod, 2005). Participant FD1 
presented with a mixed form o f dysarthira. However, he was 
selected to participate in this study, as his symptoms were pre­
dominantly flaccid in nature. Participant F D 1 was therefore con­
sidered representative o f individuals with execution dysarthria.

Data analysis procedures

In this study, the degree o f variability o f speech, as well as the 
correlation between the durational parameters o f speech were 
determined by means o f descriptive statistics (Leedy & Ormrod, 
2005).

Data Analysis Procedure f o r  Sub-Aim 1
The purpose of Sub-aim 1 was to determine the degree o f  

variability o f motor speech performance o f the participants and

their matched controls. A measure o f dispersion, the coefficient 
o f  variation, was used to determine the degree o f variability of 
each temporal parameter. The coefficient of variation, which is 
the standard deviation squared, is a dimensionless index, allow­
ing measures o f different sizes and units to be compared (Leedy, 
1997; Leedy & Ormrod, 2005). The coefficient o f variation was 
calculated for each temporal parameter across the first nine repe­
titions of each o f the 15 stimulus words produced by the partici­
pants and control participants. The tenth repetition o f each 
stimulus word was omitted as most participants uttered the final 
repetition with greater emphasis as if to indicate that this was the 
final word o f the series. This change in emphasis would not be 
representative o f the former nine repetitions. The 15 coefficients 
o f variation for each temporal parameter were then averaged for 
each participant and control participant. In this way, the overall 
degree of variability o f speech was determined for each dy­
sarthric participant and control participant. A comparison was 
then made o f the overall degree o f variability o f speech between 
the dysarthric speakers and the control participants, and between 
the different types o f dysarthria.

Data Analysis Procedure f o r  Sub-Aim 2
The purpose o f Sub-aim 2 was to determine the correla­

tion between VD and VSSD, between VD and VFTD and be­
tween VSSD and VFTD across repeated production o f the stimu­
lus words by the participants. A Pearson product moment corre­
lation (Leedy & Ormrod, 2005) was applied to calculate the cor­
relation coefficient between the durational parameters. Only the 
correlation between the durational parameters was calculated. 
The correlation coefficient was calculated for each durational 
parameter across all the words produced by the participants with 
dysarthria as well as their matched control participants. A com­
parison of the correlation between the durational parameters of 
the dysarthric speakers and the control participants, and between 
the different types o f dysarthria was performed through subjec­
tive inspection o f the data.

RESULTS

Degree o f variability of the temporal parameters

The coefficients o f variation calculated for each temporal pa­
rameter across repeated production of the 15 stimulus words are 
presented in Table 3 for each participant as well as each matched 
control participant. '

As indicated in Table 3, all o f the dysarthric speakers, 
excluding Participant FD2, exhibited greater variability of the 
temporal control of speech than their matched controls. Partici­
pant FD2 (who represented execution dysarthria), exhibited less 
variability than his matched control with regard to all the tempo­
ral parameters with the exception of VOT (28.13). Participant 
FD2 also exhibited the lowest degree o f variability o f VD (6.91) 
and VSSD (9.13) when compared with the other dysarthric 
speakers. In contrast to the relatively low degree o f variability of

T a b le  3: C oefficients o f  variation o f  the tem poral param eters o f  vow el duration, vow el steady state duration, vow el form ant transition duration and 
voice onset time

Temporal
Parameters

FD1 CFD1 FD 2 CFD2 HD1 CHD1 HD2 CHD2 AD1 CAD1 AD2 CAD2

VD 22.95 7.09 6.91 7.07 9.95 7.09 10.81 6.01 9.81 9.07 9.94 7.19

VSSD 21.73 7.40 9.13 9.86 12.75 7.40 14.28 8.78 13.9 9'' 10.04 10.47 9.73

VFTD 39.38 21.37 28.58 29.07 41.77 21.37 29.99 27.72 37.60 36.97 28.35 29.06

VOT 63.01 12.73 28.13 20.63 18.89 12.73 21.84 13.37 25.43 16.38 26.54 17.08

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Acquired D ysarthria w ithin the C ontext o f  the Four-level Fram ew ork o f Speech Sensorim otor Control

the temporal control o f speech exhibited by Participant FD2, 
Participant FD1 (who also represented execution dysarthria) 
showed the highest degree o f variability for each of the tempo­
ral parameters, excluding VFTD when compared with the con­
trols and the other dysarthric speakers. The possible influence 
o f upper motor neuron involvement in Participant FD1 may 
have contributed to the high degrees o f variability exhibited by 
this participant. Participant HD1 exhibited the highest overall 
degree o f variability o f VFTD (41.77). From the information 
presented in Table 3 it would therefore appear that program­
ming-execution dysarthria cannot be distinguished from execu­
tion dysarthria on the basis o f the overall degree o f variability 
o f speech alone.

A comparison o f the degree o f intra-subject variability 
o f each o f the temporal parameters (Table 3) reveals differ­
ences in performance between the participants with program­
ming-execution dysarthria and participants with execution dy­
sarthria. For each o f the control participants as well as the par­
ticipants with programming-execution dysarthria, variability o f 
VOT (which reflects interarticulatory synchronization) was 
greater than the durational parameters o f VD and VSSD, but 
less variable than VFTD. The participants with programming- 
execution dysarthria thus followed the same pattern o f variabil­
ity as the control participants with regard to intra-subject vari­
ability o f the temporal parameters o f speech. In contrast, Par­
ticipant FD1 (representing execution dysarthria), exhibited 
greater variability o f VOT (63.01) than any o f the durational 
parameters (VD: 22.95; VSSD: 21.73 and VFTD: 39.38). Par­
ticipant FD2, who is considered to be a more true reflection o f 
a lower motor neuron lesion than Participant FD1, obtained 
coefficients of variation o f 28.13 for VOT and 28.58 for VFTD. 
Thus, while Participant FD2, like the other dysarthric speakers 
and control participants exhibited greater intra-subject variabil­
ity o f VFTD than VOT, the difference in variability was not as 
great. In summary, it would appear that the participants with 
programming-execution dysarthria followed the same pattern 
o f variability as the control participants with regard to the intra­
subject variability of the temporal parameters, while the partici­
pants with execution dysarthria did not.

Correlation between durational parameters

The averages o f the correlation coefficients between the dur­
ational parameters o f VD, VSSD and VFTD exhibited by each 
participant and control participant across repeated production 
of the stimulus word are indicated in Table 4.

According to the information presented in Table 4, 
each o f the dysarthric speakers achieved the highest correlation 
between the durational parameters o f VD and VSSD. Thus, for 
each o f the dysarthric speakers, an increase in milliseconds o f 
VD was accompanied by a concomitant increase in millisec­
onds o f VSSD. The same appears to be true for each o f the con­
trol participants with the exception of CAD2 who achieved a 
higher correlation coefficient (0.43) between VD and VFTD

than between VD and VSSD (0,40). Furthermore, for each o f 
the dysarthric speakers, as well as their matched control partici­
pants, the correlation between VD and VFTD was also posi­
tive. Finally, the lowest correlation exhibited by each o f the 
dysarthric speakers as well as their matched controls was found 
between VSSD and VFTD. It would thus appear that each of 
the dysarthric speakers followed the same trends as the normal 
speakers with regard to the nature o f the correlations between 
the durational parameters. It was therefore not possible to dif­
ferentiate between programming-execution dysarthria and exe­
cution dysarthria based on the nature o f the correlation between 
the durational parameters.

DISCUSSION 

Variability o f temporal parameters

The results regarding the degree o f variability o f the temporal 
control o f speech revealed that each o f the dysarthric speakers, 
with the exception o f participant FD2, exhibited greater vari­
ability than the control participants. Participant FD2 exhibited 
less variability o f vowel duration, vowel steady state duration 
and vowel formant transition duration, but greater variability of 
voice onset time than his matched control participant. The find­
ing that the dysarthric speakers were more variable than the 
controls is in agreement with previous research investigating 
variability o f dysarthric speech. For example, increased vari­
ability o f vowel durations in individuals with ALS has been 
reported (Turner & Tjaden, 2000; Weismer, Tjaden & Kent,
1996). Increased variability o f motor speech performance in 
hypokinetic dysarthria associated with Parkinson’s Disease 
(Reed & Franks, 1998) as well as in ataxic dysarthria (Hertrich 
& Ackermann, 1999) has also been reported. If temporal vari­
ability o f speech is indeed an indication o f the precision or reli­
ability o f motor control (Kent et al., 1991), then it is to be ex­
pected that dysarthric speakers would show greater variability 
of the temporal control o f speech than the control participants. 
All the dysarthric speakers, with the exception o f participant 
FD2 (excluding voice onset time) confirmed this prediction. 
However, it was not possible, in this study, to differentiate pro­
gramming-execution dysarthria from execution dysarthria on 
the basis o f the overall degree o f variability o f speech. For ex­
ample, in contrast to the relatively low degrees of variability 
exhibited by Participant FD2, Participant FD1 (representing the 
same dysarthria group as Participant FD2) exhibited the highest 
overall degree of variability o f vowel duration, vowel steady 
state duration and voice onset time. The possibility exists that 
variables such as age, medication, the presence o f involuntary 
movements (Gerratt, 1983), speech rate (Kent et al., 1991; 
McHenry, 2003) and the severity o f dysarthria (Kent et al., 
1979; McHenry, 2003) contribute in a particular way to the 
overall degree o f variability exhibited by dysarthric speakers. 
Differences due to these factors thus complicate the differentia­
tion between the levels o f breakdown in dysarthria.

73

T able 4: Correlation coefficients between the durational parameters of vowel duration, vowel teady state duration and vowel formant transition 
duration

FD1 CFD1 FD2 CFD2 HD1 CHD1 HD2 CHD2 AD1 CAD1 AD2 CAD2

Correlation between VD 
and VSSD

0.76 0.82 0.69 0.80 0.85 0.82 0.70 0.88 0.80 0.73 0.80 0.40

Correlation between VD 
and VFTD

0.64 0.79 0.47 0.24 0.29 0.79 0.60 0.44 0.4 0.22 0.37 0.43

Correlation between 
VSSD and VFTD

0.32 0.48 0.12 -0.26 -0.06 0.48 0.25 0.31 0.00 -0.04 0.15 -0.07

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74 A lexandra Stipinovich and A nita van d er M erwe

A comparison o f the temporal parameters showing the 
highest degrees o f variability revealed differences between pro­
gramming-execution dysarthria and execution dysarthria. For 
each o f the dysarthric speakers as well as each o f the control 
speakers, voice onset time was more variable than vowel dura­
tion and vowel steady state duration, but less variable than 
vowel formant transition duration. In contrast, Participant FD1 
(representing execution dysarthria) exhibited greatest variability 
o f voice onset time. Similarly, Participant FD2 (also represent­
ing execution dysarthria) showed relatively high degrees o f in­
tra-subject variability o f VOT when compared with the other 
temporal parameters. It would therefore appear that the indi­
viduals with programming-execution dysarthria followed the 
same patterns o f variability as the control participants, despite 
showing a higher overall degree of variability o f motor speech 
control. The individuals with execution dysarthria, on the other 
hand, do not appear to have followed the same trends as the 
normal speakers or the participants from the programming- 
execution dysarthria group with regard to intra-subject variabil­
ity o f the temporal parameters.

The similar performance o f the individuals with pro- 
gramming-execution dysarthria to that o f the control partici­
pants regarding intra-subject variability o f the temporal parame­
ters may be explained by the possibility o f the participants with 
hypokinetic dysarthria and ataxic dysarthria resorting to em­
ploying cortical mechanisms to control motor performance 
(Brooks, 1986). While this is likely to take longer and move­
ments are likely to be executed less automatically, the possible 
cortical control over movements in individuals with basal gan­
glia or cerebellar involvement may reflect greater movement 
control than that seen in an individual with flaccid dysarthria 
who has intact motor planning and motor programming abili­
ties, but an inability to execute movements according to the 
specifications o f  these plans and programmes due to impaired 
lower motor neurons (Von Gruenewaldt, 2003).

The relatively high degrees o f intra-subject variability o f 
voice onset time exhibited by Participants FD1 and FD2 may be 
interpreted within the context o f the FLF (Van der Merwe, 
1997; 2007). Voice onset time reflects inter-articulatory syn­
chronization (Van der Merwe, 1997) and assesses the temporal 
coordination o f the vocal folds and the oral articulators. Accord­
ing to the FLF (Van der Merwe, 1997; 2007), the potential for 
inter-articulatory synchronization is created on the motor plan­
ning level o f the speech production process. If this is true, then 
Participants FD1 and FD2 (each representing execution dy­
sarthria) possess the potential to plan the synchronization be­
tween the oral and laryngeal articulators for voice onset time. In 
addition, they possess the ability to specify motor programmes 
for the muscles o f the necessary articulators. However, the coor­
dinated execution o f the movements o f the articulators accord­
ing to the specifications o f the motor plan and programme is 
likely to be impaired in these speakers. The degree to which the 
execution o f movements required for voice onset time is im­
paired, is likely to be related to the extent to which the motor 
neurons are impaired. The finding that Participant FD2 was less 
variable with regard to voice onset time than Participant FD1 
may therefore be because Participant FD2 only needed to coor­
dinate weak tongue and velar movements with intact laryngeal 
articulators. In ALS, the articulatory structures are not all af­
fected to the same degree (DePaul & Brooks, 1993). The coor­
dinated execution o f movements of the oral and laryngeal ar­
ticulators was thus likely to have been more difficult for Partici­
pant FD1.

In summary, each o f the dysarthric speakers, with the 
exception o f Participant FD2 (excluding voice onset time), ex­

hibited greater overall variability o f the temporal control of 
speech than their matched control participants. The individuals 
with programming-execution dysarthria followed similar pat­
terns o f variability to the control group. In contrast, the partici­
pants with execution dysarthria differed with regard to the pat­
tern o f variability exhibited when compared with the partici­
pants with programming-execution dysarthria and the control 
group. This is a possible indication that individuals with pro­
gramming-execution dysarthria resort to a different level of 
control than individuals with execution dysarthria.

Interactive control of durational parameters

The results o f the correlation analysis showed that all the par­
ticipants (with the exception o f CAD2) achieved the highest 
correlation between the durational parameters o f vowel dura­
tion and vowel steady state duration. The correlation between 
vowel duration and vowel formant transition duration was also 
positive (again, with the exception o f CAD2). For each o f the 
participants, the lowest correlation was found between vowel 
steady state duration and vowel formant transition duration. In 
summary, the general trend o f the current research results sug­
gests that the dysarthric speakers performed in a similar way to 
the control participants with regard to the nature o f the correla­
tion between the durational parameters. The implication of 
these results is that the dysarthric speakers, regardless o f fac­
tors such as the degree o f variability o f motor speech perform­
ance, age, medication, the presence of involuntary movements, 
speech rate, and severity o f dysarthria, were able to maintain 
the internal timing relations between the durational parameters.

The positive correlation between vowel duration and 
vowel steady state duration and between vowel duration and 
vowel formant transition duration exhibited by the control par­
ticipants is not unexpected. Given that there can be consider­
able changes in absolute duration and magnitude o f individual 
muscle events, there must be some stability in the internal rela­
tions between muscle events that underlie the phonetic percept 
(Harris et al., 1986). Thus, for many skilled activities, it is the 
internal timing relations that are preserved over such transfor­
mations as rate and force changes.

The reason for the ability o f the dysarthric speakers to 
maintain the internal timing relation between the i durational 
parameters is unclear. In addition, there is no existing data with 
which the correlation coefficients reported in this study may be 
compared. The possibility exists that, despite the higher de­
grees o f variability o f the individual temporal parameters ex­
hibited by the dysarthric speakers (with the exception o f FD2) 
when compared with the control participants, the dysarthric 
speakers may have been able to consciously control the relative 
duration o f the movements executed, thereby preserving the 
perceptual identity o f the words produced. Alternatively, the 
dysarthric speakers may have implemented compensatory tech­
niques to preserve the perceptual identity o f words. For exam­
ple, individuals with ALS exhibit consistently greater weakness 
in the tongue as compared to the jaw  and lower lip (DePaul & 
Brooks, 1993). Increasing the range o f jaw  opening 
(particularly during the production o f vowels) is seen to be a 
strategy to compensate for reduced tongue movement (DePaul 
& Brooks, 1993; Turner & Tjaden, 2000) and is achieved by 
adjusting the motor programmes of the muscles o f the jaw. If 
this is the case, the jaw may become the primary articulator in 
an individual with ALS, resulting in the jaw, lower lip and 
tongue moving together as a single mass. If this is so, then one 
could expect to see a linear relationship between vowel dura­
tion and vowel steady state duration and between vowel steady

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A  q u ir e d  D ysarthria w ithin the C ontext o f the Four-level Fram ew ork o f Speech Sensorim otor C ontrol 75

state duration and vowel formant transition duration in
a  s p e a k e r  w i t h  A L S .

Whatever the reason may be for the maintenance 
o f the internal timing relations between the durational 
parameters by the dysarthric speakers, it was not possi­
ble on the basis o f the correlation analysis, to differen­
tiate between programming-execution dysarthria and 
execution dysarthria. It was also not possible, however, 
to differentiate the dysarthric speakers from the normal 
speakers on the basis of the correlation analysis. The 
internal timing relations between the durational pa­
rameters of words may therefore not be a sensitive in­
dex of pathology. Additional indeces o f variability 
which may further explore the hypothesis set by the 
FLF (Van der Merwe, 1997; 2007), namely that pro­
gramming-execution dysarthria differs from execution 
dysarthria must be investigated.

CONCLUSION

This study was a preliminary exploration o f the vari­
ability o f motor speech performance o f individuals with 
flaccid dysarthria, hypokinetic dysarthria and ataxic 
dysarthria in an attempt to differentiate between pro­
gramming-execution dysarthria and execution dy­
sarthria. The FLF (Van der Merwe, 1997; 2007) was 
used as the conceptual framework for this study. The 
degree o f variability o f motor speech performance, and 
the correlations between the durational parameters of 
speech were investigated as possible indeces to differ­
entiate between the dysarthria types.

The dysarthric speakers performed in a similar 
way to the control participants regarding the correla­
tions between the durational parameters. It was there­
fore neither possible to differentiate between the control 
participants and the dysarthric speakers, nor between 
the participants with programming-execution dysarthria 
and the participants with execution dysarthria, on the 
basis o f the correlation analysis. Investigation o f corre­
lation between the durational parameters may therefore 
not have been an accurate index to pathology. 
Examination o f the degree o f variability of the temporal 
parameters of speech showedjthat the participants with 
hypokinetic and ataxic dysarthria (representing pro­
gramming-execution dysarthria) exhibited the same 
patterns o f variability as the | controls regarding intra­
subject variability of the temporal parameters. In con­
trast, the participants representing execution dysarthria 
exhibited relatively higher degrees o f intra-subject vari­
ability o f voice onset time. These differences found in 
the patterns o f variability support the hypothesis pre­
sented by the FLF (Van der Merwe, 1997; 2007), that 
individuals with programming-execution dysarthria 
resort to a different level o f control than those with exe­
cution dysarthria. It is recommended that more exten­
sive research be performed on the variability o f motor 
speech performance normal speakers. In addition, it is 
recommended that future research investigating vari­
ability o f motor speech performance in dysarthria be 
performed using larger speaker groups in which speak­
ers are matched for severity o f dysarthria. Additional 
indeces o f variability should be explored to further in­
vestigate the hypotheses set by the FLF (Van der 
Merwe, 1997; 2007).

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