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R van Toorn
MB ChB, (Stell) MRCP (Lond), FCP (SA)
Specialist
Department of Paediatrics and Child Health
Faculty of Health Sciences
Stellenbosch University and
Tygerberg Children’s Hospital
Ronald van Toorn obtained his medical
degree from the University of Stellenbosch,
and completed his paediatric specialist
training at both Red Cross Children’s
Hospital in Cape Town and the Royal
College of Paediatricians in London. One
of his interests is in the field of neuromus-
cular medicine. His working experience
includes the neuromuscular clinics attached
to Birmingham Children’s, Red Cross
Children’s, Guy’s and St Thomas’ hospitals.
CLINICAL APPROACH TO THE
FLOPPY CHILD
The floppy infant syndrome is a well-recognised entity for paediatricians and
neonatologists and refers to an infant with generalised hypotonia presenting at birth
or in early life. An organised approach is essential when evaluating a floppy infant,
as the causes are numerous.
A detailed history combined with a full systemic and neurological examination
are critical to allow for accurate and precise diagnosis. Diagnosis at an early
stage is without a doubt in the child’s best interest.
HISTORY
The pre-, peri- and postnatal history is important. Enquire about the quality and
quantity of fetal movements, breech presentation and the presence of either poly-
or oligohydramnios. The incidence of breech presentation is higher in fetuses
with neuromuscular disorders as turning requires adequate fetal mobility.
Documentation of birth trauma, birth anoxia, delivery complications, low cord
pH and Apgar scores are crucial as hypoxic-ischaemic encephalopathy remains
an important cause of neonatal hypotonia. Neonatal seizures and an encephalo-
pathic state offer further proof that the hypotonia is of central origin. The onset
of the hypotonia is also important as it may distinguish between congenital and
aquired aetiologies. Enquire about consanguinity and identify other affected fam-
ily members in order to reach a definitive diagnosis, using a detailed family
pedigree to assist future genetic counselling.
CLINICAL CLUES ON NEUROLOGICAL EXAMINATION
There are two approaches to the diagnostic problem. The first is based on identi-
fying the neuro-anatomical site of the lesion or insult. The second is to determine
whether or not the hypotonia is accompanied by weakness. Careful neurological
examination should, in most cases, localise the site of the lesion to the upper
motor neuron (UMN) or lower motor neuron (LMN) unit. Useful clues are listed in
Fig. 1.
Next assess whether the hypotonia is accompanied by weakness. Weakness is
uncommon in UMN hypotonia except in the acute stages. Hypotonia with pro-
found weakness therefore suggests involvement of the LMN. Assessment of muscle
power of infants is generally limited to inspection.
Useful indicators of weakness are:
• Ability to cough and clear airway secretions (‘cough test’). Apply pressure to
the trachea and wait for a single cough that clears secretions. If more than
one cough is needed to clear secretions, this is indicative of weakness.2
• Poor swallowing ability as indicated by drooling and oropharyngeal pooling
of secretions.
• The character of the cry — infants with consistent respiratory weakness have
a weak cry.
• Paradoxical breathing pattern — intercostal muscles paralysed with intact
diaphragm.
THE FLOPPY CHILD
August 2004 Vol.22 No.8 CME 449
• Frog-like posture and quality of
spontaneous movements — poor
spontaneous movements and the
frog-like posture are characteristic
of LMN conditions.
Further confirmation of the last indica-
tor can be obtained by means of infor-
mal neurological examination in the
test positions. Excessive head lag will
be evident on ‘pull to sit’. Minimal
support with a sensation of ‘slipping
through he hands’ during vertical sus-
pension testing and inverted U posi-
tion on ventral suspension are further
indicators (Fig. 2.1 and 2.2).3
Floppy strong
Increased tendon reflexes
Extensor plantar response
Sustained ankle clonus
Global developmental delay
Microcephaly or suboptimal
head growth
Obtundation convulsions
Axial weakness a significant
feature
Upper motor neuron
disorder
Central hypotonia
Lower motor neuron
disorder
Peripheral hypotonia
Creatine kinase assay
EMG
Nerve conduction
studies
Genetic studies
Karotyping
FISH methylation studies
VLCFA
Triosomy 21
Prader-Willi syndrome
Zellweger syndrome
Hypoxic ischaemic
encephalopathy
Cerabral malformations
Congenital
structural
myopathies
Spinal muscuar
dystrophy
Congenital myotonic
dystrophy
Congenital muscular
dystrophies
CT/MRI DNA-based mutation
analysis if available
Muscle or nerve
biopsy
Floppy weak
Hypo- to areflexia
Selective motor delay
Normal head circumference
and growth
Preserved social interaction
Weakness of antigravitational
limb muscles
Low pitched weak cry
Tongue fasciculations
Paradoxical chest wall
movement
Fig. 1. Clinical clues on neurological examination (EMG = electromyogram: CT= computed tomograph; MRI = magnetic
resonance imaging; VLCFA = very long-chain fatty acids; FISH = fluorescent in situ hybridisation)
THE FLOPPY CHILD
450 CME August 2004 Vol.22 No.8
A distinct pattern of weakness may
favour certain aetiologies:
• Axial weakness is a significant fea-
ture in central hypotonia.
• Generalised weakness with sparing
of the diaphragm, facial muscles,
pelvis and sphincters suggests ante-
rior horn cell involvement.
• With myasthenic syndromes, the
bulbar and oculomotor muscles
exhibit a greater degree of involve-
ment.
• Progressive proximal symmetrical
weakness suggests a dystro-
phinopathy. Signs of proximal
weakness in the older infant
include a lordotic posture,
Trendelenburg gait and Gower
sign.
• A striking distribution of weakness
of the face, upper arms and shoul-
ders suggests fascioscapulohumeral
muscular dystrophy.
• Distal muscle groups are predomi-
nantly affected with peripheral neu-
ropathies. Signs suggesting distal
weakness in an older infant would
include weakness of hand grip,
foot drop and a high stepping,
slapping gait.
THE FLOPPY WEAK INFANT
Table I gives a comprehensive
approach to the clinical clues and
investigations for the more common
phenotypes of the weak floppy infant.
Once the lesion has been localised to
the LMN proceed with further neu-
roanatomical localisation according to
the compartments of the LMN. The
compartments and disease associa-
tions are listed in Fig. 3.
Examine the tongue for size and fasci-
culations. Fasciculations, irregular
twitching movements, generally indi-
cate an abnormality of the anterior
horn cells (Fig. 4). Do not examine the
tongue while the infant is crying. The
co-existence of atrophy would strongly
favour a denervative aetiology. An
ECG may be helpful in demonstrating
baseline fasciculations of the inter-
costal muscles (Fig 5). Enlargement of
the tongue may suggest a storage dis-
order such as Pompe’s disease.
The presence of a facial diplegia
(myopathic facies) suggests either a
congenital structural myopathy or
myasthenia gravis. Respiratory and
bulbar weakness can accompany
both conditions. Fluctuation in strength
would favour myasthenic syndromes
(Fig. 6).
Where clinical evaluation suggests
complex multisystem involvement (i.e.
hypotonia plus) inborn errors of
metabolism should be excluded.
Referral to a tertiary centre for meta-
bolic investigations would then be
indicated.
THE FLOPPY STRONG CHILD
The presence of facial dysmorphism
should alert the doctor to the possibili-
ty of an underlying syndrome or genet-
Fig. 2.1. A 12-week-old male infant with
excessive headlag evident on ‘pull-to-sit’.
Note the hypotonic posture of the legs
with external rotation.
Fig. 2.2. The same infant in horizontal
suspension. Note the inverted U posture.
Fig. 4. Tongue fasciculations in a child
with spinal muscular atrophy. The com-
bination of fasciculations with atrophy
is strongly indicative of muscle dener-
vation.
Fig. 5. ECG of a floppy infant with spinal muscular atrophy demonstrating base-
line fasciculations arising from the underlying intercostal muscles.
Fig. 6. Ptosis and external ophthalmo-
plegia in a floppy weak child sugges-
tive of myasthenia gravis.
THE FLOPPY CHILD
August 2004 Vol.22 No.8 CME 451
Nerve fibre: neuropathies
(Demyelinating or axonal)
Acquired: Guillain-Barré syndrome
Infectious: diphtheria, syphilis, coxsackie, HIV
Toxic: drugs, heavy metals
Nutritional: Vit B1, B6, B12, E, folate
Endocrine: Diabetes, uraemia
Metabolic neurodegenerative causes
Hereditary: Charcot-Marie-Tooth disease
Muscle
Dystrophinopathies (lack of specific muscle protein):
Duchenne, Becker’s fascioscapular humeral, limb gir-
dle and congenital muscular dystrophies
Congenital myopathies (abnormal muscle structure)
Muscle membrane disorders: congenital myotonias,
congenital myotonic dystrophies
Inflammatory myopathies: dermatomyositis,
poliomyositis
Metabolic myopathies: lipid glycogen storage dis-
eases
Endocrine myopathies: hypothyroidism
Energy depletion within muscle: mitochondrial, free-
fatty acid oxidatation and carnitine disorders
Anterior horn cell:
Spinal muscular atrophy
Poliomyelitis
Neuromuscular junction
Myasthenia gravis
Botulism
Fig. 3. LMN comportments and disease associations.
THE FLOPPY CHILD
452 CME August 2004 Vol.22 No.8
Table I. Clincical clues and investigations of the more common phenotypes of the floppy weak infant
Condition Clinical clues Investigations
Spinal cord transection or Haemangioma or tuft of hair in midline MRI spinal cord
disease Scoliosis
Syringomyelia or other forms Evidence of bladder or bowel dysfunction
of spinal dysraphism Mixed deep tendon reflexes with absent
abdominal and anal reflexes
Spinal muscular atrophy Tongue atrophy and fasciculations ECG: Baseline fasciculations
Paradoxical breathing pattern Deletion of the survival motor
Severe proximal muscle weakness with neuron (SMN) gene by PCR
absent tendon reflexes testing
Preserved social interaction
Peripheral neuropathy Weakness predominantly distal Motor nerve conduction
In most cases absent deep tendon reflexes studies
Pes cavus Sural nerve biopsy
Molecular DNA testing is
available for specific
demyelinating disorders
Myasthenia gravis Greater involvement of oculomotor and Response to acethylcholine
bulbar muscles esterase inhibitors
True congenital myasthenia due to receptor Single-fibre EMG
defects is rare Serum antibodies to
Exclude transient neonatal form from acethylcholine receptors
maternal history Electrodiagnostic studies not
universally positive in young
patients
Infantile botulism Acute onset descending weakness, Isolation of organism from
cranial neuropathies, ptosis, stool culture
unreactive pupils, dysphagia, Presence of toxin in the stool
constipation
Congenital muscular Hypotonia, weakness and contractures Creatine kinase usually
dystrophy at birth elevated
Associated brain and eye problems Brain MRI for structural and
white matter abnormalities
Muscle biopsy: merosin stain
Congenital myotonic Polyhydramnios with reduced fetal Molecular DNA testing by
dystrophy movements determining number of CTG
Inverted V-appearance of the mouth repeats (normal range 5 - 39
Examination of mother’s face shows inability repeats)
to bury her eyelashes and grip myotonia EMG of the mother
Premature cataract surgery in the mother
Congenital structural Slender stature CK and EMG usually not
myopathy Hypotonia with feeding problems at birth helpful
Weakness that is often non-progressive Muscle biopsy is critical for
Nemaline myopathy: often associated with definitive diagnosis.
feeding problems ECG when nemaline and
Central core: most often associated with desmin myopathies are
malignant hyperthermia suspected
Myotubular myopathy: Ptosis and The genetic basis for several
extraocular palsies consistent of the congenital myopathies
clinical features has now been determined
Glycogen storage disease Enlarged heart in a very floppy weak Blood smear vacuolated
Pompe’s disease newborn lymphocytes
Unexplained cardiac failure Urine oligosaccharides
Tongue may appear large Typical ECG and ECHO
changes
Acid maltase assay in
cultured fibroblasts
Muscle biopsy usually not
necessary
THE FLOPPY CHILD
August 2004 Vol.22 No.8 CME 453
ic disorder. Conditions that need to be
excluded include trisomy 21, Prader-
Willi and Zellweger syndrome. At
birth the facial anomalies in Prader-
Willi syndrome are often insignificant
and the diagnosis is usually only
established after onset of obesity.
Useful early markers include the pres-
ence of feeding difficulties, small
hands and feet, almond shaped eyes,
narrow bifrontal diameter and hypogo-
nadism (Fig. 7). Failure to identify
electrophysiological abnormalities in a
neonate with profound hypotonia
should prompt testing for Prader-Willi
syndrome. This can be done by a
DNA methylation study which will
detect 99% of cases.
Zellweger syndrome presents in the
newborn with typical facial dysmor-
phism including high forehead, wide
patent fontanelles and sutures, shallow
orbital ridges, epicanthus and microg-
nathia. Neurological manifestations
are dominated by severe hypotonia
with depressed or absent tendon
reflexes, and poor sucking and swal-
lowing. Hepatomegaly and liver dys-
function are consistent findings.
VALUE AND CHOICE OF
DIAGNOSTIC MODALITIES
Special investigations should be guid-
ed by clinical findings. Evaluation of
tone and power should be delayed in
the systemically unwell nutritionally
compromised child. Infective and bio-
chemical parameters should first be
normalised before attempts are made
to examine tone and power.
Hypokalaemia and hypophospha-
taemia in particular will cause
reversible weakness. Serum albumin,
calcium, phosphorus, alkaline phos-
phatase and thyroxine levels will pro-
vide confirmation of clinical suspicion
in malnutrition, ricketts and hypothy-
roidism.
SUSPECTED CENTRAL CAUSE
For infants with central hypotonia, ini-
tial investigations include karyotype
and neuroimaging (CT or MRI scan). A
karyotype is a must in the dysmorphic
hypotonic child. This can be combined
with FISH testing if Prader-Willi syn-
drome is suspected. Cranial MRI will
identify patients with structural CNS
malformations, neuronal migration
defects and those with white matter
changes (congenital muscular dystro-
phies in particular). Hypotonia may
also be prominent in connective tissue
diseases such as Ehlers Danlos or
Marfan’s syndrome. An excessive
range of joint mobility, unusual joint
postures, the ability to do various con-
tortions of the limbs and/or hyperelas-
ticity of the skin are important diag-
nostic clues. Although metabolic disor-
ders are well recognised as the cause
for central hypotonia, because of the
rarity of the conditions, the diagnostic
yield is low. Very long-chain fatty
acids (VLCFA) testing should be per-
formed if a peroxisomal disorder such
as Zellweger is suspected.
SUSPECTED PERIPHERAL
CAUSE
Major discoveries have been made in
the genetic analysis of the muscular
dystrophies, spinal muscular atrophies
and hereditary neuropathies. This
means that most neuromuscular condi-
tions can now be diagnosed by molec-
ular testing. Examples include spinal
muscular atrophy which can now be
confirmed by polymerase chain reac-
tion (PCR) testing for a deletion of the
survivor motor neuron (SMN) gene
and congenital myotonic dystrophy
which can be diagnosed by demon-
strating an expansion of cytosine
thymine guanine (CTG) triplet repeats.
DNA Xp21 deletion testing (PCR
assays) can confirm the diagnosis in
65% of males with Duchenne muscular
dystrophy and 80% of males with
Becker’s muscular dystrophy. Only in
the remaining cases is muscle biopsy
still advocated. Muscle enzymes levels
(creatine kinase assay) are rarely help-
ful in the floppy infant, with the excep-
tion of muscle disorders where crea-
tine kinase values are elevated, such
as congenital muscular dystrophies
and in some of the congenital structur-
al myopathies.
Electromyography (EMG) should not
be performed in isolation. It does not
allow for a definitive diagnosis as
there are virtually no waveforms that
are pathognomonic for specific dis-
ease entities. In the floppy child, EMG
is indispensable in deciding whether
there is true weakness due to neuro-
muscular disease, or merely hypotonic-
ity from causes in other systems or
other parts of the nervous system. The
abnormalities detected may then assist
in localizing the disease process to the
neuron, neuromuscular junction or
muscle. EMG is also useful to confirm
a clinical suspicion of myotonia in the
older child.
Nerve conduction studies are useful in
the investigation of hereditary motor
sensory neuropathies and distinguish-
ing axonal from demyelinating disor-
ders. Molecular DNA testing can then
be used for specific demyelinating dis-
orders. Commercial testing is not yet
available for most axonal forms of
hereditary neuropathies.
Muscle biopsy remains the investiga-
tion of choice in an infant with a sus-
Fig. 7. A 1-year-old girl with Prader-
Willi syndrome. Marked hypotonia
and feeding difficulties were evident
during the first few months of her life.
THE FLOPPY CHILD
454 CME August 2004 Vol.22 No.8
pected congenital structural myopathy,
as none of the clinical features are
truly pathognomonic. Even a CK with-
in the reference range and normal
EMG does not exclude the presence of
a myopathy. Muscle biopsy is also
indicated in infants with suspected
limb-girdle muscular dystrophies
(LGMD).
The term ‘benign essential hypotonia’
or ‘hypotonia with favourable outcome’
should be used with caution since
newer investigative techniques have
resulted in most previously labelled
cases being classified into specific disor-
ders. There are however many benign
congenital hypotonia cases that remain
unclassified, even with detailed exami-
nation of the muscles. Patients labelled
as ‘hypotonia with favourable outcome’
should fulfil all of the following criteria1
:
• early hypotonia, usually since birth
• active movements of limbs and nor-
mal tendon reflexes
• normal or mild motor retardation that
improves later on
• normal muscle enzymes, EMG,
motor nerve conduction studies
(MNCS) and histology.
PRINCIPLES OF
MANAGEMENT
Regular physiotherapy will prevent con-
tractures. Occupational therapy is
important in facilitating activities of
daily living. Vigorous treatment of respi-
ratory infections is indicated. Annual flu
vaccination is necessary. Annual
orthopaedic review is required to moni-
tor for scoliosis and to exclude hip dislo-
cation/subluxation.
Feeding intervention by nasogastric tube
or gastrostomy will benefit the under-
nourished child. Maintenance of ideal
weight is important, as excessive weight
gain will exacerbate existing weakness.
Children with neuromuscular disorders
deserve special attention when it comes
to anaesthesia. The anaesthetist should
be forewarned about the possibility of
an underlying muscle disease even if the
child has very mild or non-existing
symptoms. A family history of muscle
disease or mild hyper-CK-aemia may be
of importance. Muscle relaxants should
only be used if essential because of
their more profound and prolonged
effect in myopathic children. All children
with
neuromuscular disease should also be
considered potentially susceptible to
malignant hypothermia (the strongest
correlation is with central core disease)
and implicating agents should therefore
be avoided.
Ethical considerations such as the
appropriateness of cardiopulmonary
resuscitation in the event of cardiac
arrest or acute respiratory failure need
to be addressed sensitively.
References available on request.
When evaluating a floppy infant,
the first goal should be to distin-
guish whether the disorder is cen-
tral or peripheral in origin.
Hypotonia with weakness suggests
a lower motor neuron lesion, where-
as weakness is uncommon in disor-
ders affecting the upper motor neu-
ron except during the acute stage.
Evaluation of tone and power
should be delayed in the unwell,
nutritionally compromised child.
Muscle enzymes are rarely helpful
in the floppy child, with the excep-
tion of the congenital muscular dys-
trophies and some of the structural
congenital myopathies.
EMG does not allow a definitive
diagnosis but is indispensable in
deciding whether there is weakness
due to neuromuscular disease, or
merely hypotonia from causes in
other systems or parts of the nerv-
ous system.
The most common of the neuromus-
cular disorders, spinal muscular
atrophy (SMA), is now diagnosable
by molecular genetic analysis
(PCR).
Where clinical evaluation suggests
complex multisystem involvement
(i.e. hypotonia plus) inborn errors
of metabolism should be excluded.
Children with neuromuscular disor-
ders deserve special attention when
it comes to anaesthesia.
The term ‘benign essential hypoto-
nia’ or ‘hypotonia with a
favourable outcome’ should be used
with caution and only after compli-
ance with strict diagnostic criteria.
IN A NUTSHELL
The onset of the hypotonia
is also important as it may
distinguish between
congenital and aquired
aetiologies.
There are two approaches
to the diagnostic problem.
The first is based on identi-
fying the neuro-anatomical
site of the lesion or insult.
The second is to determine
whether or not the hypoto-
nia is accompanied by
weakness.
Children with neuromuscu-
lar disorders deserve spe-
cial attention when it
comes to anaesthesia.
THE FLOPPY CHILD
August 2004 Vol.22 No.8 CME 455

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Approach to hypotonia

  • 1. R van Toorn MB ChB, (Stell) MRCP (Lond), FCP (SA) Specialist Department of Paediatrics and Child Health Faculty of Health Sciences Stellenbosch University and Tygerberg Children’s Hospital Ronald van Toorn obtained his medical degree from the University of Stellenbosch, and completed his paediatric specialist training at both Red Cross Children’s Hospital in Cape Town and the Royal College of Paediatricians in London. One of his interests is in the field of neuromus- cular medicine. His working experience includes the neuromuscular clinics attached to Birmingham Children’s, Red Cross Children’s, Guy’s and St Thomas’ hospitals. CLINICAL APPROACH TO THE FLOPPY CHILD The floppy infant syndrome is a well-recognised entity for paediatricians and neonatologists and refers to an infant with generalised hypotonia presenting at birth or in early life. An organised approach is essential when evaluating a floppy infant, as the causes are numerous. A detailed history combined with a full systemic and neurological examination are critical to allow for accurate and precise diagnosis. Diagnosis at an early stage is without a doubt in the child’s best interest. HISTORY The pre-, peri- and postnatal history is important. Enquire about the quality and quantity of fetal movements, breech presentation and the presence of either poly- or oligohydramnios. The incidence of breech presentation is higher in fetuses with neuromuscular disorders as turning requires adequate fetal mobility. Documentation of birth trauma, birth anoxia, delivery complications, low cord pH and Apgar scores are crucial as hypoxic-ischaemic encephalopathy remains an important cause of neonatal hypotonia. Neonatal seizures and an encephalo- pathic state offer further proof that the hypotonia is of central origin. The onset of the hypotonia is also important as it may distinguish between congenital and aquired aetiologies. Enquire about consanguinity and identify other affected fam- ily members in order to reach a definitive diagnosis, using a detailed family pedigree to assist future genetic counselling. CLINICAL CLUES ON NEUROLOGICAL EXAMINATION There are two approaches to the diagnostic problem. The first is based on identi- fying the neuro-anatomical site of the lesion or insult. The second is to determine whether or not the hypotonia is accompanied by weakness. Careful neurological examination should, in most cases, localise the site of the lesion to the upper motor neuron (UMN) or lower motor neuron (LMN) unit. Useful clues are listed in Fig. 1. Next assess whether the hypotonia is accompanied by weakness. Weakness is uncommon in UMN hypotonia except in the acute stages. Hypotonia with pro- found weakness therefore suggests involvement of the LMN. Assessment of muscle power of infants is generally limited to inspection. Useful indicators of weakness are: • Ability to cough and clear airway secretions (‘cough test’). Apply pressure to the trachea and wait for a single cough that clears secretions. If more than one cough is needed to clear secretions, this is indicative of weakness.2 • Poor swallowing ability as indicated by drooling and oropharyngeal pooling of secretions. • The character of the cry — infants with consistent respiratory weakness have a weak cry. • Paradoxical breathing pattern — intercostal muscles paralysed with intact diaphragm. THE FLOPPY CHILD August 2004 Vol.22 No.8 CME 449
  • 2. • Frog-like posture and quality of spontaneous movements — poor spontaneous movements and the frog-like posture are characteristic of LMN conditions. Further confirmation of the last indica- tor can be obtained by means of infor- mal neurological examination in the test positions. Excessive head lag will be evident on ‘pull to sit’. Minimal support with a sensation of ‘slipping through he hands’ during vertical sus- pension testing and inverted U posi- tion on ventral suspension are further indicators (Fig. 2.1 and 2.2).3 Floppy strong Increased tendon reflexes Extensor plantar response Sustained ankle clonus Global developmental delay Microcephaly or suboptimal head growth Obtundation convulsions Axial weakness a significant feature Upper motor neuron disorder Central hypotonia Lower motor neuron disorder Peripheral hypotonia Creatine kinase assay EMG Nerve conduction studies Genetic studies Karotyping FISH methylation studies VLCFA Triosomy 21 Prader-Willi syndrome Zellweger syndrome Hypoxic ischaemic encephalopathy Cerabral malformations Congenital structural myopathies Spinal muscuar dystrophy Congenital myotonic dystrophy Congenital muscular dystrophies CT/MRI DNA-based mutation analysis if available Muscle or nerve biopsy Floppy weak Hypo- to areflexia Selective motor delay Normal head circumference and growth Preserved social interaction Weakness of antigravitational limb muscles Low pitched weak cry Tongue fasciculations Paradoxical chest wall movement Fig. 1. Clinical clues on neurological examination (EMG = electromyogram: CT= computed tomograph; MRI = magnetic resonance imaging; VLCFA = very long-chain fatty acids; FISH = fluorescent in situ hybridisation) THE FLOPPY CHILD 450 CME August 2004 Vol.22 No.8
  • 3. A distinct pattern of weakness may favour certain aetiologies: • Axial weakness is a significant fea- ture in central hypotonia. • Generalised weakness with sparing of the diaphragm, facial muscles, pelvis and sphincters suggests ante- rior horn cell involvement. • With myasthenic syndromes, the bulbar and oculomotor muscles exhibit a greater degree of involve- ment. • Progressive proximal symmetrical weakness suggests a dystro- phinopathy. Signs of proximal weakness in the older infant include a lordotic posture, Trendelenburg gait and Gower sign. • A striking distribution of weakness of the face, upper arms and shoul- ders suggests fascioscapulohumeral muscular dystrophy. • Distal muscle groups are predomi- nantly affected with peripheral neu- ropathies. Signs suggesting distal weakness in an older infant would include weakness of hand grip, foot drop and a high stepping, slapping gait. THE FLOPPY WEAK INFANT Table I gives a comprehensive approach to the clinical clues and investigations for the more common phenotypes of the weak floppy infant. Once the lesion has been localised to the LMN proceed with further neu- roanatomical localisation according to the compartments of the LMN. The compartments and disease associa- tions are listed in Fig. 3. Examine the tongue for size and fasci- culations. Fasciculations, irregular twitching movements, generally indi- cate an abnormality of the anterior horn cells (Fig. 4). Do not examine the tongue while the infant is crying. The co-existence of atrophy would strongly favour a denervative aetiology. An ECG may be helpful in demonstrating baseline fasciculations of the inter- costal muscles (Fig 5). Enlargement of the tongue may suggest a storage dis- order such as Pompe’s disease. The presence of a facial diplegia (myopathic facies) suggests either a congenital structural myopathy or myasthenia gravis. Respiratory and bulbar weakness can accompany both conditions. Fluctuation in strength would favour myasthenic syndromes (Fig. 6). Where clinical evaluation suggests complex multisystem involvement (i.e. hypotonia plus) inborn errors of metabolism should be excluded. Referral to a tertiary centre for meta- bolic investigations would then be indicated. THE FLOPPY STRONG CHILD The presence of facial dysmorphism should alert the doctor to the possibili- ty of an underlying syndrome or genet- Fig. 2.1. A 12-week-old male infant with excessive headlag evident on ‘pull-to-sit’. Note the hypotonic posture of the legs with external rotation. Fig. 2.2. The same infant in horizontal suspension. Note the inverted U posture. Fig. 4. Tongue fasciculations in a child with spinal muscular atrophy. The com- bination of fasciculations with atrophy is strongly indicative of muscle dener- vation. Fig. 5. ECG of a floppy infant with spinal muscular atrophy demonstrating base- line fasciculations arising from the underlying intercostal muscles. Fig. 6. Ptosis and external ophthalmo- plegia in a floppy weak child sugges- tive of myasthenia gravis. THE FLOPPY CHILD August 2004 Vol.22 No.8 CME 451
  • 4. Nerve fibre: neuropathies (Demyelinating or axonal) Acquired: Guillain-Barré syndrome Infectious: diphtheria, syphilis, coxsackie, HIV Toxic: drugs, heavy metals Nutritional: Vit B1, B6, B12, E, folate Endocrine: Diabetes, uraemia Metabolic neurodegenerative causes Hereditary: Charcot-Marie-Tooth disease Muscle Dystrophinopathies (lack of specific muscle protein): Duchenne, Becker’s fascioscapular humeral, limb gir- dle and congenital muscular dystrophies Congenital myopathies (abnormal muscle structure) Muscle membrane disorders: congenital myotonias, congenital myotonic dystrophies Inflammatory myopathies: dermatomyositis, poliomyositis Metabolic myopathies: lipid glycogen storage dis- eases Endocrine myopathies: hypothyroidism Energy depletion within muscle: mitochondrial, free- fatty acid oxidatation and carnitine disorders Anterior horn cell: Spinal muscular atrophy Poliomyelitis Neuromuscular junction Myasthenia gravis Botulism Fig. 3. LMN comportments and disease associations. THE FLOPPY CHILD 452 CME August 2004 Vol.22 No.8
  • 5. Table I. Clincical clues and investigations of the more common phenotypes of the floppy weak infant Condition Clinical clues Investigations Spinal cord transection or Haemangioma or tuft of hair in midline MRI spinal cord disease Scoliosis Syringomyelia or other forms Evidence of bladder or bowel dysfunction of spinal dysraphism Mixed deep tendon reflexes with absent abdominal and anal reflexes Spinal muscular atrophy Tongue atrophy and fasciculations ECG: Baseline fasciculations Paradoxical breathing pattern Deletion of the survival motor Severe proximal muscle weakness with neuron (SMN) gene by PCR absent tendon reflexes testing Preserved social interaction Peripheral neuropathy Weakness predominantly distal Motor nerve conduction In most cases absent deep tendon reflexes studies Pes cavus Sural nerve biopsy Molecular DNA testing is available for specific demyelinating disorders Myasthenia gravis Greater involvement of oculomotor and Response to acethylcholine bulbar muscles esterase inhibitors True congenital myasthenia due to receptor Single-fibre EMG defects is rare Serum antibodies to Exclude transient neonatal form from acethylcholine receptors maternal history Electrodiagnostic studies not universally positive in young patients Infantile botulism Acute onset descending weakness, Isolation of organism from cranial neuropathies, ptosis, stool culture unreactive pupils, dysphagia, Presence of toxin in the stool constipation Congenital muscular Hypotonia, weakness and contractures Creatine kinase usually dystrophy at birth elevated Associated brain and eye problems Brain MRI for structural and white matter abnormalities Muscle biopsy: merosin stain Congenital myotonic Polyhydramnios with reduced fetal Molecular DNA testing by dystrophy movements determining number of CTG Inverted V-appearance of the mouth repeats (normal range 5 - 39 Examination of mother’s face shows inability repeats) to bury her eyelashes and grip myotonia EMG of the mother Premature cataract surgery in the mother Congenital structural Slender stature CK and EMG usually not myopathy Hypotonia with feeding problems at birth helpful Weakness that is often non-progressive Muscle biopsy is critical for Nemaline myopathy: often associated with definitive diagnosis. feeding problems ECG when nemaline and Central core: most often associated with desmin myopathies are malignant hyperthermia suspected Myotubular myopathy: Ptosis and The genetic basis for several extraocular palsies consistent of the congenital myopathies clinical features has now been determined Glycogen storage disease Enlarged heart in a very floppy weak Blood smear vacuolated Pompe’s disease newborn lymphocytes Unexplained cardiac failure Urine oligosaccharides Tongue may appear large Typical ECG and ECHO changes Acid maltase assay in cultured fibroblasts Muscle biopsy usually not necessary THE FLOPPY CHILD August 2004 Vol.22 No.8 CME 453
  • 6. ic disorder. Conditions that need to be excluded include trisomy 21, Prader- Willi and Zellweger syndrome. At birth the facial anomalies in Prader- Willi syndrome are often insignificant and the diagnosis is usually only established after onset of obesity. Useful early markers include the pres- ence of feeding difficulties, small hands and feet, almond shaped eyes, narrow bifrontal diameter and hypogo- nadism (Fig. 7). Failure to identify electrophysiological abnormalities in a neonate with profound hypotonia should prompt testing for Prader-Willi syndrome. This can be done by a DNA methylation study which will detect 99% of cases. Zellweger syndrome presents in the newborn with typical facial dysmor- phism including high forehead, wide patent fontanelles and sutures, shallow orbital ridges, epicanthus and microg- nathia. Neurological manifestations are dominated by severe hypotonia with depressed or absent tendon reflexes, and poor sucking and swal- lowing. Hepatomegaly and liver dys- function are consistent findings. VALUE AND CHOICE OF DIAGNOSTIC MODALITIES Special investigations should be guid- ed by clinical findings. Evaluation of tone and power should be delayed in the systemically unwell nutritionally compromised child. Infective and bio- chemical parameters should first be normalised before attempts are made to examine tone and power. Hypokalaemia and hypophospha- taemia in particular will cause reversible weakness. Serum albumin, calcium, phosphorus, alkaline phos- phatase and thyroxine levels will pro- vide confirmation of clinical suspicion in malnutrition, ricketts and hypothy- roidism. SUSPECTED CENTRAL CAUSE For infants with central hypotonia, ini- tial investigations include karyotype and neuroimaging (CT or MRI scan). A karyotype is a must in the dysmorphic hypotonic child. This can be combined with FISH testing if Prader-Willi syn- drome is suspected. Cranial MRI will identify patients with structural CNS malformations, neuronal migration defects and those with white matter changes (congenital muscular dystro- phies in particular). Hypotonia may also be prominent in connective tissue diseases such as Ehlers Danlos or Marfan’s syndrome. An excessive range of joint mobility, unusual joint postures, the ability to do various con- tortions of the limbs and/or hyperelas- ticity of the skin are important diag- nostic clues. Although metabolic disor- ders are well recognised as the cause for central hypotonia, because of the rarity of the conditions, the diagnostic yield is low. Very long-chain fatty acids (VLCFA) testing should be per- formed if a peroxisomal disorder such as Zellweger is suspected. SUSPECTED PERIPHERAL CAUSE Major discoveries have been made in the genetic analysis of the muscular dystrophies, spinal muscular atrophies and hereditary neuropathies. This means that most neuromuscular condi- tions can now be diagnosed by molec- ular testing. Examples include spinal muscular atrophy which can now be confirmed by polymerase chain reac- tion (PCR) testing for a deletion of the survivor motor neuron (SMN) gene and congenital myotonic dystrophy which can be diagnosed by demon- strating an expansion of cytosine thymine guanine (CTG) triplet repeats. DNA Xp21 deletion testing (PCR assays) can confirm the diagnosis in 65% of males with Duchenne muscular dystrophy and 80% of males with Becker’s muscular dystrophy. Only in the remaining cases is muscle biopsy still advocated. Muscle enzymes levels (creatine kinase assay) are rarely help- ful in the floppy infant, with the excep- tion of muscle disorders where crea- tine kinase values are elevated, such as congenital muscular dystrophies and in some of the congenital structur- al myopathies. Electromyography (EMG) should not be performed in isolation. It does not allow for a definitive diagnosis as there are virtually no waveforms that are pathognomonic for specific dis- ease entities. In the floppy child, EMG is indispensable in deciding whether there is true weakness due to neuro- muscular disease, or merely hypotonic- ity from causes in other systems or other parts of the nervous system. The abnormalities detected may then assist in localizing the disease process to the neuron, neuromuscular junction or muscle. EMG is also useful to confirm a clinical suspicion of myotonia in the older child. Nerve conduction studies are useful in the investigation of hereditary motor sensory neuropathies and distinguish- ing axonal from demyelinating disor- ders. Molecular DNA testing can then be used for specific demyelinating dis- orders. Commercial testing is not yet available for most axonal forms of hereditary neuropathies. Muscle biopsy remains the investiga- tion of choice in an infant with a sus- Fig. 7. A 1-year-old girl with Prader- Willi syndrome. Marked hypotonia and feeding difficulties were evident during the first few months of her life. THE FLOPPY CHILD 454 CME August 2004 Vol.22 No.8
  • 7. pected congenital structural myopathy, as none of the clinical features are truly pathognomonic. Even a CK with- in the reference range and normal EMG does not exclude the presence of a myopathy. Muscle biopsy is also indicated in infants with suspected limb-girdle muscular dystrophies (LGMD). The term ‘benign essential hypotonia’ or ‘hypotonia with favourable outcome’ should be used with caution since newer investigative techniques have resulted in most previously labelled cases being classified into specific disor- ders. There are however many benign congenital hypotonia cases that remain unclassified, even with detailed exami- nation of the muscles. Patients labelled as ‘hypotonia with favourable outcome’ should fulfil all of the following criteria1 : • early hypotonia, usually since birth • active movements of limbs and nor- mal tendon reflexes • normal or mild motor retardation that improves later on • normal muscle enzymes, EMG, motor nerve conduction studies (MNCS) and histology. PRINCIPLES OF MANAGEMENT Regular physiotherapy will prevent con- tractures. Occupational therapy is important in facilitating activities of daily living. Vigorous treatment of respi- ratory infections is indicated. Annual flu vaccination is necessary. Annual orthopaedic review is required to moni- tor for scoliosis and to exclude hip dislo- cation/subluxation. Feeding intervention by nasogastric tube or gastrostomy will benefit the under- nourished child. Maintenance of ideal weight is important, as excessive weight gain will exacerbate existing weakness. Children with neuromuscular disorders deserve special attention when it comes to anaesthesia. The anaesthetist should be forewarned about the possibility of an underlying muscle disease even if the child has very mild or non-existing symptoms. A family history of muscle disease or mild hyper-CK-aemia may be of importance. Muscle relaxants should only be used if essential because of their more profound and prolonged effect in myopathic children. All children with neuromuscular disease should also be considered potentially susceptible to malignant hypothermia (the strongest correlation is with central core disease) and implicating agents should therefore be avoided. Ethical considerations such as the appropriateness of cardiopulmonary resuscitation in the event of cardiac arrest or acute respiratory failure need to be addressed sensitively. References available on request. When evaluating a floppy infant, the first goal should be to distin- guish whether the disorder is cen- tral or peripheral in origin. Hypotonia with weakness suggests a lower motor neuron lesion, where- as weakness is uncommon in disor- ders affecting the upper motor neu- ron except during the acute stage. Evaluation of tone and power should be delayed in the unwell, nutritionally compromised child. Muscle enzymes are rarely helpful in the floppy child, with the excep- tion of the congenital muscular dys- trophies and some of the structural congenital myopathies. EMG does not allow a definitive diagnosis but is indispensable in deciding whether there is weakness due to neuromuscular disease, or merely hypotonia from causes in other systems or parts of the nerv- ous system. The most common of the neuromus- cular disorders, spinal muscular atrophy (SMA), is now diagnosable by molecular genetic analysis (PCR). Where clinical evaluation suggests complex multisystem involvement (i.e. hypotonia plus) inborn errors of metabolism should be excluded. Children with neuromuscular disor- ders deserve special attention when it comes to anaesthesia. The term ‘benign essential hypoto- nia’ or ‘hypotonia with a favourable outcome’ should be used with caution and only after compli- ance with strict diagnostic criteria. IN A NUTSHELL The onset of the hypotonia is also important as it may distinguish between congenital and aquired aetiologies. There are two approaches to the diagnostic problem. The first is based on identi- fying the neuro-anatomical site of the lesion or insult. The second is to determine whether or not the hypoto- nia is accompanied by weakness. Children with neuromuscu- lar disorders deserve spe- cial attention when it comes to anaesthesia. THE FLOPPY CHILD August 2004 Vol.22 No.8 CME 455