SEPTEMBER, 1970 P H Y S I O T H E R A P Y Page 7

maximum independence and in a London Unit those not 
on home dialysis training programmes, had leg shunts and 
were encouraged to put themselves on the machine after 
having assembled their own machines. The following 
morning they stripped and cleaned their machines.

Muscle Power
D ecrease in  m uscle p o w e r m id o rth o p a e d ic  type c o m p li­

c ations were seen in su c h  m u ltitu d e  th a t I  b e g a n  to  w on d er 
w hether tra n s p la n ta tio n  w as in a n y  w ay ju stifia b le , especially 
a fte r seeing such fit and h e alth y  p a tie n ts in o n e  London 
Dialysis U nit.

Surely the answer to transplantation cannot merely be 
good and/or adequate renal function but an active normal 
human being. If muscule power, especially around the 
weight-bearing joints can be hypertrophied, can one not 
hope to prolong the use of that joint ? The intense and vigor­
ous rehabilitation while the patient is awaiting transplanta­
tion should aim at achieving as “normal” a person as 
possible, making the actual transplant a much less formidable 
procedure.

This was, to some extent, confirmed in a London Unit 
where similar vigorous and comprehensive rehabilitation 
programmes existed and where these devastating results 
did not present themselves.

The fact that i have harped on the American hospitals 
more than elsewhere is partly due to the fact that 1 spent 
46 days in Canada and the U.S.A., four in France, 20 in 
the U.K., and three in Johannesburg. Furthermore, the 
standard of physiotherapy — I repeat prophylactic respira­
tory physiotherapy — in the U.S.A. is something one has 
to see to believe. It was for this reason that I ended my 
travels in the U.K. in the hopes of learning. I must stress 
that I did not visit rehabilitation units, which would have 
had much valuable material to offer as this is their forte, 
but 1 was sent to visit Transplant, Cardio thoracic and 
Intensive Care Units only. The U.K. in itself was somewhat 
disappointing. I went eager to learn a great deal and to 
come back with lots of new ideas. Here the standard of 
physiotherapy was high, but there was little or no progress 
since my post-graduate scholarship visit of three months 
in 1965. At some places more cardiac surgery was being 
done, but the physiotherapy was routine and unchanged. 
In fact I felt we could teach quite a lot.

Research in transplantation from the physiotherapeutic 
aspect is vast. The long term effects of exercise on muscle 
power, bone and joint involvement and high doses of 
steroids is an unexplored one and theories alone are not 
acceptable. It is sad that our programme at Groote Schuur 
is so small and so slow moving as to get conclusive results 
one requires greater numbers and over a lengthier time 
period than our present results range.

SUMMARY

observations, findings and recommendations relating 
n  c a j  Cardiac Units and Transplant Units in the 
f .L a U.K. have been discussed with special reference 
to the prophylactic aspect o f physiotherapy.

ni , n t att® P t  has been made to demonstrate the great 
need tor this type of physiotherapy in the U.S.A.

J l C° nuClusion m y  s i n .c e r e  thanks are due to John Acker- 
him p  r necessary driving force behind the whole trip, to 
n™’c,™fe,ss° r L - Ea'es- Dr. G. Thatcher, D r. J. Terblariche, 
dnrtinn. ?  ? ? nders and Dr. T. O’Donovan for the intro- 
ProvinrLi0 *!le Yarl0Us. heads o f units I visited, to the Cape 
trin , “ministration for the realisation o f this study
Groote rr J ' P -  Burger» Medical Superintendent,

Schuur Hospital for permission to publish.

The Use of Muscle 

Stimulation for Peripheral 

Nerve Lesions
by

E. J. WOOD, B.Sc. (Physio.) C.T.P., 
Lecturer in Physiotherapy, 

University of Cape Town

The use of electrical stimulation has been the subject of 
much controversy over the years and this paper represents 
a review of the available literature to date. However, before 
discussing the value o f this treatment, a revision of the struc­
ture o f a peripheral nerve trunk and the changes associated 
with a  lesion may be o f benefit to those concerned with the 
problem.

THE PERIPHERAL NERVE TRUNK 
The structures forming the nerve trunk are:

1. Nerve fibres; 2. Connective tissue;
3. Nervi nervorum; 4. Blood vessels and lymphatics.

1. Nerve Fibres

The neurone is the basic structural and functional unit of 
the nervous system and its structural division into cell body 
dendrites and axon is well known. The axons forming the 
trunk are myelinated with .the myelin forming segments. 
Around these segments the cytoplasm of the Schwann cells 
form a sheath, with one nucleus to a segment, and the whole 
is enclosed in a connective tissue sheath, the endoneurium. 
Where the cytoplasm of the Schwann cell dips in towards 
the axon at the end o f each myelin segment the notch so 
formed is called the Node of Ranvier.

Functionally the fibres within the nerve trunk are repre­
sentative of both motor and sensory systems, including the 
Autonomic system.

2. Connective Tissue

The part played by the connective tissue components of 
nerve trunks in relation both to injury and recovery of 
function is often not fully appreciated.

Endoneurium: Composed mainly of collagen fibres this 
sheath surrounding the axon both protects the fibre and is 
responsible for maintaining the intracellular pressure of the 
axon.

Perineurium: Bundles o f fibres are enclosed by this con­
nective tissue wrapping, the whole being named a funiculus. 
The perineurium contains both elastic and collagen fibres 
which are arranged in oblique, circular and longitudinal 
layers around the bundles o f fibres. These funiculi engage 
in repeated divisions and re-uniting along the length of the 
nerve so that the cross-sectional pattern o f the nerve trunk 
varies as does the amount o f perineurium present at any 
one place. Where there are many small funiculi and there­
fore more perineurium, the nerve trunk is strongest. This 
arrangement tends to occour where nerves cross joints and 
are subject to stretch. It is also o f interest to note that the 
lateral popliteal nerve contains very much fewer funiculi 
than the medial popliteal nerve in the region of the knee 
joint. This factor may well account for the greater propor­
tion of lateral popliteal nerve lesions following traction 
injuries in this area.

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Where no perineurium exists, as at the nerve roots, the 
fibres are more vulnerable to traction injury; this often 
occurs with brachial plexus lesions.

The perineurium acts in protecting the nerve fibre and 
maintaining the intrafunicular pressure in much the same 
way as the endoneurium. In addition, because of its strength, 
it is largely responsible for maintaining the integrity of the 
nerve trunk as a whole under stretch. If sufficient of the 
funiculi are stretched beyond the elastic limit o f the peri­
neurium the whole nerve tends to elongate rapidly.

Epineurium: The funiculi are embedded in an amount of 
loose areolar tissue with an enclosing sheath at the periphery. 
This sheath, the epineurium, separates the nerve trunk from 
the surrounding structures and allows a degree of mobility 
o f the nerve along its course. Branches given off along the 
length of the nerve tend to anchor it as do blood vessels 
concerned with supplying its structures.

Although capable of stretching and therefore protective 
to the funiculi, it is not as strong as the perineurium and 
serves more to cushion the bundles of fibres within it and 
protect them from compression. A nerve is therefore less 
liable to damage from compression where there are a 
number of small funiculi embedded in a large amount of 
epineurium.

3. Nervi Nervorum
Small branches from the nerve supply the connective 

tissue and form perivascular plexuses. They contain sympa­
thetic and sensory fibres.

4. Blood Vessels and Lymphatics
These provide nutrition for the connective tissues and 

the axon along the length of the nerve. The vessels arise 
from arteries in the vicinity and are concerned with supply­
ing both the connective tissues and the axon, although its 
survival and ability to function fully depends on the integ­
rity of the cell body.

Damage to a Peripheral Nerve Trunk
This may occur in a number o f ways.
Stretch: The strength of the perineurium is the prime 

factor in protecting a nerve trunk against damage due to 
stretch. Once the elastic limit of this structure has been 
reached it does not immediately break but elongates rapidly, 
rather like chewing gum. However, the endoneurium, being 
not as strong, gives before the perineurium' and the axon 
is disrupted first. Continued stretch will progressively rupture 
the various connective tissue layers until finally the entire 
trunk is torn apart.

A compression factor also exists with stretching a nerve 
as the diameter decreases. Another problem is that lesions 
may be spread along the length of the nerve and not neces­
sarily be confined to one area as the fibres will give where 
they are weakest.

Compression: Mechanical pressure will interfere with 
function by both disrupting the molecular organisation of 
the axon as well as causing ischaemia by pressure on the 
blood supply.

Friction: Here stretch or compression factors may operate 
where a nerve is stretched over callus or some other obstruc­
tion, or protective fibrosis may cause compression.

Ischaemia: Other than local compression mentioned above, 
interference with the main vascular supply to the area may 
cause nerve damage. Volkmann’s Ischaemia is usually due 
to damage to the median nerve in this way.

Classification o f Nerve Damage
The three well-known headings usually used to classify 

nerve damage, i.e. neurapraxia, axonotmesis and neurot­

mesis, fail to account adequately for the different degrees 
of connective tissue damage which occurs and which affect 
the prognosis. Sunderland1 has tabulated five degrees of 
damage which more fully cover the field.

1st Degree (Neurapraxia) This is the well-known con­
duction block with disorganisation of the molecular structure 
of the axon only. The integrity o f the axoplasm remains 
intact and this lesion is fully reversible. The length of time 
taken for recovery depends on the severity o f the deforming 
force and may take anything from a few minutes to two to 
three months; recovery o f muscle function does not neces­
sarily follow a distributional pattern.

2nd Degree (Axonotmesis): Here again the pattern is 
familiar, with disintegration o f the axon at the site o f the 
lesion, distal to the lesion and for a short distance proxi- 
mally; the cell body also undergoes changes in structure. 
Wallerian degeneration occurs, with the nerve retaining its 
ability to conduct for 48-72 hours after which this function 
diminishes until after anything from 14-28 days the axo­
plasm has been completely removed. The endoneurium 
shrinks as the intracellular pressure is not present but the 
tissue remains intact. |

Recovery depends on the cell body remaining intact and 
the length of time is variable. The structure o f the cell body 
must first return to norm al; the axoplasm must grow down 
the endoneurial tube, grow across the site o f the lesion and 
distally to the end-plate. As the return to full function 
depends on the return o f the nerve fibre to its former dia­
meter recovery must not be so delayed as to cause the endo­
neurial tube to thicken with fibrous tissue as well as shrink; 
the former irreversibly reduces the lumen and impairs 
function of the fibre. With the endoneurium intact in 2nd 
degree injuries recovery is usually uncomplicated and once 
the former end-organ relationship has been established 
function is possible. The pattern of functional recovery will 
be distributional, i.e. it will occur in the order of nerve 
supply from proximal to distal.

3rd Degree (Neurotmesis): Damage has been sufficient to 
not only disrupt the axon but the endoneurium as well. 
The perineurium is intact but the fibres within the funiculi 
are disorganised. Recovery is delayed and may be incom­
plete. A new factor is involved in the crossing of the site 
of the lesion by the regenerating axon. The axoplasm may 
not necessarily grow down its former endoneurial tube or 
for that matter any endoneurial tube, and normal end- 
organ relationships may not be restored. If the time factor 
is long enough the endoneurial tube may no longer be 
capable o f expanding to its former diameter as explained 
previously; changes in the end-organs themselves due to 
prolonged denervation may be such as to preclude recovery 
and function will depend on sufficient number of fibres 
returning to normal.

4th Degree: This degree of injury damages the peri­
neurium with subsequent disruption o f the funiculi. Func­
tional recovery is incomplete and delayed due to the amount 
of connective tissue damage and the difficulties involved 
when the axoplasm has to bridge the site of the lesion ; not 
only are the endoneurial tubes disorganised but the guiding 
perineurium is not present to maintain the integrity of the 
funiculi.

5th Degree: Disruption of the epineurium and therefore 
loss of continuity of the entire nerve trunk is the feature of 
this stage of damage. Recovery depends on suturing the 
nerve ends and is never complete.

With these last two degrees of injury changes in the 
structures supplied by the nerve may be such that even with 
regeneration of the axon, functional recovery is not possible. 
Time for recovery to occur plays a large part in determining 
these changes and a brief discussion is necessary here before 
reviewing the possibilities of benefit by electrical stimulation 
to the denervated muscle.

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SEPTEMBER, 1970 p h y s i o t h e r a p y Page 9

Changes in Structures Deprived of their Nerve Supply
Loss of voluntary muscle power and cutaneous sensation 

are the most obvious presenting changes following de­
nervation. It must be remembered that joints and soft 
tissues will have lost their sensory supply and be more 
susceptible to trauma; vaso-motor disturbances occur 
following loss of sympathetic control of blood vessels; 
abnormal sensation will also be experienced with recovering 
or progressing lesions; disturbances of conduction, and 
false localisation due to misrepresentation in the cortex 
after wrong regeneration of an axon to an end-organ. ■

Changes in Muscle
Loss of voluntary movement, which may be complete 

paralysis or partial paresis of the muscle or muscles supplied 
by the nerve follows a lesion to a peripheral nerve trunk.

The muscle first shows a reduction in size and weight 
and a change in colour. This atrophy proceeds rapidly for 
the first 60 days, 70 per cent of the original muscle bulk 
having diminished in this time. The rate of atrophy then 
slows down and reaches a more or less constant level at 
120 days when there has been 80 per cent to 90 per cent 
reduction in size.2- “■4- 5

It has been shown experimentally6’ 7 that 18 months to 
three years after denervation, muscle fibre, although atro­
phied, had not lost its ability to contract. In addition the 
end-plates have been observed to remain intact for periods 
up to 17 months.8

Changes in the connective tissues also occur, this tissue 
following the same pattern in muscle as in nerve, with 
individual fibres enclosed in endomysium, bundles of fibres 
(fasiculi) in perimysium and then the whole ensheathed in 
epimysium. Following denervation the connective tissue 
proliferates, the perimysium first and then the endomysium. 
This proliferation appears from the second month onwards 
and progresses for varying periods, finally reaching a steady 
state where the muscle fibres are separated by the thickened 
connective tissue but retain their own characteristic histo­
logical appearance and fasicular pattern within the muscle. 
Ultimately the muscle cell itself fragments, thins or swells 
and disintegrates, the muscle unit being replaced by fat 
and fibrous tissue.

Many of these findings have been experimentally induced 
in animals, but studies on human muscle show a close 
correlation.

Bowden and Gutmann9 showed vascular changes in 
human muscle as well with obliteration of arteries and capil­
laries after 12 months’ denervation.

Time is once more an element which emerges in the 
consideration of nerve lesions. If the axon regenerates 
within the period, while the muscle fibre remains intact 
return of function is possible, and this has been shown to 
sometimes last as long as three years. However, other 
factors operate to jeopardise the survival of the muscle 
fibre and cause its degeneration and replacement by fibrous 
tissue to occur more rapidly.

ĥ i Auction in circulation, due to vaso-motor paralysis 
ana lack of muscular activity impairs the nutrition to the 
part and accelerates degeneration of the fibres.10 Lack of 
muscular activity may be due both to the paralysis of muscles 
• t0 immobilisation of the part following other injuries 
,n„ur^ a t  the same time. It may also be due to bad splint- 

g ot the part to support the paralysed muscles.
nvlr)e£afaiysed r o u t e s  are very susceptible to traum a and

-stretching which accelerates degeneration.11
Ip/ h"* ,^°.n' neVral complications at the time of injury may 
interitSiaiI11fla-1i me?-t ,of .circulation and the formation of 
formati™ f l whlctl wil1 impair nutrition and hasten the 
■urmation of fibrous tissue.

The end picture in long standing denervation is one of 
widespread interstitial fibrosis involving muscles, joints, 
tendon and fascial planes with contractures of muscles! 
From the above experiments and clinical findings it seems 
reasonable to believe that the prognosis on functional 
recovery of human muscle for periods up to 12 months 
following denervation is good, and that it thereafter depends 
on conditions prevailing both at the time of injury and 
during the period of denervation.

THE ROLE OF ELECTROTHERAPY

To date no procedure is known which will influence axon 
regeneration and treatment must be directed towards 
maintaining the part in as good a condition as possible 
until reinnervation occurs and to restore full function and 
muscle power following recovery.

The questions one asks are:
Can electrical stimulation of denervated muscle prevent 

atrophy and fibrosis ? and
Can it accelerate the period between reinnervation and 

restoration of full power?
Experiments have shown the answer to the second question
o be in the negative49’ 26 but widely conflicting views are 

held on the first question.

Experimental Findings

While some animal experiments have shown that atrophy 
of muscle following denervation can be retarded, but not 
prevented by electrical stimulation,12’ 13’ 16> 16. 2. 23■ « 
others have shown that electrical stimulation is of no value 
in the prevention of denervation atrophy.18’ 19> 20>21 Still 
other workers have found the value unproven or unsure.5 22

The differences which arise are due, apparently to :—
1. different methods of assessing degree of atrophy;
2. different animals used;
3. different strength of contraction;
4. different duration and frequency of treatment.

1. Methods o f Assessing Atrophy
These have included weight of. the muscle as compared 

to normal side, wet and dry weight after death, measure­
ment of maximal tension, volumetric readings, histological 
studies, oxygen consumption comparisons, strength dura­
tion curves and measurement of double refraction. Measure­
ment of weight has proved difficult due to the fact that 
connective tissue proliferation will increase weight and is 
liable to increase if there has been inflammation and trauma, 
and there is therefore no indication of how much weight 
maintenance is due to muscle bulk and how much due to 
connective tissue proliferation. Volumetric measurements are 
complicated by the increase in fluid in the muscle following 
contraction and must not be done immediately after 
exercise. The most reliable method is the histological study 
of muscle sections which show degree of muscle fibre, the 
size of the fibres and amount of connective tissue present.

2. Different Animals Used
Most experiments which showed a positive finding were 

carried out on the gastrocnemius muscle of the rat or rabbit. 
When experiments were tried on monkeys, cats and dogs 
they were found to be unsuccessful and the theory that 
there was a species difference was postulated. However, 
histological studies on rat gastrocnemius muscle showed 
that only the peripheral muscle fibres retained some bulk, 
but that the deeper fibres had atrophied.15 The muscles of 
the other species are larger than those of the rat and perhaps 
this fact is responsible for the species difference, i.e. that 
stimulation can only affect superficial fibres and very small 
muscles.

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3. Different Strength of Contraction
Here the more successful experimentalists anaesthetised the 

animal to produce strong contractions, often against 
resistance. Trophic changes on the skin caused difficulties 
and the electrodes had to be moved continually from place 
to place. In the experiments showing no beneficial results 
the animals were not anaesthetised and treatment was within 
the patient’s tolerance. It would appear that success in 
retarding denervation atrophy depends on producing strong 
contractions preferably against a load.

4. Different Duration and Frequency of Treatment
Many different opinions were voiced on this matter. As 

far as the type of current used was concerned, whatever type 
produced the required contraction a t the lowest intensity 
appeared to meet the requirements. Duration of treatment 
varied from several seconds a day to throughout an eight- 
hour period. Some experimentalists felt there was no duration 
difference, a short treatment being as effective as prolonged 
treatment, but in those experiments which produced positive 
findings 20-30 minutes treatment was given. Fatigue was 
found to have no detrimental effect on the muscle, and the 
rest periods were given to allow the muscle to recover before 
continuing stimulation.

Frequency of treatment worked on the more the better 
principle, twice daily better than daily and only twice a 
week being ineffective.

CLINICAL TRIALS

Clinical trials on man introduce many more problems 
for accurate assessment, suitability of patients and time 
available for treatment. Of the six trials reported, four 
showed negative results.27’ 28■ 29> 30 The trials were carried 
out on patients with radial, ulnar and median nerve lesions 
and facial paralysis. Two trials on denervated hand muscles, 
where volumetric measurement was used to assess muscle 
atrophy showed retardation of atrophy about seven per 
cent better on the treated muscles than on the untreated 
muscles.25- 26

In  all trials only patients who continued the treatment 
daily were assessed. In  the trials showing retardation of 
atrophy25’ 26 it was stated that any break in continuity did 
not produce results and full daily treatment was essential. 
Duration of treatment was 90 contractions strong enough 
to move the hand with gravity eliminated. The difference 
in atrophy between treated and untreated tmuscles was 
only in the region o f seven per cent and as no patients were 
stimulated before 60 days, the muscles had already atro­
phied 60 per cent. The prevention o f seven per cent further 
atrophy as the result of daily treatment for periods up to 
400 days does not really seem very significant. This view 
was held by the authors of a report on similar clinical trials 
with the same results30 who felt that they did not justify 
the expenditure of time, money and personnel in the routine 
application of electrical stimulation to denervated muscle.

Trials on facial muscles27' 29 treated daily with 90 con­
tractions per day (never less than 30), for up to seven months, 
were completely negative, no shortening o f the interval 
between initial movement and full recovery or time of onset 
of initial movement being shown as compared to untreated 
muscles.

In a comprehensive study of denervated muscles supplied 
by the radial nerve26 patients’ tolerance allowed moderate 
contractions of which only 30 were given daily. No benefit 
was shown from electrical stimulation which may have been 
due to the short duration of daily treatment. However, the 
authors then carried out trials to assess the amount o f work 
done by a muscle during, electrical stimulation and used 
the amount o f increased blood flow as an index. A sleeve 
plethysmograph recorded volume increase and lesions where 
the distal part o f the limb was totally denervated, such as

sciatic nerve and brachial plexus lesions, were chosen. To 
produce contractions of sufficient intensity, the skin had 
to be anaesthetised in sciatic nerve lesions, the arm already 
having lost sensation in the brachial plexus lesions. Com­
parisons were made of the injured limb after stimulation 
using five times the skin tolerance intensity for four minutes 
at 30 and 60 contractions per minute and the uninjured limb 
after one hour’s rest and then active movement against slight 
resistance for half a minute. The increase in blood flow after 
stimulation at far above normal tolerance of current intensity 
produced no increase in circulation whilst the active move­
ment produced a marked increase. Electrical stimulation 
was carried out in the same way on normal muscle also 
with no effect and the authors felt that it is impossible to 
produce a useful degree of exercise by electrical stimulation.

CLINICAL AND EXPERIMENTAL EVALUATIONS

There have been numerous articles written on the subject 
after clinical experience in which opinions differ widely,31’ 32 
some feeling that, if the lesion will take long to recover, 
treatment should be given35 while others feel the exact 
opposite.41 Earlier workers felt only the weakest contraction 
possible should be used33 whilst still others that a large 
number of vigorous contractions37 should be used. Finally 
there have been those who feel that the value of stimulation 
is unproven and balanced against the length o f time for 
which the patient needs to attend and the use of the physio­
therapy department it is not worth undertaking.34' 36

This latter view is held in the Medical Research Council 
Report on Peripheral Nerve Lesions.38

The difficulty o f assessing which of the modalities one is 
employing during treatment has the most benefit, is obvious.

In the more recent articles, opinion has very markedly 
swung away from the need to use electrical stimulation in 
nerve lesions.39’ 40’ 41,42’ 43’ 44’ 45, 48> 47’ 48 If the treatment is 
mentioned at all, it is stated that it is not used or that its 
value is doubtful with the above conclusions.

The most comprehensive physiotherapy article read44 on 
the treatment of nerve lesions puts emphasis on the control 
of oedema, maintenance of joint range, constant usage of 
the limb and intensive re-education once re-innervation has 
occurred of both motor and sensory function. Good func­
tional results have been attained without resorting to electro­
therapy at any stage.

Of interest is that the facial muscles do not benefit from 
treatment27' 29 and physiotherapy is not advocated by 
leading workers treating facial paralysis.46’ 48’ 47

SUMMARY

1. The structure o f a Peripheral Nerve trunk is discussed.
2. Causation of damage to a peripheral nerve is discussed 

and five degrees of nerve damage listed.
3. Changes in structure deprived of their nerve supply, 

particularly muscles, are explained.
4. It has been shown experimentally that electrical stimu­

lation producing strong contractions o f denervated muscle 
against a load, given daily for 20-30 minutes will not 
prevent muscle atrophy but will retard it in the smaller 
animals such as the rat and the rabbit.

5. Clinical trials have failed to prove any marked benefit 
from the treatment o f denervated muscle by electrical 
stimulation.

6. Recent views on the subject show that while it may be of 
some value, it is not a necessary part of treatment and 
does not justify the time, money and effort needed to 
carry out the treatment.

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