KEY WORDS
Brachial plexus injury - brachioradialis - finger flexion - flexor digitorum profundus
- tendon transfer
INTRODUCTION
Loss of finger flexion can result from the lower type of brachial plexus paralysis,
combined high injuries of median and ulnar nerves and rarely loss of forearm muscles.[[1]] Avulsion of C7–T1 or C8 and T1 roots is a rare entity in adult brachial plexus
lesions representing 3% of all brachial plexus injury (BPI), where spontaneous recovery
is not possible. Residual paralysis involving C7, C8 and T1 nerve roots with incomplete
recovery of C5 and C6 or C5–C7 is not common in pan brachial plexus injuries; however,
there are chances of useful recovery of elbow extension, wrist extension and wrist
flexion. There seems to be a deficit in the recovery of finger flexion in almost all
of the cases.
In such injuries, in addition to loss of the flexor digitorum profundus (FDP), there
is an accompanying loss of the flexor pollicis longus (FPL) and varied loss of the
function of intrinsics along with absence of finger extension due to associated paralysis
of extrinsic extensors. Even with a successful nerve repair, secondary tendon transfers
are required to address the intrinsic paralysis.[[2]] The clinical presentation is a flat hand and thumb that is adducted because of
gravity; all grip functions is lost [[Figures 1]
[2]].
Figure 1: Preoperative image showing flat hand
Figure 2: Preoperative image with flat hand and adducted thumb
Although nerve repairs below the elbow can return the function of the FDP, higher
injuries, especially when treated with nerve grafts, may not give adequate return
of function.[[3]] In early presentatation of lower plexus injuries, finger flexion and finger extension
can be restored by using peripheral nerve transfers like BR motor branch or brachialis
branch of the musculocutaneous nerve to anterior interosseus nerve, and supinator
branch to posterior interosseus nerve.[[5]
[6]
[7]]
The functioning muscle transfer is a well-known procedure, especially for pan brachial
plexus injuries and electrical burns, where no local muscles are available for a transfer.
This procedure has a 6–12 month rehabilitation period before any useful recovery can
be seen.[[8]] Tendon transfers, in contrast, provide an earlier return of function, within a
period of 3 months.
This study analyses the functional improvement in finger flexion following transfer
of the BR muscle to the FDP tendon.
Aims and objective
The aim and objective of this study is to determine the efficacy of the BR transfer
in providing finger flexion and the quality of hand function regained after other
ancillary procedures on the thumb and fingers.
MATERIALS AND METHODS
Eleven patients underwent BR to FDP tendon transfer between January 2013 and January
2017. All of them were diagnosed with lower BPI; the time to presentation for treatment
from the time of injury varied from 10 to 30 months.
All the patients had a flat hand with an inability to flex the fingers at the proximal
interphalangeal joint (PIPJ) and distal interphalangeal joint. In addition, these
patients had evidence of intrinsic muscle paralysis and loss of finger extension.
A complete physical examination was performed to assess the strength of all available
muscles in the upper limb at or below the elbow. Among the 11 patients, nine were
male, and two were female. Age ranged from 20 to 45 years, and there was one child
with 6 years of age.
All these patients had a normal shoulder function; elbow extension was M3 to M4 in
5 patients due to C7 injury. Two of the 11 patients had a normal wrist extension.
Details of these are mentioned in [Table 1].
Table 1
Patient details
|
Age/sex
|
DOI
|
Mode of injury
|
Type of injury
|
Time since injury (month)
|
Clinical presentation
|
|
Finger movement
|
Wrist movement
|
|
Date of Issuance
|
|
24/male
|
6th May, 2015
|
Fall on conveyer belt
|
C7, C8, T1
|
11
|
Fl and ext0/5
|
Fl+
Ext-
|
|
25/male
|
16th April, 2015
|
RTA
|
C8, T1
|
16
|
Fl and ext 0/5
|
Fl 3+
Ext 4+
|
|
20/male
|
10th February, 2012
|
RTA
|
C8, T1
|
30
|
Fl and ext 0/5
|
Fl 3+
Ext 4+
|
|
28/male
|
10th July, 2012
|
Fall from height
|
C7, C8, T1
|
11
|
Fl and ext 0/5
|
Fl 3+
Ext -
|
|
20/male
|
21st August 2015
|
RTA
|
C7, C8, T1
|
10
|
Fl and ext 0/5
|
Fl 3+
Ext 2+
|
|
6/female
|
10th October, 2015
|
RTA
|
C8, T1
|
11
|
Fl and ext 0/5
|
Fl 3+
Ext 2+
|
|
24/male
|
27th June, 2015
|
Fall from height
|
C8, T1
|
12
|
Fl and ext 0/5
|
Fl 3+
Ext -
|
|
40/female
|
27th February, 2013
|
RTA
|
C7, C8, T1
|
10
|
Fl and ext 0/5
|
Fl 0
Ext 3+
|
|
19/male
|
02nd January, 2013
|
RTA
|
C8, T1
|
27
|
Fl and ext 0/5
|
Fl 4+
Ext -
|
|
26/male
|
16th April, 2012
|
RTA
|
C7, C8, T1
|
11
|
Fl and ext 0/5
|
Fl 0+
Ext 2+
|
|
45/male
|
25th December, 2013
|
Assault
|
C8, T1
|
19
|
Fl and ext 0/5
|
Fl 0+
Ext 4+
|
The primary surgical procedure performed was a transfer of the BR tendon to the FDP
tendon.
Additional procedures were performed either simultaneously or sequentially to address
the problems of
-
Absent FPL function of thumb
-
Absent palmar abduction of thumb
-
Intrinsic paralysis and ‘claw attitude’ at the PIPJ of the fingers.
Details of these are mentioned in [Table 2].
Table 2
Surgical procedures performed
|
Primary surgical procedure
|
Complications
|
Simultaneous ancillary procedures
|
Secondary ancillary procedures
|
|
BR: Brachioradialis, FDP: Flexor digitorum profundus, FCR: Flexor carpi radialis,
PL: Pollicis longus, APB: Abductor pollicis brevis, ECRB: Extensor carpi radialis
brevis, PIPJ: Proximal interphallangeal joint, CMCJ: Carpometacarpal joint
|
|
BR to FDP tendon transfer
|
Nil
|
C7 neurolysis
|
PIPJ, CMCJ arthrodesis
|
|
BR to FDP tendon transfer
|
Nil
|
FCR-APB
|
Intrinsic transfer using ECRB
|
|
BR to FDP tendon transfer
|
Nil
|
PL-APB
|
Intrinsic transfer, PIPJ arthrodesis
|
|
BR to FDP tendon transfer
|
Nil
|
FCR-APB
|
-
|
|
BR to FDP tendon transfer
|
Nil
|
CMCJ arthrodesis
|
-
|
|
BR to FDP tendon transfer
|
Nil
|
PL-APB
|
-
|
|
BR to FDP tendon transfer
|
Snapped tendon repair
|
-
|
PIPJ, CMCJ arthrodesis
|
|
BR to FDP tendon transfer
|
Nil
|
-
|
Brachialis to APB transfer, intrinsic transfer
|
|
BR to FDP tendon transfer
|
Nil
|
FCR-APB
|
-
|
|
BR to FDP tendon transfer
|
Nil
|
-
|
-
|
|
BR to FDP tendon transfer
|
Nil
|
CMCJ arthrodesis
|
-
|
At the 6 months follow-up examination, patients were evaluated for range and strength
of finger flexion achieved and ability to adopt various basic handgrips.
-
a. Range of finger flexion was assessed by measuring distance between pulp of the
index finger and distal palmar crease with a scale
-
b. Strength of finger flexion was assessed by passively stretching the fingers completely
by examiner's hand and noted per Medical Research Council (MRC) grades
-
c. Hook grip strength was assessed by measuring maximum weight the patients can hook
(500 ml normal saline pints in a plastic bag) with elbow in extension.
Patients were asked to perform various activities required to adopt various handgrips
such as holding a pin, key, wooden block, glass, and recap a water bottle.
Surgical technique
The surgical procedure was performed under general anaesthesia or axillary brachial
block with the application of an arm tourniquet inflated after exsanguination with
an Esmarch's bandage.
A longitudinal incision was given over the middle two-fourths of the forearm along
the medial border of the BR musculotendinous unit. The dissection of the tendon was
started distally by carefully protecting the radial vessels on medial aspect as well
as the radial nerve and the extensor muscles of the forearm on the lateral aspect.
The distal insertion of BR was detached from the base of the radial styloid. Proximal
dissection of the muscle was stopped at the widest part of the muscle in the proximal
third of the forearm; however, the investing fascia was opened over the portion of
the muscle below the elbow to improve excursion [[Figure 3]].
Figure 3: Intraoperative photograph showing isolated brachioradialis, flexor digitorum profundus,
flexor carpi radialis, flexor pollicis longus
At least, 30 mm of passive excursion of BR tendon was obtained from resting position
of the muscle.
The original incision was extended transversely over distal forearm or a second vertical
incision was given along the ulnar aspect of the distal forearm to isolate the FDP
tendons.
FDP tendons were identified, separated from the ulnar neurovascular bundle, cut at
musculotendinous junctions and sutured together.
BR tendon was sutured to bunched up FDP tendons with 2.0 polypropylene suture using
the Pulvertaft technique [[Figure 4]].
Figure 4: Brachioradialis flexor digitorum profundus, flexor carpi radialis-flexor pollicis
longus tendon transfer
Tension of transfer was adjusted with elbow at neutral, forearm supine, wrist in neutral
to allow all fingers to assume a hook position. A tube drain was placed after deflation
of the tourniquet and the incision was closed in layers.
An above elbow dorsal blocking plaster slab was applied for immobilisation with the
elbow flexed at 90°.
The patient was discharged between three to 5 days and was advised a follow-up visit
after 1 week. The above elbow slab was converted to a below elbow slab after 3 weeks
and finally removed at 6 weeks.
For the first 3 weeks, the patient performed isometric exercises using the BR to FDP
transfer; next 3 weeks active flexion was done for 15 min four times a day. At 6 weeks,
a dorsal outrigger splint was given to permit full active flexion of the fingers (as
the opening of the hand was not possible due to lack of intrinsics and finger extensors).
RESULTS
Eleven patients with complete loss of finger flexion and intrinsic paralysis were
included in the study.
There were nine male and two female patients. Age ranged from six to 45 years mean
age was 25.1. There was one female child, 6 years of age, while the age of other patients
varied from 20 to 45 years.
All the patients presented for examination between 10 and 30 months after injury.
Five patients had Grade 3–4 elbow extension with C7, C8, T1 BPI and six patients had
C8, T1 BPI. Only two of 11 patients had Grade 5 wrist extension. Pre-operative finger
movements were nil in all the patients.
Primary surgical procedure to restore finger flexion was a tendon transfer using the
BR end-to-end to the FDP of the fingers. Simultaneous ancillary procedures were performed
in seven of the 11 patients addressing the thumb [[Table 2]]. The palmaris longus or flexor carpi radialis was transferred to abductor pollicis
brevis (APB) in five patients. First, carpometacarpal joint (CMCJ) arthrodesis was
done in 2 patients positioning the thumb in opposition, where no tendons were available
for transfer. Five patients underwent secondary procedures, two had their PIPJ and
CMCJ arthrodesis performed while intrinsic transfer using extensor carpi radialis
brevis (ECRB) was performed on two patients. Brachialis to APB transfer was done in
one patient; however, acceptable result was not achieved. One patient had post-operative
complication of snapped tendon repair after 2 weeks which was repaired immediately.
Three out of the 11 cases were not available for follow-up. The remaining eight cases
have been evaluated on follow-up for pulp to palmar crease distance, strength of finger
flexion, hook grip strength, total range of movement and ability to adopt basic hand
grips and variables have been mentioned in [Table 3].
Table 3
Results
|
Pulp to palmar crease distance
|
Strength of finger flexion
|
Hook grip strength
|
Grips able to do
|
Total ROM
|
|
ROM: Range of motion
|
|
0 cm
|
M4
|
>5 kg
|
Hook, span, key, chuck, pulp pinch
|
270°
|
|
2 cm
|
M4
|
>4 kg
|
Hook, span, key, chuck
|
240°
|
|
3 cm
|
M4
|
>4 kg
|
Hook, span, key, chuck, pulp pinch
|
210°
|
|
2 cm
|
M3
|
>4 kg
|
Hook, span, pulp pinch
|
240°
|
|
2 cm
|
M4
|
>3 kg
|
Hook, span, key, chuck, pulp pinch
|
240°
|
|
3 cm
|
M3
|
>2 kg
|
Hook
|
210°
|
|
4 cm
|
M3
|
>3 kg
|
Hook
|
180°
|
|
3 cm
|
M4
|
>3 kg
|
Hook, key
|
210°
|
Pulp to palm distance was 1 cm in one patient, 1–3 cm in six patients and 4 cm in
1 patient [[Figures 5]
[6]].
Figure 5: Postoperative finger flexion
Figure 6: Pulp to palm distance 0 cm
Finger flexion strength as assessed by examiners hand (after the complete extension
of the fingers) was M4 in 5 patients and M3 in three patients [[Figure 7] and Videos 1,2].
Figure 7: Measuring strength of finger flexion
Hook grip strength was >4 kg in four patients and 2–4 kg in four patients [[Figures 8]
[9]].
Figure 8: Measuring hook grip strength
Figure 9: Measuring hook grip strength
Total ROM of fingers was 270° in one patient and 180°–240° in seven patients.
Four of the eight patients got a functionally useful hand to carry out activities
of daily living with hook grip, span grasp, key pinch, chuck grip and pulp pinch.
These patients also underwent simultaneous or secondary ancillary procedures. None
of them got a power grasp. One patient underwent a secondary procedure for thumb abduction
using a tendon graft from brachialis to APB, but did not achieve enough handgrip and
needed further procedures for the improvement of the same. Three patients did not
undergo any secondary procedures, still are under follow up and will need additional
procedures to further improve functionality of the hand despite having a flexion range
[[Figures 10]
[11]
[12]].
Figure 10: Pin grip
Figure 11: Chuck grip
Figure 12: Functionality of reconstructed hand
DISCUSSION
Restoration of hand function after C7–T1 brachial plexus injuries has long been challenging
for surgeons. Tendon transfers are a routine procedure used to improve hand function
in brachial plexus injuries. The choice of donor motor for the restoration of digital
flexion has been extensor carpi radialis longus (ECRL); this assumes a functioning
ECRB and takes advantage of the synergism in finger flexion and wrist extension.[[9]] Biceps (reinnervated or normal) or the brachialis has also been used for transfer
to the FDP tendons but with the addition of a tendon graft usually harvested as a
fascia lata graft.[[10]
[11]]
BR due to its high innervation (C5, C6) is a valuable option as a donor to restore
finger flexion in the lower plexus type of palsies. Not many studies are available
describing the use of BR to restore finger flexion. Although excursion of BR is (3
cm) less compared to FDP (7 cm), after complete fascial release, there is 2–3 cm increase
in excursion, which is comparable to ECRL.[[12]]
In our study, presentation since time of injury was 10–30 months, leaving no option
of nerve repair or transfer. Movement was achieved by 3 months post-operatively with
no prolonged lag period. Power of finger flexion was M4 in four patients and M3 in
four patients. Xu et al. study of finger flexion strength after brachialis motor branch transfer[[13]] has only corresponded to the MRC Grades M2–M3, lowering the grip strength and practical
value of the reconstructed hand. To obtain satisfactory hand function, combined nerve
and tendon transfers were done in staged procedures. Nerve transfer was done within
5 months since the time of injury. Second surgery was performed 9 months after the
first with power of finger flexion M3 and 30 months follow-up showed M4 power in three
fingers. Brachioradalis tendon was transferred to APB to restore thumb opposition.
Total active range of movement achieved in our present series in eight cases who came
for follow-up was between 180° and 270°. Doi et al.[[14]] in their case series achieved total active range of movement of the fingers between
70° and 110° following free functional muscle transfer with gracilis muscle.
Mohindra et al.[[15]] showed that, for key pinch reconstruction, both BR and PT turned to be equally
efficacious donors, while for hook reconstruction, PT and BR transfer to FDP turned
out to be superior to FDP tenodesis in tetraplegic hands for the restoration of finger
flexion and key pinch. In lower plexus type of injury, if PT is used as a donor, pronation
may be affected due to lower trunk innervation of pronator quadratus by the anterior
interosseous nerve (C8, T1).
CONCLUSION
The BR is effective in providing adequate range and power of finger flexion; this
muscle is always preserved in lower plexus injuries due to high innervation (C5, C6).
It is expendable as an elbow flexor. A comparable excursion to that of the ECRL can
be achieved after complete fascial release; this makes it valuable in allowing wrist
extension to be conserved. This is important as only two of the 11 patients with lower
plexus injuries in this series had a normal wrist extension. Although the pronator
teres could also be used,[[16]] the absence of a pronator quadratus, which is innervated by the anterior interosseous
nerve (C8, T1) could deprive forearm pronation. It is true that further functional
improvement necessitates other tendon transfers and strategic arthrodesis.
Declaration of patient consent
The authors certify that they have obtained all appropriate patient consent forms.
In the form the patient(s) has/have given his/her/their consent for his/her/their
images and other clinical information to be reported in the journal. The patients
understand that their names and initials will not be published and due efforts will
be made to conceal their identity, but anonymity cannot be guaranteed.
Financial support and sponsorship
Nil.
