The feasibility, safety, and efficacy of myoblast transfer therapy (MT
T) were assessed in an experimental lower body treatment (LBT) involvi
ng 32 Duchenne muscular dystrophy (DMD) boys aged 6-14 yr, half of who
m were nonambulatory. Through 48 injections, five billion (55.6 x 10(6
)/mL) normal myoblasts were transferred into 22 major muscles in both
lower limbs, in 10 min with the subject under general anesthesia. Ten
subjects received myoblasts cultured from satellite cells derived from
1-g fresh muscle biopsies of normal males aged 9-21 yr. Donor myoblas
ts for the remaining 22 boys were subcultured from reserves frozen 1 m
o-1.5 yr ago. Only four donors were known to have identical histocompa
tibility with their recipients. All subjects took oral doses of the im
munosuppressant cyclosporine (Cy), beginning at 2 days before MTT and
lasting for 6 mo after MTT to facilitate donor cell survival. There wa
s no evidence of an adverse reaction to MTT or Cy as determined by ser
ial laboratory evaluations including electrolytes, creatinine, and ure
a. Objective functional tests using the KinCom Robotic Dynamometer mea
sured the maximum isometric contractile forces of the ankle plantar fl
exors (AF), knee flexors (KF), and knee extensors (KE) before MTT and
at 3, 6, and 9 mo after MTT. The AF, being distal muscles and less deg
enerative than the KE and the KF, showed no decrease in mean contracti
le force 3 mo after MTT, and progressive increases in force at 6 and 9
mo after MTT. At 9 mo after MTT, 60% of the 60 AF examined showed a m
ean increase of 50% in force ; 28% showed no change; and only 12% show
ed a mean decrease in force of 29% when compared to the function of th
e same muscles before MTT. The KF, being proximal muscles and more deg
enerative, showed no change in function at 9 mo after MTT. The KE, bei
ng proximal and anti-gravitational, were most degenerative before MTT.
They showed no statistically significant change in force at 3 mo afte
r MTT but showed decreases at 6 and 9 mo after MTT. At 9 mo after MTT,
23% of the 60 KE examined showed a mean increase of 65% in force; 22%
showed no change; and 55% showed a mean decrease of 24% in force. Whe
n results of all muscle groups (AF, KF, KE) were pooled, there was no
change in force at 3, 6, or 9 mo after MTT vs. before MTT according to
the Wilcoxon signed rank test. The ambulatory subjects showed more mu
scle improvement than the nonambulatory ones at various times after MT
T. Statistically significant progressive increase in force in the AF a
nd arrest of weakening in the KF and KE were observed in the ambulator
y subjects as early as 3 mo and continued up to 9 mo after MTT. Statis
tically significant changes were confirmed with analyses of variance.
The results indicate that (a) MTT is safe; (b) MTT improves muscle fun
ction in DMD : 88% of the AF, 49% of the KF, and 45% of the KE showed
either increase in strength or did not show continuous loss of strengt
h 9 mo after MTT; (c) the dosage used is more effective in the AF than
in the KF, and is least effective in the KE; (d) more than 5 billion
myoblasts are necessary to strengthen both lower limbs of a DMD boy be
tween 6 and 14 yr of age; (e) the more degenerated proximal muscles wi
ll need more myoblasts per unit muscle volume than the distal muscles
for MTT to be effective; (f) MTT is more effective in the younger, amb
ulatory subjects than in the older, nonambulatory subjects; (g) Cy is
not responsible for the functional improvement, because muscle functio
n continues to improve 9 mo after MTT despite Cy withdrawal at 6 mo af
ter MTT; (h) Cy immunosuppression permits donor cell survival and deve
lopment, without overt rejection symptoms, when properly managed; (i)
myoblasts from frozen reserves are as effective as those from fresh mu
scle biopsies; (j) fifteen billion myoblasts can be cultured from a 1-
g muscle biopsy; (k) billions of cultured myoblasts can be injected in
to subjects without tumor formation.