Evolution of placental mammals over the past 160 million years witnesses the relative sparing of muscles from cancer attacks. In 1) nude mice with human gastrointestinal or lung tumors, and 2) human subjects with liver, lung or gastrointestinal tumors, intra-tumor implantation of allogeneic human myoblasts induced cancer apoptosis, inhibiting metastasis and tumor growth. We postulate four mechanisms of cancer apoptosis: a) myoblasts releasing tumor necrosis factor- α (TNF- α); b) deprivation of nutrients and oxygen; c) local inflammatory and immunologic attacks; and d) prevention from metastasis. These basic and clinical studies demonstrated preliminary safety and efficacy of intra-tumor myoblast implantation in the development of prevention and treatment for cancer, now the number one disease killer of mankind.
Myoblast transplantation is the world’s first human gene therapy and somatic cell therapy that corrected the primary gene defect of Duchenne muscular dystrophy boys in year 1990 [
Skeletal myoblasts have a unique ability to fuse. Implanted myoblasts naturally fuse among themselves to form genetically normal myofibers to replenish dead fibers [
In the 500 million years of vertebrate evolution, especially during the 160 million years of mammalian divergence of placental and marsupial [
The discovery of a muscle development promotion factor called cachectin or tumor necrosis factor-α (TNF-α) [
In year 1995, Law disclosed the results of co-cultures of normal human myo- blasts and malignant melanoma (CRL6322) cells [
The switching from culture medium to fusion medium constituted a condition of serum restriction because the fusion medium contained only one-fifth of the serum concentration as in the culture medium. Serum restriction terminated the mitotic cycle of the myoblasts, and initiated the developmental process of natural cell fusion towards myotube formation. Law envisioned that myoblast fusion was associated with membrane breakage with significant amount of TNF- α and possibly other cancer killing factors being released. Furthermore, myoblast fusion resulted in myotube formation and development, quickly depriving the melanoma cells of oxygen and nutrients within the confined microenvironment of the tumor capsule. These two mechanisms were considered to be responsible for the melanoma cell death in the co-culture studies [
TNF-α is an endogenous muscle factor promoting myogenesis through activation of the p38α and Pax7 pathway [
In 2013, Stolting et al. reported that myoblasts restricted prostate cancer growth and metastasis by paracrine TNF-α secretion. An increase up to 25 fold of TNF-α mRNA basal level was demonstrated when myoblasts were co-cultured with tumor cells. Co-culture experiments revealed induction of cell cycle arrest, tumor death by apoptosis and increased myoblast differentiation. This effect was largely blocked by TNF-α inhibition. The same outcome was noted in nude mice, in which co-injected human myoblasts inhibited the tumor growth and lymph node metastasis of all prostate cancer cell lines evaluated [
Based on the above information, we initiated a series of animal experimentation leading to a clinical study testing the feasibility, safety and preliminary efficacy of implantation of allogeneic human myoblasts into solid tumors of cancer patients as follows.
Upon approval of the Institutional Review Board (IRB) of the Cell Therapy Institute and the signing of the Donor Informed Consent, muscle donors were admitted after meeting the Inclusion and Exclusion criteria. They were male volunteers between the ages of 13 and 27. They were certified by a physician as being in good health, having normal levels of aspartateaminotransferase (AST), alanine transaminase (ALT), or lactate dehydrogenase (LD) and tested negative for human immunodeficiency virus (HIV), hepatitis B surface antigen (HBSAg), hepatitis C (HCV), syphilis (RPR), and cytomegalovirus (CMV-IgM). They also received the following tests: Chem 24, CBC, and physical examination with nor- mal results. Donors were excluded if they had any chronic or infectious diseases, or were allergic to the local anesthetic Lidocaine.
About 2 grams of muscle were removed from the quadriceps muscle using an open biopsy technique under local anesthetic (Lidocaine) in a sterile field of a surgical suite of a hospital. The donor site was sutured and bandaged. No prophylactic antibiotic was used. The donor was discharged after recovery from the surgical procedure to be followed by his physician if infection occurred.
Biopsy specimen obtained was processed immediately using sterile techniques meeting CFDA approved GMP and ISO 9001 standards. Myoblasts were cultured in growth medium and incubated in 35˚C - 37˚C and 7% CO2 as previously described [
Random samples of the myoblasts were tested for their ability to divide, fuse, and form myotubes [
To determine biologic dosing and pharmacokinetics, nude mice were used to test the effect of human myoblasts on the proliferation and apoptosis of non- small-cell lung cancer (NSCLC) A549 cells, and of human gastrointestinal cancer cells SGC-7901 in subcutaneous solid tumors. In addition, human myoblasts were injected into tumors having Ehrlich ascites cells (BS344 EAC) in KM mice to determine if such intervention might prolong the life-spans of the cancer inflicted mice.
Male BALB/c nude mice averaging 17 ± 1 g were obtained from Beijing Witung Lihua Limited Co. SCXK (Beijing) 2008-0005. Male KM mice averaging 20 ± 2 g were obtained from Hubei Animal Experimentation Center SCXK (Wuhan) 2014-0007. Mice were maintained in compliant with SPF standards. NSCLC and EAC were supplied by the Alfie Inc., Wuhan. Six animal studies were conducted as listed in
Involved 20 nude mice injected subcutaneously on each side of the back with 0.2 mL of A549 NSCLC cells at a concentration of 25 million/ml. After 18 to 20 days when the tumors reached 250 - 300 mm3 in volume and had developed capillary network of their own, 0.2 ml of saline was injected into the left tumor and 0.2 ml of human myoblasts into the right tumor at a low concentration of 10 million/ml of saline.
The length and width of control and test tumors were measured every week using a caliper. The volume was calculated using the formula: (length × width2)/2. At 3 weeks after myoblast treatment, mice were sacrificed and the tumors dissected out and weighted. Student’s t-tests demonstrated significant difference at P < 0.05 between the mean volumes (2687.8 ± 713.4 mm3 vs. 2133.7 ± 638.3 mm3) and weights (3.12 ± 0.88 g vs. 2.48 ± 0.78 g) of control versus myob-
Studies | Cancer | Cell Line | No. of Mice | Myoblasts/Volume | Days Follow-up |
---|---|---|---|---|---|
1 | NSCLC | A549 | 20 | 2 × 106/0.2 ml | 21 |
2 | GI | SGC-7901 | 8 | 6 × 106/0.15 ml | 5 |
3 | GI | SGC-7901 | 22 | 2 × 106/0.15 ml 10 × 106/0.15 ml | 15 4 |
4 | GI | SGC-7901 | 5 | 14 × 106/0.15 ml 6 × 106/0.15 ml | 4 5 |
5 | GI | SGC-7901 | 6 | 28 × 106/0.15 ml | 9 |
6 | EAC | BS344 | 11 | 50 × 106/0.2 ml | 22 |
EAC | BS344 | 10 | 0/0.2 ml | 17 |
Group | Volume (mm3) | Weight (g) x ± SD (n = 8) | TIF (%) | |||
---|---|---|---|---|---|---|
d0 | d7 | d14 | d20 | |||
Control | 305.5 ± 78.6 | 1032.8 ± 310.4 | 1875.3 ± 546.8 | 2687.8 ± 713.4 | 3.12 ± 0.88 | |
Test | 325.8 ± 101.4 | 874.2 ± 276.5 | 1586.0 ± 488.7 | 2133.7 ± 638.3* | 2.48 ± 0.78* | 20.5 |
TIF, tumor inhibitory factor; *indicates p < 0.05 by Student’s t-test.
last-treated tumors (
Consisted of four groups of nude mice aged 4 to 5 week old that had previously received subcutaneous injections of GI SGC-7901 cancer cells on the back and had developed mature tumors of similar sizes on both sides measuring approximately 0.3 × 0.2 × 0.2 cm. These dose-escalation studies were designed to study the pharmacokinetics of myoblasts to determine the safety and efficacy of treating gastrointestinal cancer using different myoblast concentrations and procedures.
For example, Studies 2 and 5 involved single-time injections of 6 and 28 million myoblasts with follow-up periods of 5 and 9 days respectively. Studies 3 and 4 involved two-time injections of 12 and 20 million myoblasts with follow-up periods of 19 and 9 days respectively.
In these studies, comparison was made between myoblasts-injected tumors versus control tumors that received similar volume of carrier solution, in terms of tumor size and cancer cell number as revealed by histology of tumor sections
using H&E stain.
Histologic study demonstrated spindle-shaped myoblasts and myotubes amidst round tumor cells in the myoblast-treated tumors (
observed wrapping around the round cancer cells in sections of the myoblast- treated tumors (
Study 2 to 5 established the safe and effective dose range and optimal pharmacokinetics of the allogeneic human myoblasts in treating mature gastrointestinal cancer using different myoblast concentrations and procedures. Doses of 2 to 28 million myoblasts administered at 13.3 million/ml to 186.7 million/ml respectively were found to be safe and effective in reducing tumor volume, weight and cancer cell number. The surprising discovery of myoblasts wrapping around the cancer cells in sections of the myoblast-treated tumors (
Involved 21 KM mice injected intraperitoneal with 20 million Ehrlich ascites cellseach and randomized into test (11 mice) and control (10 mice) groups. One day later, control mice each received intraperitoneal injection of 0.2 ml of saline, whereas test mice each received 0.2 ml containing 50 million human myoblasts. The mean survival period after cancer implantation for the control mice was 15.4 ± 1.5 days, significantly less than that for the myoblast-injected mice of 18.6 ± 3.2 days at P < 0.005 by Student’s t-test. Study 6 demonstrated that 50 million allogeneic human myoblasts administered at a high concentration of 250 million/ml could extend the lifespan of mice inflicted with immature Ehrlich ascites cells by 20.8%.
Four mechanisms were considered to be responsible for inhibition of cancer cell proliferation, tumor volume reduction and cancer cell apoptosis:
1) The tumor necrosis factor-α (TNF-α) released following cell membrane breakage in the processes of myoblast mitosis and cell fusion killed cancer cells (
2) Dividing myoblasts and newly developed myotubes competed successfully and had taken away most if not all of the nutrients and oxygen inside the tumor from the cancer cells (
3) Injection trauma of allogeneic myoblasts mounted local inflammatory and immunologic attacks on both myoblasts and cancer cells (
4) Myoblasts wrapped around cancer cells, preventing them from metastasis, and continued to exert detrimental effects on them (
Results of co-culture and animal studies supported the hypothesis that mitotic or fusing human myoblasts and newly formed myotubes were potent biologics to
inhibit cancer cell proliferation, killing cancer cells and inhibiting tumor growth. Considering that our terminal cancer subjects had no immediate effective alternative, and the demonstrated safety of myoblast treatment of patients suffering muscular dystrophy, cardiomyopathy, and Type II diabetes, benefit versus risk ratio would favor proceeding onto clinical studies with cancer patients.
In China, cell transplantation is considered as a medical treatment technology and has been regulated not by the Chinese Food and Drug Administration (CFDA) but by the National Ministry of Health, now called the National Health and Family Planning Commission. As of July 2, 2015 the Commission abolished the necessity to gain approval at the national level for somatic cell transplantation to initiate clinical trials, except for stem cells. Such human studies, however, have to be approved by a Grade 3A hospital that would take on the responsibility of patient safety and register such studies with the Health and Family Planning Commission at the provincial level [
The use of allogeneic human myoblasts as a biologic in clinical studies was approved by the Institutional Review Board (IRB) of the Third Affiliated Hospital of Xinxiang Medical University in Henan, China.
Three volunteer cancer patients, aged between 55 and 80, were admitted after meeting the Inclusion and Exclusion criteria and signing of Patient Informed Consent. They were certified by a physician as being in good health, having normal levels of AST, ALT, or LD, and tested negative for human immunodeficiency virus (HIV), hepatitis B surface antigen (HBSAg), hepatitis C (HCV), syphilis (RPR), and cytomegalovirus (CMV-IgM). They also received the following tests: Chem 24, CBC, and physical examination with normal results. Subjects were excluded if they had any infectious diseases.
Being the world’s first, this clinical trial proceeded with great caution, examining the safety and efficacy of precision implantation of allogeneic human myoblasts into solid tumors of three patients having lung, liver and gastrointestinal cancers respectively.
Yang XX, female, aged 62, had history of lung cancer metastasized into the brain and the left adrenal gland. Her brain metastasis was treated previously with radiation therapy and chemotherapy for 3 weeks without remission.
The subject underwent allogeneic human myoblast implantation into the adrenal metastatic small cell carcinoma of the lung on September 10, 2015. MRI showed the tumor from 49.50 mm in its maximum length measured at one month before (
of the patient’s own serum [
Some adverse reactions were observed, treated and remised in 10 days. These included temporary reduction in blood pressure down to 82/50 mmHg, coughing, phlegm sputum and headache.
The abdomen was examined with MRI (Siemens, Magnetum-ESSENZA) before and after myoblast implantation, comparing tumor size and density through signals obtained from test and control areas. Examining methods included Axi: IN-PHASE, OPP-PHASE, TSE T2WI/FS, DWI and Cor: TRUFI, T2WI.
At 2 months after myoblast implantation, the tumor size decreased, measuring 45.86 mm in length (
Pathology of the adrenal tumor biopsies at 2 months postoperatively confirmed the diagnosis of adrenal metastatic small cell carcinoma of the lung, with TIF-1 (+), Vimentin (−), CK (pan) (−), CK7 (−), CK19 (−), SyN (+), CgA (+), Ki-67 (+, 40%). Histologic examination demonstrated that the non-injected portion of the carcinoma was densely packed with cancer cells (
Wang, XX, male, aged 67, previously diagnosed with cardiac malfunction and primary liver cancer having multiple tumors, underwent allogeneic human myoblast implantation on September 10, 2015. About 700 million myoblasts at a concentration of 100 million/ml of patient’s own serum was injected into a solid tumor measuring 35.2 mm × 25.2 mm (
The upper abdomen was examined with MRI (Siemens, Magnetum-ESSENZA) at 1 month after myoblast implantation, comparing tumor size and density
through signals obtained from test and control areas. Examining methods included Axi: IN-PHASE, OPP-PHASE, TSE T2WI/FS, DWI and Cor: TRUFI, T2WI.
MRI demonstrated that the myoblast-injected upper tumor significantly decreased in size and density with time (Figures 6(A)-(D)), whereas the non-in- jected control lower tumor in the same liver increased in size (
At 1 month after myoblast implantation, the myoblast-injected tumor was punctured and two needle biopsies were obtained measuring 1.5 cm and 2.0 cm in length respectively. Pathology demonstrated nodular connective tissue being distributed among sclerotic liver tissue. No cancerous tissue was observed (Fig- ure 5(C)), indicating that the implanted myoblasts and developing myotubes had interrupted cancer proliferation and induced cancer apoptosis.
Shang XX, male, aged 63, had previous been diagnosed with gastric cardia high/ middle differentiated ulcer type adenocarcinoma that became metastasized to the abdominal wall and the lymph node posterior to the diaphragm. Immunopathology demonstrated CEA (+), Villin (+), CK19 (+), CK7 (+/−), CK20 (−), Ki-67 (+, 30%), CKpan (+). Surgical removal and chemotherapy did not result in remission of the cancer.
On December 23, 2015, the subject underwent allogeneic human myoblast implantation into the metastasized tumor on the abdominal wall measuring 41.5 × 16.9 mm, and into the metastasized tumor in the lymph node measuring 29.0 × 23.0 mm. About 400 million myoblasts at a concentration of 100 million/ml of patient’s own serum were injected into each tumor without any adverse reaction.
At 1 month after myoblast implantation, there was a slight reduction in tumor sizes measuring 29.0 × 23.0 mm and 19.0 × 12.0 mm respectively. Histology of the abdominal tumor showed cancer cell scarcity with the presence of myotubes (
As of March 11, 2017 when this manuscript was submitted, all the myoblast-treated patients were alive and well.
Cumulated results from co-culture studies, animal experimentation and clinical trial provided confirmatory evidence to indicate that myoblasts and developing myotubes, either singly or in combination, were potent biologics that inhibited tumor growth and induced cancer cell apoptosis.
Direct injection of allogeneic (or even autologous) human myoblasts at 100 million per milliliter of host serum into the solid tumor without immunosuppressant was preferred, though myoblast concentration might vary from 75 million to 250 million per milliliter.
Exposing the allogeneic myoblasts to 100% host serum primed the myoblasts for proliferation. Implantation of this mixture into the tumor constituted serum restriction, a condition that terminated mitosis and induced cell fusion to occur.
Myoblasts’ unique characteristic shared only with cardiac and smooth muscle cells was natural cell fusion through which myoblasts at the end of their mitotic cycle underwent cell membrane breakage, releasing large but naturalquantity of cancer-killing TNF-α and possibly other TNFs into the microenvironment. The second phase of cell fusion was accomplished by massive sarcolemma formation, enclosing two hundred to five hundred myoblast nuclei into one myotube. Competition for nutrients and oxygen against cancer cells within the tightly encapsulated tumor was fierce resulting in death of cancer and myogenic cells. Each of the myotube had to be vascularized and innervated to survive, failing which the myotubes would disappear, leaving vacuoles and empty spaces within shrunken tumors. Furthermore, allogeneic myoblast implantation triggered inflammation and local immune response, killing myoblasts and cancer cells indiscriminately. Cancer cells also became non-metastatic as being “wrapped” with myoblasts immuno-stained brownish with desmin.
This is the first report to have documented plausible mechanisms and the use of precision implantation of intra-tumor myoblast implantation to treat solid tumors in cancer patients. The safety and efficacy that it demonstrated, though preliminary, lead the way to developing a potential new treatment for cancer. Lacking graft-versus-host damage, myoblasts and developing myotubes are safe biologics. Obviously the benefit versus risks ratio will favor well designed clinical trials to be conducted at their earliest, including randomized, double-blind studies.
P.K.L. is a CHINA 1000 Plan Scholar. The work was partially supported by grants awarded to P. K. L. from the Wuhan East Lake 3551 Program, and the Cell Therapy Institute, Wuhan.
Law, P.K., Song, S.J., Lu, P., Gao, Y., Ao, M.Z., Zhao, H.D., Bai, L.Y., Guo, K. and Law, D.M. (2017) World’s First Myoblast Treatment of Human Cancer Found Safe and Efficacious. Open Journal of Regenerative Medicine, 6, 1-16. https://doi.org/10.4236/ojrm.2017.61001