Background: The US FDA has recently approved autologous cultured fibroblast cells (ACF) as treatment for cutaneous contour defects. ACF provides an alternative to synthetic fillers or fat grafting with the significant advantage of producing longer lasting effect. Methods: This was a prospective open label single group clinical study to demonstrate the clinical efficacy of ACF that we have replicated in our lab. The study enrolled 18 patients with nasolabial folds from 2 centres in Malaysia in 2011-2012. ACF at dose of 23 or 92 million cells were injected on 3 occasions at 4 weeks interval. Efficacy at 6- and 12-month post treatment was assessed using a standardized 7-point scale which was performed by the 2 investigators as well as a panel of 7 independent evaluators. Results: We obtained a successful outcome (primary endpoint), defined as improvement in the appearance of the nasolabial fold of at least 2 point s on the 7-point scale, in 33% of patients as assessed by investigators at 12-month follow-up and in 22% of patients assessed by independent evaluators. Investigators also found 78% of patients having had a 1-point improvement from baseline while independent evaluators found 83% of patients having improved by as much. Patients were uniformly (100%) satisfied with the improvement in their appearance. No treatment - related adverse event was reported. Baseline score and follow - up duration had significant effect on treatment response. The greater the baseline severity and the longer the post-treatment follow-up, the better the response to ACF. Larger dose of cells (92 million cells) has little additional effect suggesting that the 1 mL dose (23 million cells) is near optimal. Older patients showed a trend towards poorer response but this was not statistically significant. Conclusions: We have successfully replicated the laboratory method and clinical procedure to perform ACF treatment which was effective in improving the appearance of nasolabial folds in some patients.
Cutaneous contour defects consist of skin soft tissue abnormalities such as superficial wrinkles around the eyes, lip, deep fold or furrows in the forehead, glabella, nasolabial and peri-oral region, or scarring of the skin due to acne, chicken pox, trauma or burns. Many patients seek correction for these defects especially those affecting the face.
Available treatments for these defects include dermal fillers and fat grating. Filler has been around for more than 30 years and still has an important role [
More recently, the US FDA has approved a new treatment for cutaneous contour defects, the autologous cultured fibroblast cells (ACF).Histopathology studies on human volunteers have demonstrated that the injected human fibroblast cells were incorporated into the dermal structure and began production of collagen or stimulated synthesis from the native cells creating the thicker collagen layer [
We have replicated the fibroblast cell culture technique in our lab. This report presents the results of a clinical replication study to demonstrate the clinical efficacy and safety of the cell therapy as performed by our lab and clinic. This is to ensure that we could replicate the same good results as those reported by others in the literature [
We conducted a prospective open label single group clinical trial at two centres in Malaysia to replicate the clinical efficacy of autologous cultured fibroblast cell (ACF) therapy. The study was conducted in accordance with Declaration of Helsinki and Good Clinical Practice (GCP) requirements. The institutional review-board of the study sites approved the protocol, and all patients gave written informed consent.
The inclusion criteria were age between 18 and 75 years, patients who were “dissatisfied” or “very dissatisfied” with the appearance of their nasolabial fold (score 4 or higher on a 5-point satisfaction scale) and the severity of which as assessed by the investigator were “moderate” or worse (Grade 4 or higher on a standardized 7-point ordinal severity scale with a photoguide).
The exclusion criteria were pregnant or nursing woman; evidence of HIV, hepatitis B and C, active systemic infection, active or chronic skin disease (such as psoriasis, eczema, blistering skin disease or local infection), severe keloid at BCG vaccination site), on chronic antibiotic or steroid therapy; history of organ transplant, autoimmune disease, alcohol or substance abuse, cancer.
Autologous fibroblast cells were isolated from a skin biopsy specimen (epidermal and dermal layers, 3 × 7 mm2) taken from the patient’s skin behind the ear and was transported to the lab in cryo vial filled with 2 mL culture media. Thermo Scientific Hyclone® classical liquid media Dulbecco’s Modified Eagles Medium, High Glucose (DMEM/High): with 4500 mg/L Glucose, with 4.0 mm L-Glutamine, without Sodium Pyruvate was used throughout the cell culture process. The skin biopsy was washed 4 - 6 times with culture media and excess fat was removed by using forceps and scissors. It was then transferred to a 60 mm petri dish, minced into small pieces and scattered over the petri dish before leaving it to dry for 10mins. Meanwhile, microbial screening for bacteria, mould and yeast was performed on the culture medium which was used to transport the biopsy tissue by spreading sufficient amount of medium onto nutrient agar and potato dextrose agar plates accordingly and observed after 3 - 5 days incubation at 37˚C. Once the biopsy tissue had adhered onto the petri dish, 3 mL culture medium mixture (DMEM/High, 10% characterized foetal bovine serum and 1% penicillin-streptomycin, all from Thermo Scientific Hyclone®) was added gently into the petri dish and incubated at 36.8˚C with 5% CO2. Medium was changed every 2 - 3 days and fibroblast cell growth was monitored under phase contrast microscope.
Subculture was performed when primary culture reached 90% confluence, cell concentration was determined to be at 2.1 - 2.4 × 107 cells/mL on average through cell count. Fibroblast cells were washed with DMEM/High and 1 mL 0.25% trypsin-EDTA was added into the petri dish for 5 min incubation at 37˚C with 5% CO2. Skin tissue might be detached from the petri dish under prolonged trypsinization process, hence 3 mL of culture medium mixture was added next to inactivate trypsin and cell suspension fluid was centrifuged at 1000 rpm for 5 min to separate the fibroblast cells from supernatant. Once the cells suspension fluid was transferred to the centrifuge tube, 3 mL culture media mixture was added immediately to the primary culture dish to maintain fibroblast cells growth. The supernatant was then aspirated and 7 mL culture medium mixture with additional epidermal growth factor (EGF) was added into the centrifuge tube to re-suspend fibroblast cells and transferred to a 100 mm petri dish and culture was continued in a 5% CO2 incubator at 37˚C. From first passage onwards, culture medium mixture with extra EGF was used to promote cell growth and temperature of CO2 incubator was maintained at 37˚C as well.
Fibroblast cells were harvested when the amount of cells were sufficient for treatment purpose, which is usually between the fourth and sixth passage. Microbial screening was carried out during the last media change which was 3 days before cell harvesting to ensure sterility of the culture. One day prior to cell harvesting, the media in all petri dishes were changed to DMEM/High, thus the culture was free from serum and antibiotics. On the harvest day, culture media was aspirated and trypsinization process was performed as described previously. After centrifugation at 1000 rpm for 5 min, the supernatant was discarded and 10 mL DMEM/High was added to the fibroblast cells pellet and mixed gently with a serological pipette followed by centrifugation again at 1000 rpm for another 5 min. The washing procedure was repeated again with DMEM/High and then washed twice using multiple electrolytes injection fluid. During the final centrifugation, supernatant was aspirated and fibroblast cells pellet were transferred into a 2 mL cryo vial before sending to the designated clinical centre where the ACF treatment is to be administered. Endotoxin test using Limulus ES-II (Wako, Japan) was performed on the same day prior to injection.
Fibroblast cells for each patient were preserved for future use after all 3 injections were completed. Procedures for cryopreserve were similar to cell harvesting. Five cryo vials with 1 mL fibroblast cells in each were prepared and kept at 2˚C - 8˚C for 30 min, −20˚C for 30 min and overnight at −80˚C accordingly before moving to liquid nitrogen cryo tank for cell preservation.
The suspension of cultured fibroblast cells in cryo-vial was delivered to the treating physician for intradermal injection into the patient’s nasolabial fold. One ml of the cell suspension contains about 23 million fibroblast cells (range 21 to 24 million cells per mL). Each patient received a course of therapy consisting of three injections administered at an interval of 5 weeks. Theoretically number of mL (cell dosing) administered per injection varied according to length of the nasolabial fold to be treated. For this trial, 12 patients were treated with 1 mL per injection (0.5 mL for each side of the bilateral nasolabial folds) and another 7 patients were treated with 4 mL per injection.
Study visits post-injection occurred at the second week, then monthly till to month 6 and one final visit at month 12 for efficacy and safety assessments.
The primary efficacy endpoint consists of 7 independent evaluator’s assessment of the photographs of the bilateral nasolabial folds taken before treatment, at 6- and 12-month after completing treatment, on a standardized 7-point ordinal severity scale with a photoguide. An efficacious response is defined as a 2-point improvement from the baseline (pre-treatment) score on the 7-point scale in at least one treated area. The evaluators were not involved in the patients’ care, nor did they participate in any laboratory or clinical procedure.
Other efficacy endpoints are:
・ Investigator’s live assessment of the change in facial contour defects before and after treatment using the same 7-point photoguide;
・ Subject’s live assessment of their satisfaction with the change in facial contour defects before and after treatment using a 5-point scale;
・ Histological features of the healthy skin biopsy specimen compared with the features of an injected post-auricular site taken from a repeat biopsy 6-month after the injection. However, no patients consented to repeat biopsy.
Sample size was estimated based on the primary efficacy parameter which was the percent of patients who had an efficacious response to treatment. We assume this would be 75% [
Continuous variables were described by summary statistics such as mean, median, and standard deviation and categorical (nominal/ordinal) variables, by the frequencies of each category.
Ordinal regression (Proportional odds model [
In proportional odds model, the cumulative probabilities for the ordinal dependent variable, after suitable transformation (log it transform), is modelled as a linear function of covariates. The regression coefficient has interpretation as cumulative odds ratio (OR) [
The level of significance was set at 0.05. To account for cluster sampling (each patients were scored multiple times by the 7 independent evaluators), we obtained robust variance estimates using the Huber’s [
We enrolled a total of 19 patients for this study. One patient was mistakenly enrolled and treated for acne scar instead of nasolabial fold. She is excluded from analysis. All other patients had completed 6-month follow-up and are included in this analysis. All but 2 patients completed 12-month follow-up.
Baseline characteristics of these patients are shown in
The mean (SD) age of the patients was 54 years (range 26 to 70), and 94% of them were women. No patients had previous treatment for their nasolabial folds.
Eleven patients were treated with a dose of 1 mL per injection (0.5 mL each side of the nasolabial fold) while 7 patients were given a higher dose of 4 mL per injection (2 mL each side of the nasolabial fold). No local or systemic complications were reported.
Baseline characteristics | N = 18 |
---|---|
Mean age (SD), years | 54 (9) |
No. (%) male patients | 1 (5%) |
Mean body weight (kg) | 55.5 (7.5) |
No. (%) non-smoker | 18 (100) |
No. (%) without previous treatment for nasolabial fold | 18 (100) |
No patients had any post-injection adverse events (AE). AE that were specifically sought included local pain, inflammation, bleeding and systemic reaction.
The outcome of ACF treatment is summarized in
All 18 patients (100%) completed the study and were included in the analysis.
For the primary endpoint, only 4 patients (22%) had improved by 2 or more points on the 7-point scale, short of the required 45% response rate. However, fifteen patients (83%) had at least 1 point improvement on the 7-point scale at 12-month follow-up. All patients (100%) by self-assessment were satisfied with the improvement in the appearance of their nasolabial folds.
In this prospective study, we have administered autologous cultured fibroblast cells (ACF) to 18 patients for the correction of bilateral nasolabial folds. We obtained an improvement in the appearance of the nasolabial fold of at least 1 point on a 7-point scale, in about 80% of patients at 12-month follow-up as evaluated by both independent evaluators and the investigators. Investigators were more optimistic in their assessment in finding 33% of patients having had a 2-point improvement from baseline while independent evaluators found only 22% of patients having improved by as much. Patients were uniformly (100%) satisfied with the improvement in the appearance of their nasolabial folds. Our results therefore indicate that the regenerated dermis from the ACF treatment had successfully corrected the facial contour defects at 1 year after treatment.
Our results however did not compare favourably to the original ACF [
Outcome | Time on trial | Results N = 18 |
---|---|---|
Independent evaluator’s photograph assessment of severity on a 7-point ordinal scale | ||
Primary End-point No. (%) with at least 2-point improvement from baseline score | Baseline | 0 (0) |
6-month post treatment | 1 (6) | |
12-month post treatment | 4 (22) | |
No. (%) with at least 1-point improvement from baseline score | Baseline | 0 (0) |
6-month post treatment | 8 (44) | |
12-month post treatment | 15 (83) | |
No. (%) with no improvement (change from baseline 0 or worst) from baseline score | Baseline | 18 (100) |
6-month post treatment | 10 (56) | |
12-month post treatment | 6 (17) | |
Investigator’s live assessment of severity on a 7-point ordinal scale | ||
No. (%) with at least 2-point improvement from baseline score | Baseline | 0 (0) |
6-month post treatment | 6 (33) | |
12-month post treatment | 6 (33) | |
No. (%) with at least 1-point improvement from baseline score | Baseline | 0 (0) |
6-month post treatment | 8 (44) | |
12-month post treatment | 14 (78) | |
No. (%) with no improvement (change from baseline 0 or worst) from baseline score | Baseline | 18 (100) |
6-month post treatment | 10 (56) | |
12-month post treatment | 3 (17) | |
Patient’s self-assessment of satisfaction with the change in facial contour defects before and after treatment on a 5-point ordinal scale (5 very dissatisfied, 1 very satisfied) | ||
Median Score (interquartile range) | Baseline | 4 (1) |
6-month post treatment | 2 (0) | |
12-month post treatment | 2 (0) | |
No. (%) with at least 1-point improvement from baseline score | Baseline | 0 (0) |
6-month post treatment | 18 (100) | |
12-month post treatment | 18 (100) |
Variables | N | Mean change from baseline score (SD) | Cumulative OR | 95% CI | P value |
---|---|---|---|---|---|
Age group, years | |||||
<50 (ref*) | 7 | 1.38 (0.81) | 1 | - | |
50 - 59 | 7 | 1.53 (0.84) | 1.82 | (0.62, 5.38) | 0.277 |
≥60 | 4 | 1.17 (0.89) | 0.82 | (0.18, 3.78) | 0.801 |
Body weight, kg | |||||
<50 Kg (ref*) | 4 | 1.45 (0.77) | 1 | - | |
>50 Kg | 14 | 1.38 (0.87) | 0.33 | (0.077, 1.42) | 0.137 |
Baseline score | |||||
4 (ref*) | 7 | 1.10 (0.70) | 1 | - | |
5 | 10 | 1.57 (0.86) | 3.35 | (1.75, 6.43) | <0.001 |
6 | 1 | 1.55 (1.06) | 5.26 | (0.74, 37.13) | 0.096 |
Cell dose | |||||
1 mL (ref*) | 11 | 1.30 (0.80) | 1 | - | |
4 mL | 7 | 1.52 (0.91) | 1.02 | (0.46, 2.27) | 0.958 |
Duration post treatment | |||||
6 months (ref*) | 18 | 1.16 (0.81) | 1 | - | |
12 months | 18 | 1.64 (0.84) | 3.27 | (1.86, 5.70) | <0.001 |
*ref: Reference category in regression analysis.
marketed as Azficel-T (Laviv®) by Fibrocell Technologies Inc in the US. In the pivotal study on Azficel-T for variety of facial contour deformities including nasolabial folds [
In this study, we have further investigated the effect of patients’ age, duration after treatment (6 and 12 months) and cell dose on the response to ACF treatment. Older patients (age >60 years) did show a trend towards poorer response to treatment but this was not statistically significant. The longer the post-treatment follow-up, the better was the response to ACF. This is consistent with ACF being a natural cell based treatment which is slower in producing a noticeable effect compared with synthetic fillers but is capable of producing ongoing and sustained improvement. Interestingly a much larger cell dose (92 million cells) has little additional effect suggesting that the 1 mL cell dose (23 million cells) is near the optimal cell dosing. This was also the cell dose used in the Azficel-T trial [
In conclusion, we have replicated the laboratory and clinical procedures to perform ACF treatment in Malaysia. Our ACF was effective in improving the appearance of nasolabial folds in 22% of patients, and likely other facial contour defects too.
The authors thank Beijing Cell Technology Inc. for providing the cultured fibroblast cells for this research.
Lee, E.C.R., Lee, K.S., Lim, J., Yip, J., Zhang, C., Zhang, X., Bin, H. and Lim, T. (2017) Efficacy of Autologous Cultured Fibroblast Cells as a Treatment for Patients with Facial Contour Defects: A Clinical Replication Study. Journal of Cosmetics, Dermatological Sciences and Applications, 7, 306-317. https://doi.org/10.4236/jcdsa.2017.74027