Stem cell fat grafting
Stem cell fat grafting is autotransplantation of adipose-derived stem cells (ADSCs) extracted from fat-abundant donor sites (i.e. thigh or stomach) to other areas such as the face, breast, and hip to reconstruct the operative areas into desirable shapes.[1] ADSCs are multipotent stem cells found in adipose tissues, displaying similar differentiation potentials to bone marrow-derived mesenchymal stem cells (BM-MSCs).[2]
The discovery of ADSCs has brought great advances to the field of regenerative medicine and aesthetic procedures.Whilst the use of embryonic stem cells was reconsidered for ethical reasons, ADSCs got attention from plastic surgeons owing to their characteristics such as pluripotent differentiation potential, paracrine activities, immunomodulatory functions, and homing effect.[3]
Regardless of the numerous benefits, there are few side effects and oncology safety issues The rising investment in stem cell cosmetic therapy reflects the high expectation and demands especially in South Korea. Further research on the effectiveness of ADSCs grafting proposed that the aftermath of the therapy can be affected by the quality of stem cells and diet by fostering adequate conditions for stem cell growth and sufficient consumption of nutrients.[4]
History of stem cell plastic surgery
Dr.James Thomson at the University of Wisconsin first isolated human embryonic stem cells in 1998. However, due to the ethical controversies regarding embryonic stem cells, the induced pluripotent stem cells (iPSCs) were proposed as the substitute. The remaining oncological concern of iPSCs was eased by suggesting adult stem cells as the most primary resource of regenerative medicine.[5]
History of autologous fat grafting
The first isolation of mesenchymal stem cells from the bone marrow was done by Friednstein et al. in 1986 and considered as a primary clinical stem cell source. However, the painful acquisition and low cell yield limited further research. Then Zuk et al. isolated ADSCs and found it has same potentials as BM-MSCs. Although later other stem cells were identified from different parts of the human body, ADSCs was considered to be the safest as it was the easiest stem cell to isolate and did not require cell expansion. Thus ADSCs are still used as a primary source of fat transfer therapies.[6]
The concept of autologous fat grafting was first suggested in 1893. The first report described that the adipose tissue without changing its structure was implanted to the adherent scars from osteomyelitis. The result was successful and soon widely used in different fields of aesthetic procedures such as breast augmentation and rhinoplasties.[6]
In 1978, a liposuction procedure was invented to remove the excessive fat depositions. Later, Illouz found that this procedure is the ideal supplier of fat tissue and used impurified lipoaspirate as a transplant in 1983 and Fournier proposed a reinjection technique of aspirated fat.[6]
The third period starts from 1994 when S.R. Coleman introduced the Coleman technique, which uses adipose tissue for lipids cell transfer. The lipoaspirate was centrifuged to separates the stromal vascular fraction(SVF) including ADSCs from blood, tissue, fluid, and lipids.[3] Yet, the fat cell retention rate was varied from 30% to 95%. The first theory that explains graft survival is the Cell Survival Theory, which suggests that the transfer of viable adipocytes for adequate circulation enhances the survival rate and this can be done by developing the processing and injection techniques to minimize trauma.[6]
The recent theory is the Host replacement theory that retention rate after fat grafting is determined by the ADSCs replacing adipocytes, as the successful ADSCs activation and replacement of adipocytes is related to the early death of transferred adipocytes in ischemic conditions.[6]
Mechanisms
ADSCs
Fang et al. proposed that ADSCs are the most widely used due to the following three characteristics: their pluripotent differentiation potentials, paracrine activity and immunomodulatory function. ADSCs are one type of mesenchymal stem cells (MSCs), and they exhibit high similarities with BM-MSCs.[7] Hence, they are capable of multilineage differentiation into fats, cartilages, cardiac muscles, nerves, skins, and Skeletal muscles. They also tend to survive for a longer period with a higher proliferative capacity than other stem cells. ADSCs secret pro-angiogenic factors and anti-apoptotic factors like cytokines, chemokines, growth factors, mRNAs, and microRNAs. Then, they act on different systems where they were transplanted and regenerate cells in these transplanted systems. Moreover, as ADSCs resemble BM-MSCs, they have immunosuppressive characteristics, suppressing both innate and adaptive immune systems. However, their capacity is even stronger than BM-MSCs by secretion of immunosuppressive factors such as IL-6 and TGF-B. Additionally, they perform as immune tolerators to suppress lymphocyte proliferation; such property suggests the possibility of ADSCs for xenotransplantation.[8]
Homing effect
The homing effect refers to the engraftment of ADSCs to bone marrow endothelium owing to the arrest of ADSCs within the vasculature of a tissue. ADSCs are engrafted to the bone marrow endothelium, as they circulate across the endothelium and adhesion interactions are activated to the bone marrow endothelium. Thus, such engraftment increases the probability of long-term survival of transferred fats. The homing effect follows three main processes: rolling, adhesion, and transmigration. During the rolling, ADSCs migrate and interacts with vascular endothelial cells in bone marrow in shear-resistant and low-affinity manners. As ADSCs adhere to bone marrow endothelium, MSCs express several different molecules that increase the adhesion such as CD44 isoforms and integrins. As ADSCs transmigrate through vessels in bone marrow, interaction and signaling between stromal-derived chemokine factor -1 (SDF-1) and receptor CXCR4 is the most crucial process.[9][10]
Isolation or expansion from fats
Mechanical+Enzymatic(ME) and mechanical methods are the most common isolation methods, although there is no standard method.[11] Accordingly, Dr. Glass and Ferretti proposed one of the ME methods which is to apply tumescent-assisted liposuction using a mechanical or ultrasound-assisted liposuction cannula. Through liposuction, the fat sample is digested by enzymatic activities of collagenase or trypsin in Dulbecco's modified Eagle's medium (DMEM). The resultant tissue suspension undergoes incubation and agitation at around 37 °C and is filtered through a strainer to remove unnecessary debris. The cell pallet left after centrifugation is called SVF. The SVF is seeded on the plate, after the second suspension with bovine calf serum, 1% penicillin or streptomycin, and L-glutamine. The adherent properties of ADSCs on the plate allow isolation of ADSCs.[12] However, due to the inconvenience of isolating the pure ADSCs, a cell-assisted lipo-transfer (CAL) is more commonly used. CAL transforms poor ADSCs into enriched ADSCs by mixing isolate SVF and aspirated fat.[13] The efficacy of CAL was proven by the increased survival rate of autologous breast augmentation when introduced around 270ml for each breast.[14]
Complications and safety
Breast implant
Around 1.5 million women have breast implant surgeries per year.[15] Yet the side effects of the fat transplant can be severe and cause irreversible damage to the patient's body. The most well-known side effects are foreign body sensation, calcification, fat cell necrosis, capsular construction, rupture, cysts and some fat cells leaving the implanted area.
In most cases, calcification and cysts are the biggest threat of breast augmentation surgery. Fat stem cells failed to pick up a new blood supply will die and be removed from the body by immune cells. However, when this clearing process miss removing dead cells the cluster will lead to calcification and cysts formation. These are visible on the breast as lump sometimes and are more dangerous when these un-picked up dead cells are detected as cancer cells which disturbs accurate diagnosis of breast cancer. The calcified tissue will be diagnosed as a 'benign' cancer and not cause any harm. However, if the tissue is severely damaged the entire breast needs to be removed. Once a patient is diagnosed with calcification of breast implant, regular mammograms should be done to monitor the possible cancer development.[16]
Facial fat transfer
Gornitsky et al. from McGill University conducted a systematic review of 4577 patients who have received the facial fat transfer. The most prevalent side effects were reported like the following: asymmetry, skin irregularities, hypertrophy, prolonged edema, fat necrosis and such.[17]
Oncology safety
The homing effect may have advantages in increasing the long-term survival of transferred fat, but concerns remain for patients with post-oncologic history, specifically breast cancer. It is more alarming since breast tumors are closely located with adipose tissue, as they develop a favorable microenvironment for cancer progression through homing and migration.[18] There are cancer-associated adipocytes (CAAs) crucial for metastasis and the progression of tumors. Under normal conditions, the adipocytes are mature and they do not differentiate. However, when ADSCs migrate and circulate in blood vessels by homing properties can result in the progression of tumor growth. Furthermore, the properties of migratory cells also promote tumor growth by secretion of trophic factors such as adipokines, including FGF, ILs and IGF-binding proteins. This increases vascularisation as such oncogenic properties are unusual for other BM-MSCs or lung-derived MSDCs.[19]
Application and marketing
Stem cell market
The stem cell market has grown largely along with the increasing awareness of stem cells in regenerative medicine. The Google web search big data analysis showed that the terms “Stem cell facelift” had 197,000 outcomes and “stem cell breast augmentation" had approximately 302,000 outcomes according to the American Society of Plastic Surgeons.[20]
With the rising interest in stem cell cosmetic therapy, this figure demonstrates the content analysis on the 50 clinical websites that appeared on the Google search platform for “stem cell therapy”, “treatment” or “stem cell facelift” in November 2013. The result showed that (A) 90% of the clinics use Autologous adult stem cell. (B) 71% of clinics obtained stem cells were from patient fat. (C) 90% of procedures delivered cells through subcutaneous methods. (D) facial-anti ageing treatment was advertised the most in “stem cell” treatments as well as “stem cell breast augmentation” therapies.[21]
Case study: South Korea
The International Association of Aesthetic Plastic Surgery (ISAPS), announced the Korean plastic surgery market is estimated to be about the scale of $440 million as of 2017. It is a 1/4 of the world market, and the number of plastic surgeries per year ranked the first (13.5 per 1000 population per year). Korean stem cell markets formed a scale of $1.1 billion in 2016 and they are expected to grow to 26.67% annually by 2025 ($9.5 billion).[22][23]
In 2017 the government invested in the bio sector for the highest proportion for new drug development (13%), and only 4% on stem cells ($112 million). CartistemTM, Inc. Medipost published successfully developed stem cell-based degenerative knee cartilage therapy and has achieved more than 10 billion sales since 2017.[22][23]
Legal issues
Behind the large stem cell cosmetic therapy market size of South Korea, non-specialists practice without a licence in some clinics. According to the National Statistical Office data, the number of plastic surgeons is 1,924 in 2018, and the Korean Plastic Surgery Association estimates that non-specialists in cosmetic surgery will be about 10 times that of specialists.
Dr Shin mentioned, "There have been similar surgeries that advocate stem cell breast plastic surgery recently. When receiving stem cell breast surgery, patients need to check whether the doctor has officially proved and whether the hospital has stem cell researchers and high-quality equipment."[24]
Diet after stem cell therapy
Studies have shown that diet is closely related to stem cell proliferation and performance. Among numerous chemicals that affect the entire stem cell differentiation and settlement process, it is shown that taking extra supplements such as below can help stem cells to function better.
- Vitamins such as A, B3 and C are effective targets in vitamin-dependent pathways in stem cell manipulation. Especially vitamin C stimulates proliferation to produce bone marrow stem cells. Vitamin D assist stem cells during differentiation by stimulating the activities in embryonic stem cells and iPSCs and regulates embryonic hematopoietic stem and progenitor cell production and human umbilical cord stem cell development.[25][26]
- Glucosamine and Chondroitin improve stem cell function by promoting adequate growth of progenitors of proliferative tissue lineages.[27][28][4]
- Glycemic index and calorie restriction by cutting carbohydrates and sugar enhance stem cell activity.[29][30] At mitochondrial level, the MSCs utilise energy more efficiently when the glycemic index was restricted to low by increasing oxygen consumption of MSCs and exhibiting anti-ageing abilities, while their differentiation abilities remain unaffected.[31]
References
- Bellini, Elisa; Grieco, Michele; Raposio, Edoardo (10 December 2017). "The science behind autologous fat grafting". Annals of Medicine and Surgery. 24: 65–73. doi:10.1016/j.amsu.2017.11.001. PMC 5694962. PMID 29188051.
- Rochette, Luc; Mazini, Loubna; Malka, Gabriel; Zeller, Marianne; Cottin, Yves; Vergely, Catherine (4 December 2020). "The Crosstalk of Adipose-Derived Stem Cells (ADSC), Oxidative Stress, and Inflammation in Protective and Adaptive Responses". International Journal of Molecular Sciences. 21 (23): 9262. doi:10.3390/ijms21239262. PMC 7730805. PMID 33291664.
- Simonacci, F; Bertozzi, N; Grieco, MP; Grignaffini, E; Raposio, E (August 2017). "Procedure, applications, and outcomes of autologous fat grafting". Annals of Medicine and Surgery. 20: 49–60. doi:10.1016/j.amsu.2017.06.059. PMC 5491488. PMID 28702187.
- Team, The Biotics Education. "7 Ways to Promote Stem Cell Proliferation". blog.bioticsresearch.com.
- Evans, Gregory R. D.; Widgerow, Alan D. (30 May 2020). "Stem cells and tissue engineering in plastic surgery: an update". Plastic and Aesthetic Research. 7. doi:10.20517/2347-9264.2019.53. ISSN 2347-9264.
- Varghese, Jajini; Mosahebi, Afshin (1 July 2017). "Historical Overview of Stem Cell Biology and Fat Grafting". Aesthetic Surgery Journal. 37 (suppl_3): S1–S3. doi:10.1093/asj/sjw262. PMID 29025211.
- Mazini, Loubna; Rochette, Luc; Amine, Mohamed; Malka, Gabriel (22 May 2019). "Regenerative Capacity of Adipose Derived Stem Cells (ADSCs), Comparison with Mesenchymal Stem Cells (MSCs)". International Journal of Molecular Sciences. 20 (10): 2523. doi:10.3390/ijms20102523. PMC 6566837. PMID 31121953.
- Fang, Jun; Chen, Feng; Liu, Dong; Gu, Feiying; Wang, Yuezhen (6 January 2021). "Adipose tissue-derived stem cells in breast reconstruction: a brief review on biology and translation". Stem Cell Research & Therapy. 12 (1): 8. doi:10.1186/s13287-020-01955-6. PMC 7789635. PMID 33407902.
- Zhao, Yong; Zhang, Haiyang (1 July 2016). "Update on the mechanisms of homing of adipose tissue-derived stem cells". Cytotherapy. 18 (7): 816–827. doi:10.1016/j.jcyt.2016.04.008. PMID 27260205.
- Liesveld, Jane L.; Sharma, Naman; Aljitawi, Omar S. (2020). "Stem cell homing: From physiology to therapeutics". Stem Cells. 38 (10): 1241–1253. doi:10.1002/stem.3242. PMID 32526037.
- Raposio, Edoardo; Simonacci, Francesco; Perrotta, Rosario E. (8 July 2017). "Adipose-derived stem cells: Comparison between two methods of isolation for clinical applications". Annals of Medicine and Surgery. 20: 87–91. doi:10.1016/j.amsu.2017.07.018. ISSN 2049-0801. PMC 5508488. PMID 28736612.
- Glass, Graeme Ewan; Ferretti, Patrizia (14 March 2019). "Adipose-Derived Stem Cells in Aesthetic Surgery". Aesthetic Surgery Journal. 39 (4): 423–438. doi:10.1093/asj/sjy160. PMID 29982396.
- Wang, Yu; Wu, Yanfei (19 October 2017). "Assessment of the clinical efficacy of cell-assisted lipotransfer and conventional fat graft: a meta-analysis based on case-control studies". Journal of Orthopaedic Surgery and Research. 12 (1): 155. doi:10.1186/s13018-017-0645-5. ISSN 1749-799X. PMC 5649090. PMID 29052508.
- Mazini, Loubna; Ezzoubi, Mohamed; Malka, Gabriel (4 January 2021). "Overview of current adipose-derived stem cell (ADSCs) processing involved in therapeutic advancements: flow chart and regulation updates before and after COVID-19". Stem Cell Research & Therapy. 12 (1): 1. doi:10.1186/s13287-020-02006-w. PMC 7781178. PMID 33397467.
- Alotaibi, Shaikha; Hamadani, Mehdi; Al-Mansour, Mubarak; Aljurf, Mahmoud (1 March 2021). "Breast Implant-associated Anaplastic Large Cell Lymphoma". Clinical Lymphoma, Myeloma & Leukemia. 21 (3): e272–e276. doi:10.1016/j.clml.2020.12.005. PMID 33384263.
- Horton, Karen. "Why not augment the breasts with your own fat? A warning!". www.drkarenhorton.com. Dr Karen M. Horton.
- Gornitsky, Jordan; Viezel-Mathieu, Alex; Alnaif, Nayif; Azzi, Alain; Gilardino, Mirko (1 March 2019). "A systematic review of the effectiveness and complications of fat grafting in the facial region". JPRAS Open. 19: 87–97. doi:10.1016/j.jpra.2018.12.004. ISSN 2352-5878. PMC 7061561. PMID 32158860.
- O’Halloran, Niamh; Courtney, Donald; Kerin, Michael J; Lowery, Aoife J (1 January 2017). "Adipose-Derived Stem Cells in Novel Approaches to Breast Reconstruction: Their Suitability for Tissue Engineering and Oncological Safety". Breast Cancer: Basic and Clinical Research. 11: 117822341772677. doi:10.1177/1178223417726777. PMC 5562338. PMID 29104428.
- Scioli, Maria Giovanna; Storti, Gabriele; D’Amico, Federico; Gentile, Pietro; Kim, Bong-Sung; Cervelli, Valerio; Orlandi, Augusto (4 July 2019). "Adipose-Derived Stem Cells in Cancer Progression: New Perspectives and Opportunities". International Journal of Molecular Sciences. 20 (13): 3296. doi:10.3390/ijms20133296. PMC 6651808. PMID 31277510.
- The American Society of Plastic Surgeons. "Joint ASPS & ASAPS Position Statement: Stem Cells and Fat Grafting" (PDF). Plastic surgery.
- McArdle, Adrian; Senarath-Yapa, Kshemendra; Walmsley, Graham G.; Hu, Michael; Atashroo, David A.; Tevlin, Ruth; Zielins, Elizabeth; Gurtner, Geoffrey C.; Wan, Derrick C.; Longaker, Michael T. (2014). "The Role of Stem Cells in Aesthetic Surgery: Fact or Fiction?". Plastic and Reconstructive Surgery. 134 (2): 193–200. doi:10.1097/PRS.0000000000000404. ISSN 0032-1052. PMC 4447486. PMID 24732654.
- Kim, Kyung Ae (1 November 2019). "연평균 17% 성장한다는데…'줄기세포' 연구 홀대?". 히트뉴스 (in Korean). HitNews.
- "생명공학정책연구센터". www.bioin.or.kr.
- Chung, Sim Kyo (December 29, 2020). "밋밋한 가슴의 유학생, 줄기세포 가슴 성형 위해 귀국한 이유는 :: 중앙일보헬스미디어". jhealthmedia.joins.com.
- Godoy-Parejo, Carlos; Deng, Chunhao; Zhang, Yumeng; Liu, Weiwei; Chen, Guokai (May 2020). "Roles of vitamins in stem cells". Cellular and Molecular Life Sciences. 77 (9): 1771–1791. doi:10.1007/s00018-019-03352-6. PMID 31676963. S2CID 207828217.
- Cortes, Mauricio; Chen, Michael; Stachura, David; Liu, Sarah; Kwan, Wanda; Wright, Francis; Vo, Linda; Theodore, Lindsay; Esain, Virginie; Frost, Isaura; Schlaeger, Thorsten; Goessling, Wolfram; Daley, George; North, Trista (4 October 2016). "Developmental Vitamin D Availability Impacts Hematopoietic Stem Cell Production". Cell Reports. 17 (2): 458–468. doi:10.1016/j.celrep.2016.09.012. ISSN 2211-1247. PMC 5338633. PMID 27705794.
- Jung, Jin Hyuk; Iwabuchi, Kumiko; Yang, Zhihong; Loeken, Mary R. (17 June 2016). "Embryonic Stem Cell Proliferation Stimulated By Altered Anabolic Metabolism From Glucose Transporter 2-Transported Glucosamine". Scientific Reports. 6 (1): 28452. Bibcode:2016NatSR...628452J. doi:10.1038/srep28452. PMC 4911601. PMID 27311888.
- Mehrabani, D; Mojtahed Jaberi, F; Zakerinia, M; Hadianfard, MJ; Jalli, R; Tanideh, N; Zare, S (May 2016). "The Healing Effect of Bone Marrow-Derived Stem Cells in Knee Osteoarthritis: A Case Report". World Journal of Plastic Surgery. 5 (2): 168–74. PMC 5003953. PMID 27579273.
- "Diet & Blood Sugar Levels The Effect on Stem Cells". Regen America. 2 January 2018.
- He, Jingjing; Kong, Desheng; Yang, Zhifen; Guo, Ruiyun; Amponsah, Asiamah Ernest; Feng, Baofeng; Zhang, Xiaolin; Zhang, Wei; Liu, Aijing; Ma, Jun; O’Brien, Timothy; Cui, Huixian (11 March 2021). "Clinical efficacy on glycemic control and safety of mesenchymal stem cells in patients with diabetes mellitus: Systematic review and meta-analysis of RCT data". PLOS ONE. 16 (3): e0247662. Bibcode:2021PLoSO..1647662H. doi:10.1371/journal.pone.0247662. ISSN 1932-6203. PMC 7951834. PMID 33705413.
- Lo, Ting; Ho, Jennifer H.; Yang, Muh-Hwa; Lee, Oscar K. (1 July 2011). "Glucose Reduction Prevents Replicative Senescence and Increases Mitochondrial Respiration in Human Mesenchymal Stem Cells". Cell Transplantation. 20 (6): 813–826. doi:10.3727/096368910X539100. ISSN 1555-3892. PMID 21054932. S2CID 30722685.