Organoid > Volume 2; 2022 > Article
Park, Byeun, and Choi: Progress, prospects, and limitations of organoid technology

Abstract

Organoids are mini-organs generated through in vitro 3-dimensional culture that mimic some of the structural and physiological functions of real organs. In recent research, various organoids have been derived from pluripotent stem cells or multipotent organ-specific adult stem cells in vitro and have been used in regenerative medicine, disease modeling, precision medicine, toxicology studies, and drug discovery. However, research on reproduction-related organoids has not been comprehensive, and some limitations need to be addressed for culturing these organoids. In this review, we discuss the historical advances, major recent developments, limitations, and potential of organoid culture, including human reproductive organoids.

Introduction

Embryonic stem cells were first isolated in 1981 from mouse blastocysts [1] and subsequently from human blastocysts in 1998 [2]. Stem cells have been recently used in regenerative medicine owing to their ability to differentiate into all types of cells and maintain tissue homeostasis in adults. However, most stem cells are cultured in a 2-dimensional (2D) non-physiological environment. These cultured stem cells differ greatly in their expression of genes and proteins from those cultured in a 3-dimensional (3D) environment [3]. Since various cells form a 3D network with the extracellular matrix (ECM) in vivo that affects their growth, proliferation, differentiation, and apoptosis [4,5], creating a 3D environment to mimic in vivo conditions while culturing stem cells in vitro is important. Many studies have successfully cultured stem cells in a 3D environment mimicking the in vivo ECM using various biomaterials.
With continuous efforts in stem cell research for the development of a 3D culture system, Sato et al. [6] finally generated intestinal organoids from adult intestinal stem cells using a Matrigel-based 3D culture method. When stem cells are cultured in a 3D environment with ECM-containing Matrigel in vitro, they self-organize into tiny 3D organoid structures with similar features and functionality to real organs. Several organoids, such as testis [7], fallopian tube [8], endometrium [9], brain [10], gut [11], and liver [12], have been cultured either from directly sourced tissue-resident adult stem cells (ASCs) from biopsy samples or pluripotent stem cells (PSCs). These organoids have been successfully used for many clinical applications (Fig. 1). However, research on reproduction-related organoids has not been comprehensive, as certain limitations need to be addressed for culturing these organoids. Here, we highlight the progress and briefly review the applications and current limitations of various organoids, including reproduction-related organoids, in biomedical research.
Ethics statement: This study was a literature review of previously published studies and was therefore exempt from institutional review board approval.

Progress in organoid research

1. Testis organoids

Approximately 7% of men are infertile [13]. The causes of male-factor infertility are diverse and complex. Chromosomal and genetic diseases (e.g., Klinefelter syndrome, Y chromosome deletions, trisomy 21), exposure to environmental chemicals, radiation, cancer, and chemotherapeutic agents can lead to infertility [14] due to their adverse effects on sperm function and quality in the testis. Despite the development of various organoids over the past decade, testicular organoids have received increasing attention. Testicular organoids are similar to the testes in structure and function and serve as highly useful model systems to study male infertility and the mechanism of germ cell niche, germ cell functions, and the interaction between germ cells for spermatogenesis [15,16]. In addition, testis organoids can be used as high-throughput drug and toxicity screening tools that can replace animal experiments owing to ethical issues [17].

2. Fallopian organoids

The fallopian tubes play an important role in the female reproductive system as sites for gamete and embryo transport, fertilization, sperm reservoir, and embryonic development [18]. Improper functioning of fallopian tubes can cause infertility in females. Fallopian tube organoids were derived from the female reproductive system by isolating cells using enzymatic digestion and culturing the cells by embedding them in Matrigel [8]. These organoids were able to maintain the structure and functionality of fallopian tubes, as evident from their ability to respond to female hormones (estrogen and progesterone), the presence of cilia and secretions, and folding of the epithelium [19].

3. Endometrium organoids

The human endometrium is a complex multicellular and dynamic tissue that undergoes the menstrual cycle in response to female steroid hormones [20]. During pregnancy, the blastocyst first implants at the functional layer of the endometrium, which is the outermost layer of the uterus [21]. Thus, the endometrium is essential for female reproduction in mammals, and defects in its function or cyclic remodeling can cause implantation failure, pregnancy disorders, endometriosis, or endometrial cancers [22]. Endometriosis is a chronic inflammatory disease that causes pelvic pain and excessive bleeding due to the proliferation of endometrial tissue outside the uterus [23]. Endometrial or uterine cancer is the 4th most common gynecological malignancy in women in the United States [24]. Although many studies have investigated endometrial cancer, little is known about the cellular and molecular mechanisms behind its pathology. The main limitation of these studies was the lack of an accurate research model system, as mouse models do not physiologically resemble human endometrial development and function in vivo [9]. For instance, the process of endometrial decidualization varies between mice and humans [25]. Therefore, results obtained from animal models cannot be directly translated to humans. To address these obstacles, human endometrial organoids were derived from primary endometrial cells to mimic the human endometrium. Endometrial organoids have been shown to recapitulate the morphology and function of the adult human endometrium in response to estrogen and progesterone [26]. Endometrial organoids can be used not only to elucidate the mechanism of pathological diseases, such as endometriosis and endometrial cancer, but also to contribute to the development of therapeutic agents.

4. Brain organoids

The human brain is divided into three regions—the forebrain, midbrain, and hindbrain—which are primarily composed of neurons and glial cells [27]. However, the function, development, and pathology of many disorders of the human brain are not yet fully understood, and it is difficult to study their mechanisms in vivo, as the human brain is the central system that regulates the body and cannot be cultured outside the body. Therefore, an in vitro model to understand human brain development and disorders is needed. Efforts have been made toward 2D culturing of brain tissues or organs by differentiating neural stem cells and PSCs into neurons; however, the structure and function of the brain could not be recapitulated [28]. Watanabe et al. [29] developed a 3D culture method to generate different brain regions from mouse or human PSCs. Brain organoids were then generated in vitro, as tiny organs that could recapitulate many features of the brain. In 2013, 3D cerebral organoids were generated in vitro that could grow up to a few millimeters from various brain tissues such as the retina, dorsal cortex, ventral forebrain, midbrain-hindbrain boundary, choroid plexus, and hippocampus [30]. In addition, organoids from specific brain regions, such as the midbrain and hippocampus, were established through the organoid culture system [31]. Brain organoids provide an excellent research platform for understanding the development of various disorders of the human brain, such as schizophrenia and Alzheimer disease.

5. Gut organoids

In 2009, Sato et al. [6] first established intestinal organoids derived from leucine-rich repeat-containing G protein-coupled receptor 5 (Lgr5)+ stem cells using a Matrigel 3D culture system. These organoids form crypt-villus structures with cellular heterogeneity to mimic the physiology and organization of the actual intestine. When transplanted into mice, intestinal organoids showed long-term survival, and their regenerative ability was also confirmed [32]. Hindgut spheroids were cultured from human PSCs in Matrigel to promote the maturation of intestinal organoids. Although intestinal organoids are derived from PSCs, gastric and lingual organoids—derived from parts of the digestive tract—are generated from adult pyloric stem cells and adult tongue epithelium, respectively [33]. Organoid technology can be used as a powerful tool to study gastrointestinal diseases, intestine-microbe interactions, and colorectal cancer.

6. Liver organoids

The liver is a critical organ that performs various functions such as detoxification, protein synthesis, and the production of bile, which is necessary for digestion [34]. To conduct studies on liver function and regeneration, liver organoids resembling the adult liver in various species were generated from induced PSCs, hepatoblasts, and adult tissue-derived cells [35,36]. Liver organoids can be used as in vitro culture models to replace animal models for studying drug toxicity, metabolism, personalized medicine, and regenerative medicine.

Current limitations in organoid research

Various organoids have been established from the stem or progenitor cells to recapitulate the cellular complexity of actual organs in vitro. Most organoids are cultured in Matrigel, which is derived from the secretion of Engelbreth-Holm-Swarm mouse sarcoma cells and is rich in ECM proteins, including laminin, collagen IV, heparan sulfate proteoglycan, nidogen/entactin, and other undefined factors [37]. However, these factors make it difficult to elucidate the precise structure and function of organoids cultured in Matrigel. In addition, the murine origin of Matrigel impedes organoid use for human clinical transplantation. Therefore, to overcome these limitations, organoid culture systems have been developed using a wide range of naturally derived biomaterials (collagen, alginate, fibronectin, laminin, hyaluronic acid, and alginate-chitosan mixtures) and synthetic materials (polyethylene glycol and nanocellulose) [38].
Blood vessels constitute the circulatory system of the body. Blood constantly flows through the blood vessels, ensuring cell survival by a constant exchange of nutrients, oxygen, and waste [39]. From the perspective of cell culture, the human body is dynamic. However, organoids are cultured through static methods rather than the dynamic environment of blood vessels in the body. To bypass this limitation, a microfluidic chip platform has been developed to culture organoids [40]. It can constantly carry oxygen, nutrients, and waste using a pump connected to a chip-like blood vessel with embedded organoids. Several microfluidic “organoids-on-chips” mimicking the in vivo physiology of specific organs have been designed, with tremendous implications in organoid research [41,42].
Organoids derived from PSCs and tissue-specific stem cells in vitro are a few millimeters in size, unlike in vivo organs; therefore, they are still insufficient for clinical organ transplantation [43]. However, convergence research in the fields of stem cell biology, developmental biology, bioengineering, biomaterials, tissue engineering, and microfluidics can address this problem in the future.
Organs in the body comprise different kinds of cells, including immune cells, vascular cells, fibroblasts, and microbes [44-46]. These cells all interact with each other to perform a variety of organ functions. However, organoids are currently derived from only one stem cell type. Therefore, to establish a physiological replica of human organs in vitro, a co-culture system between organoids and different cell types is required.

Conclusion

In this review, we summarized the progress, applications, and limitations of various organoids. Organoids are mini-organs cultured in vitro that resemble their organs of origin in terms of functions and characteristics. Various organoids aiming to replicate organs such as the brain, gut, liver, testis, uterus, fallopian tube, and endometrium have been derived from PSCs and ASCs for use in a variety of applications, including organ development models, disease modeling, drug development, regenerative medicine, precision medicine, and transplantation. Although organoid technology has rapidly expanded in recent years, its applications remain at the proof-of-principle level. The convergence of organoid research with stem cell biology, biomaterials research, tissue engineering, and microfluidics would make it possible to overcome several limitations of current organoid technology and to advance its implementation in preclinical and clinical research.

NOTES

Conflict of interest

No potential conflict of interest relevant to this article was reported.

Funding

This research was supported by a 2020 Yeungnam University Research Grant (220A580070).

Author contributions

Conceptualization: JHP, DGB, JKC; Data curation: JHP, JKC; Formal analysis: JHP, JKC; Investigation: JHP, DGB, JKC; Project administration: JKC; Resources: JHP, DGB; Supervision: JKC; Writing-original draft: JHP, JKC; Writing-review & editing: JHP, JKC.

Data availability

Please contact the corresponding author for data availability.

Fig. 1.
Derivation and application of various organoids from induced pluripotent stem cells (iPSCs) or adult stem cells.
organoid-2022-2-e9f1.jpg

References

1. Evans MJ, Kaufman MH. Establishment in culture of pluripotential cells from mouse embryos. Nature 1981;292:154-6.
crossref pmid pdf
2. Thomson JA, Itskovitz-Eldor J, Shapiro SS, Waknitz MA, Swiergiel JJ, Marshall VS, et al. Embryonic stem cell lines derived from human blastocysts. Science 1998;282:1145-7.
crossref pmid
3. Zhou Y, Chen H, Li H, Wu Y. 3D culture increases pluripotent gene expression in mesenchymal stem cells through relaxation of cytoskeleton tension. J Cell Mol Med 2017;21:1073-84.
crossref pmid pmc
4. Winkler J, Abisoye-Ogunniyan A, Metcalf KJ, Werb Z. Concepts of extracellular matrix remodelling in tumour progression and metastasis. Nat Commun 2020;11:5120.
crossref pmid pmc pdf
5. Kim SH, Turnbull J, Guimond S. Extracellular matrix and cell signalling: the dynamic cooperation of integrin, proteoglycan and growth factor receptor. J Endocrinol 2011;209:139-51.
crossref pmid
6. Sato T, Vries RG, Snippert HJ, van de Wetering M, Barker N, Stange DE, et al. Single Lgr5 stem cells build crypt-villus structures in vitro without a mesenchymal niche. Nature 2009;459:262-5.
crossref pmid pdf
7. Sakib S, Uchida A, Valenzuela-Leon P, Yu Y, Valli-Pulaski H, Orwig K, et al. Formation of organotypic testicular organoids in microwell culture†. Biol Reprod 2019;100:1648-60.
crossref pmid pmc pdf
8. Kessler M, Hoffmann K, Brinkmann V, Thieck O, Jackisch S, Toelle B, et al. The Notch and Wnt pathways regulate stemness and differentiation in human fallopian tube organoids. Nat Commun 2015;6:8989.
crossref pmid pdf
9. Turco MY, Gardner L, Hughes J, Cindrova-Davies T, Gomez MJ, Farrell L, et al. Long-term, hormone-responsive organoid cultures of human endometrium in a chemically defined medium. Nat Cell Biol 2017;19:568-77.
crossref pmid pmc pdf
10. Wang Z, Wang SN, Xu TY, Miao ZW, Su DF, Miao CY. Organoid technology for brain and therapeutics research. CNS Neurosci Ther 2017;23:771-8.
crossref pmid pmc
11. Almeqdadi M, Mana MD, Roper J, Yilmaz ÖH. Gut organoids: mini-tissues in culture to study intestinal physiology and disease. Am J Physiol Cell Physiol 2019;317:C405-19.
crossref pmid pmc
12. Prior N, Inacio P, Huch M. Liver organoids: from basic research to therapeutic applications. Gut 2019;68:2228-37.
crossref pmid
13. Krausz C. Male infertility: pathogenesis and clinical diagnosis. Best Pract Res Clin Endocrinol Metab 2011;25:271-85.
crossref pmid
14. Williams DH. Sperm banking and the cancer patient. Ther Adv Urol 2010;2:19-34.
crossref pmid pmc
15. Richer G, Baert Y, Goossens E. In-vitro spermatogenesis through testis modelling: toward the generation of testicular organoids. Andrology 2020;8:879-91.
crossref pmid pmc
16. Alves-Lopes JP, Stukenborg JB. Testicular organoids: a new model to study the testicular microenvironment in vitro? Hum Reprod Update 2018;24:176-91.
crossref pmid pdf
17. Kanbar M, Vermeulen M, Wyns C. Organoids as tools to investigate the molecular mechanisms of male infertility and its treatments. Reproduction 2021;161:R103-12.
crossref pmid
18. Brüssow KP, Rátky J, Rodriguez-Martinez H. Fertilization and early embryonic development in the porcine fallopian tube. Reprod Domest Anim 2008;43 Suppl 2:245-51.
crossref pmid
19. Liu X, Chen B, Chen L, Ren WT, Liu J, Wang G, et al. U-shape suppressive effect of phenol red on the epileptiform burst activity via activation of estrogen receptors in primary hippocampal culture. PLoS One 2013;8:e60189.
crossref pmid pmc
20. Gellersen B, Brosens JJ. Cyclic decidualization of the human endometrium in reproductive health and failure. Endocr Rev 2014;35:851-905.
crossref pmid pdf
21. Kim SM, Kim JS. A review of mechanisms of implantation. Dev Reprod 2017;21:351-9.
crossref pmid pmc
22. Alzamil L, Nikolakopoulou K, Turco MY. Organoid systems to study the human female reproductive tract and pregnancy. Cell Death Differ 2021;28:35-51.
crossref pmid pdf
23. Smolarz B, Szyłło K, Romanowicz H. Endometriosis: epidemiology, classification, pathogenesis, treatment and genetics (review of literature). Int J Mol Sci 2021;22:10554.
crossref pmid pmc
24. Brüggmann D, Ouassou K, Klingelhöfer D, Bohlmann MK, Jaque J, Groneberg DA. Endometrial cancer: mapping the global landscape of research. J Transl Med 2020;18:386.
crossref pmid pmc pdf
25. Zhao M, Zhang WQ, Liu JL. A study on regional differences in decidualization of the mouse uterus. Reproduction 2017;153:645-53.
crossref pmid
26. Song Y, Fazleabas AT. Endometrial organoids: a rising star for research on endometrial development and associated diseases. Reprod Sci 2021;28:1626-36.
crossref pmid pdf
27. Shankaran A, Prasad K, Chaudhari S, Brand A, Satyamoorthy K. Advances in development and application of human organoids. 3 Biotech 2021;11:257.
crossref pmid pmc pdf
28. Hong YJ, Do JT. Neural lineage differentiation from pluripotent stem cells to mimic human brain tissues. Front Bioeng Biotechnol 2019;7:400.
crossref pmid pmc
29. Watanabe K, Kamiya D, Nishiyama A, Katayama T, Nozaki S, Kawasaki H, et al. Directed differentiation of telencephalic precursors from embryonic stem cells. Nat Neurosci 2005;8:288-96.
crossref pmid pdf
30. Lancaster MA, Renner M, Martin CA, Wenzel D, Bicknell LS, Hurles ME, et al. Cerebral organoids model human brain development and microcephaly. Nature 2013;501:373-9.
crossref pmid pdf
31. Corrò C, Novellasdemunt L, Li V. A brief history of organoids. Am J Physiol Cell Physiol 2020;319:C151-65.
crossref pmid pmc
32. Spence JR, Mayhew CN, Rankin SA, Kuhar MF, Vallance JE, Tolle K, et al. Directed differentiation of human pluripotent stem cells into intestinal tissue in vitro. Nature 2011;470:105-9.
crossref pmid pdf
33. Bartfeld S, Clevers H. Organoids as model for infectious diseases: culture of human and murine stomach organoids and microinjection of Helicobacter pylori. J Vis Exp 2015;105:53359.
crossref
34. Harrison SP, Baumgarten SF, Verma R, Lunov O, Dejneka A, Sullivan GJ. Liver organoids: recent developments, limitations and potential. Front Med (Lausanne) 2021;8:574047.
crossref pmid pmc
35. Zaret KS. Regulatory phases of early liver development: paradigms of organogenesis. Nat Rev Genet 2002;3:499-512.
crossref pmid pdf
36. Timpl R, Fujiwara S, Dziadek M, Aumailley M, Weber S, Engel J. Laminin, proteoglycan, nidogen and collagen IV: structural models and molecular interactions. Ciba Found Symp 1984;108:25-43.
crossref pmid
37. Kozlowski MT, Crook CJ, Ku HT. Towards organoid culture without Matrigel. Commun Biol 2021;4:1387.
crossref pmid pmc pdf
38. Zhao Z, Vizetto-Duarte C, Moay ZK, Setyawati MI, Rakshit M, Kathawala MH, et al. Composite hydrogels in three-dimensional in vitro models. Front Bioeng Biotechnol 2020;8:611.
crossref pmid pmc
39. Fleischer S, Tavakol DN, Vunjak-Novakovic G. From arteries to capillaries: approaches to engineering human vasculature. Adv Funct Mater 2020;30:1910811.
crossref pmid pmc
40. Kim J, Koo BK, Knoblich JA. Human organoids: model systems for human biology and medicine. Nat Rev Mol Cell Biol 2020;21:571-84.
crossref pmid pmc pdf
41. Yu F, Hunziker W, Choudhury D. Engineering microfluidic organoid-on-a-chip platforms. Micromachines (Basel) 2019;10:165.
crossref pmid pmc
42. Charelli LE, Ferreira J, Naveira-Cotta CP, Balbino TA. Engineering mechanobiology through organoids-on-chip: a strategy to boost therapeutics. J Tissue Eng Regen Med 2021;15:883-99.
crossref pmid
43. Takebe T, Wells JM. Organoids by design. Science 2019;364:956-9.
crossref pmid pmc
44. Yuki K, Cheng N, Nakano M, Kuo CJ. Organoid models of tumor immunology. Trends Immunol 2020;41:652-64.
crossref pmid pmc
45. Hentschel V, Seufferlein T, Armacki M. Intestinal organoids in coculture: redefining the boundaries of gut mucosa ex vivo modeling. Am J Physiol Gastrointest Liver Physiol 2021;321:G693-704.
crossref pmid
46. Shirure VS, Hughes C, George SC. Engineering vascularized organoid-on-a-chip models. Annu Rev Biomed Eng 2021;23:141-67.
crossref pmid


ABOUT
BROWSE ARTICLES
EDITORIAL POLICY
FOR CONTRIBUTORS
Editorial Office
Room 319, Hall 1 of Chonbuk National University Dental College, 20, Geonji-ro, Deokjin-gu, Jeonju 54907, Korea
Tel: +82-63-270-4024    E-mail: editor@j-organoid.org                

Copyright © 2024 by The Organoid Society.

Developed in M2PI

Close layer
prev next