From Cells to Organoids: Approaches, Regulatory Mechanisms, Applications, and Challenges of Organoids

The starting cells for organoid construction mainly originate from embryonic stem cells (ESCs), induced pluripotent stem cells (iPSCs), adult stem cells (ASCs), and patient-derived cells. The structural fidelity and functional maturation of organoids are determined by their multipotent differentiation capacity or tissue-specific differentiation potential [15,16]. Patient-derived organoids (PDOs) and patient-derived tumor organoids (PDTOs) typically involve patient-derived tissues with the histological and genetic characteristics of the primary tumor due to their inherent properties.

The microenvironment serves as the core regulatory system for the in vitro development and functional maintenance of organoids. It integrates the physical signals and chemical messages sent out by organs to help organoids develop, grow, and work properly.

The 3D structures of organoids can be formed by stem cells, which involves signals inside the cells, cell-cell interactions, matrix interactions, cell proliferation and migration, and the perception of mechanical forces. It has been demonstrated that the physical properties of the extracellular matrix, e.g., stiffness and adhesiveness, the impact of cell self-assembly, and modulating the mechanical properties of the matrix, can effectively control the morphology and function of organoids [51]. Moreover, the self-assembly process of cells is regulated by growth factors and cytokines that promote their differentiation and organization by activating specific signaling pathways [17]. Human urine-derived stem cells (USCs) are seeded onto a porous 3D silk fibroin scaffold and cultured in an osteogenic differentiation medium to induce cell self-assembly to form bone tissues [52]. The 3D culture system for organoids primarily relies on biological scaffolds, including matrigel and collagen, to simulate the physicochemical properties of the in vivo ECM and provide necessary mechanical support [16]. The 3D culture systems can be classified into two main forms, including static culture and dynamic perfusion (e.g., microfluidic chips) [53,54]. Liver organoids, for instance, generated by the micropillar chip, display more comprehensive liver function characteristics [55]. Moreover, cell-based 3D and tissue slice-based 3D co-culture might be used for organoid generation [56].

Organoid culture relies heavily on matrigel. Matrix components extracted from mouse tumors can mimic the stem cell niche, and thus they have significant limitations since their chemical composition is undefined. The single-chain activating antibody TS2/16 (scTS2/16) retains the variable regions that recognize and activate integrin β1. The variable domains of the heavy and light chains are connected by a flexible linker peptide, and it has been reported to efficiently activate integrin β1 on the cell surface, which enhances the growth of organoids in both matrigel and collagen hydrogels [57]. This research paves the way for the standardized and large-scale culture of organoids, and ultimately, their application marks the entry of organoid culture into a new era of defined composition and clinical applicability [57].

The maturation of organoids usually takes several weeks or months. Factors, including cell source, culture conditions, and operational techniques, affect generation efficiency (ranging from 30% to 80%) and maturation of organoids [58]. Identification of mature organoids requires an analysis from multiple dimensions. Histological analysis verifies structural similarity to the organ from which they are derived [17]. Functional assessment detects specific indicators for functions, e.g., albumin secretion and drug metabolism capacity for liver organoids [16]. Molecular characterization compares organoids' consistency with that of the organ from which they are generated through transcriptomics and proteomics [59], while safety assessment focuses on genetic stability and tumorigenicity risk [60].

The values of organoids depend on their physiological functions, including cell proliferation, differentiation, metabolic activity, and response to external stimuli [61]. Liver organoids can assume energy metabolism, drug metabolism, and toxicity reactions by their hepatocytes [62], and they might be applied to unveil the pathogenesis underlying liver inflammation and hepatocellular carcinoma to identify therapeutic targets for these diseases [63]. Currently, the main challenges in functional characterization of organoids lie in standardizing organoid culture systems and assessment methods to ensure reproducibility and reliability across different laboratories [64].

Organoids can be categorized into multiple types based on their sources, including adult stem cell-derived organoids (ASCOs) originated from adult tissues [40], pluripotent stem cell-derived organoids (PSCOs) derived from embryos [24] or pluripotent stem cells [27], PDTOs directly obtained from patient tissues [44], assembloids constructed by combining multiple organoids [65,66], gastruloids with focus on simulating early-stage development [39], and organoid-on-a-chip system engineering platforms integrated with organoids [67,68,69]. Different types of organoids have distinct applications, e.g., personalized medicine for ASCOs and PDTOs [1,41,45], research on developmental mechanisms and diseases for PSCOs [70], simulating complex cell-cell interactions for assembloids [65,66], studies on early-stage vascularization for gastruloids [71], and dynamic control and drug testing for organoid-on-a-chip systems [72]. In terms of core technologies, organoid-on-a-chip systems rely on microfluidic methods to achieve precise control. Other types of organoids place emphasis on the self-organization ability and differentiation potential of cells. Regarding integration potential, organoid-on-a-chip systems can be adapted to multiple types of organoids (e.g., PDTOs, gastrula organoids). Assembloids can also serve as core input units. We compare different types of organoids in Table 2.

The process of cell-autonomous regulation depends on the genome's inherently developmental programs. These programs dictate the direction of cellular differentiation through the mechanisms of transcriptional regulation and epigenetic modifications, which lays the basis of organoid formation. The differentiation of distinct organoids relies on specialized transcription factors whose functions exhibit strict tissue specificity and stage dependency. CRISPR screening of adult intestinal organoids indicates that transcription factor ZNF800 specifically suppresses endocrine progenitor cell differentiation into enterochromaffin cells [78]. In gastric organoids, MYC stabilizes EPCAM to induce metabolic reprogramming, which inhibits lysosomal biogenesis through the activation of mTOR and ERK [79]. This process prevents the degradation of EPCAM via the macropinocytosis pathway, thereby promoting the chromatin accumulation of β-Catenin and the activation of WNT oncogenic transcription [79]. Testicular organoids involve the interaction of male germ cells and somatic cells to form regulatory networks. The maintenance of SSCs relies on PLZF to sustain their self-renewal [14]. In human-derived organoids and metastatic colorectal cancer (CRC), the squamous-like expression signature induced by Atrx deletion is closely associated with reduced expression of lineage factors, chromatin remodeling, increased invasiveness, and poor prognosis [80]. Sumoylated SnoN acts via the regulation of histone deacetylation HDAC1 to modulate EMT-related effect in breast organoids [81]. The overexpression of the miR-17-92 cluster is associated with malignant progression in colorectal adenoma organoids [82].

The ECM regulates organoid morphogenesis by providing physical support and anchoring signals. The organoid-specific composition and stiffness of the ECM directly determine their morphological differentiation. For instance, intestine organoids depend on matrigel alone, while gastric organoids require matrigel and collagen I. Lung organoids rely on matrigel and fibrin. By mimicking the physical properties of the in vivo organ microenvironment, these ECM components fulfill core functions, including the maintenance of epithelial polarity, promotion of parietal cell polarization, and support of airway branching [83,84,85]. The maturation and functional performance of hepatic organoids depend heavily on the stiffness characteristics of the ECM. It has been shown that choosing an ECM with a stiffness of 1–10 kPa (e.g., matrigel or certain synthetic hydrogels) is essential for facilitating hepatocyte interactions and detoxification functions, which is crucial for developing functional liver organoids [86]. To replicate the core functions of testicular organoids in mimicking the testis in vivo, it is necessary to composite ECM scaffolds with matrigel and collagen IV [87], which offers essentially physical support and signal anchoring for testis organoids to maintain seminiferous tubule-like structures and promote the directional differentiation of male germ cells [87].

The directed induction of organoids lies in the specificity of the "activation or inhibition combination" of classical signaling pathways that are involved in in vivo organogenesis. For intestinal organoids, Wnt3a/Noggin/EGF maintains the Lgr5⁺ stem cell pool and inhibits differentiation to form crypt-villus structures [1]. In the development of testicular organoids, small-molecule inhibitors, e.g., SB431542 and LY2157299, have been shown to promote spermatogonial proliferation and optimize cell-cell interactions and structural reorganization by inactivating the TGF-β signaling pathway [87].

Organoid maturation relies on intercellular crosstalk. In vitro vascularized organoids have been generated to reproduce the synergistic development of mesodermal and endodermal lineages, and cells within organoids spontaneously secrete signaling molecules essential for vascular growth to form vascular networks [88]. This enables the lung and intestinal organoids to develop organ-specific endothelial and mesenchymal components, which enhances cellular diversity, 3D architecture, cell viability, and maturation with physiological functions [88].

Organoids develop through distinct developmental stages (induction, proliferation, differentiation, and maturation) and switch stage-specific signals in the temporal dimension. This stage-specific dependency on regulatory cues is particularly evident in retinal and corneal organoids. In retinal/corneal organoids, stage-specific functions are exhibited by all-trans retinoic acid (ATRA) [89]. Corneal organoid transparency, a hallmark of the induction stage, is promoted by high concentrations of ATRA, whereas photoreceptor maturation is persistently suppressed, which causes defect in the maturation stage [89]. Conversely, low concentrations of ATRA enhance pigment deposition in the retinal pigment epithelium (RPE) and stimulate photoreceptor maturation [89]. Thyroid hormone T3 and taurine promote rod photoreceptor and red/green cone maturation [89], which indicates that each stage necessitates distinct combinations of signaling molecules.

Organoids also have the spatial zonation characteristics of the organ from which they are derived through differences in the levels of signaling molecules or gene expression. The crypt region of the small intestine has high levels of the Wnt protein [90], which is important for maintaining stem cells. In contrast, BMP is expressed highly in the villus region [90], which promotes epithelial differentiation. Together, Wnt and BMP proteins form a radial gradient that mediates cellular proliferation in the crypt and differentiation in the villus [90]. In the lung, the presence of FGF10 in the airway region causes bronchial branching [91,92]. Conversely, BMP4 in the alveolar region of the lung promotes alveolar epithelial differentiation [91,92], which establishes the "airway–alveolar" spatial patterning [91,92]. In gastric-associated structures, the superficial layer exhibits high expression of SOX2 [93,94], which sustains gastric epithelial identity. The deep layer displays high levels of SOX9 expression [93,94], which maintains gastric glandular progenitor cells. Together, they form a hierarchical "gastric lumen-to-gland" spatial architecture through differential gene or protein expression levels.

As the 3D in vitro models, organoids have unparalleled advantages over traditional cell and animal models for unveiling the mechanisms of organogenesis. Cerebral organoids are excellent models for investigating human brain development and brain-related disorders [95], while kidney organoids can be used to explore molecular mechanisms underlying renal development and genetic diseases [48]. Therefore, organoid models retain the functional characteristics of organs from which they are derived to provide unique platforms for the studies on organ morphogenesis and functional establishment.

Organoids mimic the pathological processes of genetic, degenerative, infectious, and other diseases, enabling the exploration of disease etiology. ASCOs are co-cultured with vascular organoids, and these liver organoids further develop into vascularized liver microtissues. These microtissues successfully simulate the complex vascular network structure of the liver, thereby serving as a valuable platform for studying vascular abnormal pathology associated with liver diseases, such as liver cirrhosis and liver cancer [96]. In genetic diseases, organoids generated from patient-derived iPSCs can replicate disease phenotypes. Lung organoids derived from cystic fibrosis patients exhibit characteristic swelling due to dysfunction in chloride transport caused by CFTR mutation [97]. These organoids provide an excellent model for studying epithelial cell functional abnormalities and compensatory mechanisms [97]. By differentiating hPSCs into striatal organoids and midbrain organoids and assembling them into a basal ganglia circuit model (human Striatal-Midbrain Assembloids, hSMAs), the pathological propagation process of α-synuclein (α-syn) was successfully simulated. This model not only recapitulated the functions of the nigrostriatal and striatonigral pathways but also revealed the propagation mechanism of abnormal protein aggregation between neurons [98]. The heart-on-a-chip (HoC) platform integrates engineered 3D cardiac tissues with microfluidic technology to simulate the structures and function of cardiac tissues, thereby providing a new tool for studying the pathogenesis of cardiovascular diseases [99]. It has been demonstrated that patient-derived colonic organoid systems can be employed to unveil the mechanisms by which colonic-resident CD8⁺ T cells induce epithelial apoptosis and gut barrier disruption due to metabolic dysregulation in HIV-infected individuals receiving antiretroviral therapy (ART). Furthermore, activating the lipid metabolism factor PPARγ may restore immune cell metabolism and reduce epithelial damage [100], which offers new approaches for future clinical interventions of infectious diseases.

Brain organoids derived from iPSCs have become ideal models for neurodisease drug screening due to their high degree of similarity to the human brain. Organoids modeling Alzheimer's disease (AD) are used to test the effect of drugs on neuronal function [101]. PDOs/PDTOs preserve tumor heterogeneity and genomic characteristics, making them suitable for anti-tumor drug screening. For example, melanoma organoids are used to monitor the efficacy of cisplatin and temozolomide via a 3D imaging system [102]. Assembloids simulate inter-organ interactions by combining different cell types. For instance, tumor-neural assembloids are applied to study the mechanisms of cancer neural invasion and the influence of drug intervention [103]. The microfluidic technology in organoid-on-chip systems enhances the physiological relevance of organoids. In personalized drug screening for breast cancer and liver cancer patients, the chip enables simultaneous dual evaluation of drug efficacy and toxicity, which is consistent with clinical pathology and ex vivo experiments [104].

Patient-derived brain organoids can retain individual genetic variations, providing a platform for predicting personalized drug response [101]. Patient-derived liver organoids (e.g., pluripotent stem cell-derived liver organoids, PSC-LOs) support drug screening in precision medicine by simulating the authentic structure of the liver. Although current models have limitations in capturing epithelial heterogeneity, technological advancements are expected to enhance their clinical application potential [105,106]. The human ascending somatosensory assembloid (hASA) model, derived from patient iPSCs, can simulate individual-specific pathological features. It provides a tool for predicting personalized drug efficacy and evaluating toxicity, thereby advancing the application of precision medicine in the field of neurosensory diseases [66]. Patient-specific vascular-on-a-chip systems are used to study individual thrombus mechanisms and develop vascular devices [107].

Organoids have the potential to address the shortage of organ donors for transplantion, and they can also provide important cells or replacement tissues for organ repair. By orthogonally activating the transcription factors ETV2 and NKX3.1, researchers have established a simplified method for generating vascular organoids (VOs) from iPSCs, and VOs can be used to examine vascular development and the etiology of diseases; however, the independent regulation of endothelial cells and mural cells still needs optimization [108]. It enables the large-scale production and further maturation of organoids using bioreactors to optimize culture conditions. For instance, kidney organoids cultivated in dynamic bioreactors can form more complete glomerular and tubular structures, which exhibit the significantly enhanced renal function activities [109]. Combining organoids with biodegradable scaffolds can generate larger-scale functional tissues or organoids. For example, seeding intestinal organoids onto tubular biodegradable scaffolds can produce "mini-guts" with intact epithelial barrier function and peristaltic capability [110], which reflects potential for intestinal repair in patients with short bowel syndrome. Pancreatic organoids have the ability to differentiate into insulin-secreting islet β cells [111]. When transplanted into diabetic model mice, they effectively decrease blood glucose levels and regulate insulin secretion in response to changes in glucose levels [111], and this technology is currently at the preclinical research stage [111]. Retinal organoids can differentiate into high-purity retinal pigment epithelium (RPE) cells. The survival of photoreceptor cells can be maintained, and visual function can be improved by replacing damaged RPE cells with these cells after they are transplanted into the subretinal space of patients with age-related macular degeneration [112]. Clinical trials have demonstrated that HLA-matched allogeneic iPSC-RPE cell transplantation is safe and exhibits stable survival [113].

On 8 October 2025, the Center for Drug Evaluation and Research (CDER) of the U.S. Food and Drug Administration (FDA) officially released a position paper titled "Replacing and Reducing Animal Testing" and its supporting implementation checklist. This document not only provides actionable alternatives to animal testing for the biopharmaceutical industry but also marks a fundamental shift in the concept of nonclinical drug evaluation, which moves away from long-term reliance on animal models toward a new assessment system centered on human biological data. It thereby opens up broad application prospects for NAM technologies represented by organoids.

A new perspective review published by the European Federation of Pharmaceutical Industries and Associations (EFPIA) in Nature Reviews Drug Discovery puts forward targeted NAMs solutions. To address the issue of lack of target molecules in animals, a co-culture model of "tumor cells + T cells" can be constructed in vitro to directly simulate the activating effect of drugs on the immune system. By measuring indicators, such as cell killing activity and cytokine release, the safe starting dose for humans can be accurately calculated. To tackle the problem of interspecies differences in target molecules, human-derived and animal-derived vascular cell models can be compared to verify whether drugs cause specific damage to human vascular endothelium. Combined with computational models to predict the safety window, unnecessary animal tests can be reduced. For the challenge where the target is a non-mammalian protein, sequence alignment is used to ensure that the drug acts only on pathogen targets, thereby avoiding off-target effect in humans. Meanwhile, human hepatocyte models are utilized to verify metabolic safety and reduce the risk of liver injury. To deal with unexpected clinical toxicity, 3D liver organoid chips are employed to simulate bile acid metabolism, which reveals the mechanism by which drugs inhibit bile salt export pump (BSEP). Quantitative Systems Toxicology (QST) models are used to predict clinical risk and guide subsequent drug optimization [114].

Although organoids show great promise in drug screening and personalized medicine, their clinical applications still face certain challenges. Firstly, the creation and maintenance of organoids requires advanced techniques and equipment, which limits their widespread use to some extent [115]. Traditional organoid culture relies on an animal-derived matrix, such as matrigel, which has complex composition, large batch variation, and high price. Studies have shown that inorganic biomaterials, e.g., CS/GelMA composite hydrogels, have the advantages of biological activity, biosafety, and cost-effectiveness, and thus they can be used as high-quality substrates for organoid culture. These materials not only support the formation and development of organoids but also significantly reduce the cost of traditional medium and scaffolds [116]. In addition, the biomaterial driven vascularized culture system decreases the dependence of organoids on expensive growth factors by mimicking the in vivo microenvironment [95]. In traditional matrigel, the addition of scTS2/16 can increase the yield of all gastrointestinal organoids by up to 5 folds. More importantly, it significantly improves the clonogenic efficiency of single-cell seeding, which addresses the technical bottleneck in organoid establishment. In the well-defined type I collagen hydrogel, the effect of scTS2/16 is even more remarkable, which enhances the organoid yield by 6–7 folds [57]. Secondly, the biological differences between organoids and clinical samples may affect the predictive accuracy of drug response, highlighting the urgent need to improve their similarity to real tumor tissues [45]. Thirdly, ethical concerns and regulatory policies may hinder the clinical application of organoids [117]. Therefore, future research should focus on optimizing organoid culture techniques, standardizing operational procedures, and addressing ethical and legal issues, in order to facilitate the clinical applications of organoids [118]. Overcoming these challenges is expected to enable organoids to play greater roles in translational medicine, which will ultimately improve patient outcomes and quality of life.

The future development of organoid technology depends on technological advancement and the use of new materials, especially innovations in biomaterials and microfluidic technologies. In recent years, researchers have started to explore new biomaterials, e.g., calcium silicate nanowires and GelMA-based composite hydrogels modified with gelatin, which provide excellent substrates for organoid formation and functions. These new materials enhance the growth and survival rates of organoids and offer more biologically realistic environments for drug screening and disease modeling [116]. The production process of organoids has become more efficient and standardized by means of the application of microfluidic technology. This has paved the way for large-scale production, which in turn has advanced the development of personalized medicine [119]. With the development of novel technologies, organoids have emerged as powerful tools for unveiling the pathogenesis of diseases and developing new drugs [18].

The current core challenges of organoid technology mainly focus on key aspects, including vascularization, immune integration, functional maturation, and standardization.

The rapid development of organoid technology has created an urgent need to address the associated ethical issues and establish regulatory frameworks. Organoid research involves the use of human cells and tissues, which raises concerns about ethical and legal issues (e.g., ensuring the informed consent of research subjects) and protects personal privacy [133]. While some countries and regions have formulated relevant ethical guidelines, there is currently a lack of unified regulatory frameworks and standards globally, which creates uncertainty around the conduct of organoid research [134]. Therefore, establishing a comprehensive ethical and regulatory framework would not only promote the healthy development of organoid technology but also provide the legal safeguards and ethical support for scientific research [135]. Such a framework should cover all aspects of research design, implementation, and reporting to ensure transparency and fairness, thereby enhancing public trust in organoid research [136].