2.1 PSC-derived organoids

Since the discovery of PSCs, researchers have generated a wide range of differentiated cell types from stem cells based on theories of developmental biology.^{39, 40} iPSCs are produced by reprogramming PSCs (such as by integrating transcription factors into the target cells), and ESCs are derived from cell masses within the blastocyst, both of which have the capacity for multidirectional differentiation.^{41, 42} The establishment of PSC-derived organoids depends on the directed differentiation of PSCs. This process requires the formation of specific germ layers (endoderm, mesoderm, or ectoderm), followed by incubating with specific growth factors, signaling molecules, and cytokines to induce cell-directed differentiation and maturation. PSC-derived organoids contain a richer cellular fraction, including mesenchymal, epithelial, and endothelial cells.^{43, 44} iPSC-derived organoids were applied in modeling various human diseases in vitro.^45-49 However, when PSC-derived organoids reach a certain lifespan, they lose their ability to proliferate and fail to develop to a fully mature state.^{50, 51} In addition, the limitations of current technologies cause the lack of important interactions between cells in PSC-derived organoids with other codeveloping cells.⁵² Therefore, PSC-derived organoids are generally naïve, resembling fetal tissues, which can be considered as excellent models for organogenesis research.⁵³ ESC-derived organoids are more mature than iPSC-derived organoids, which can be used as novel models for studying later phases of organogenesis.^{54, 55} However, ESCs need to be obtained from the embryo and there are many ethical issues involved (Figure 2).

2.2 ASC-derived organoids

ASCs (with the exception of skin stem cells) are thought to be incapable of significant in vitro expansion. The team of Clevers applied 3D technologies to culture the leucine-rich repeat-containing G protein-coupled receptor 5 positive (Lgr5+) intestinal mouse ASCs to establish intestinal organoids by adding various stem cell niche factors into the medium and manually modulating signaling pathways. This study indicated that ASCs could expand in vivo in the presence of stem cell niche factors. The construction of ASC-derived organoids requires identifying proper ASC types. WNT pathway activation is one of the main drivers of organoid formation in epithelial ASCs, and Lgr5 was positive in almost all epithelial ASCs that could be used for organoid culture. The culture protocol for ASC-derived organoids is simpler, shorter, and more mature, and they more closely resemble adult tissue.^{56, 57} Therefore, they can be better used in regenerative medicine and disease modeling because their cell sources are abundant.^58-60 However, ASC-derived organoids have a single cellular component, mainly epithelial,⁶¹ and prior knowledge of the medium for culturing ASC-derived organoids from different tissues is also a limitation for ASC-derived organoids.

2.3 Tumor cell-derived organoids

Based on the culture protocol for ASC-derived organoids, organoids can be generated from isolated tissues. Isolated tumor tissues after digestion and dissociation can be used to grow organoids with 3D culture conditions, and these organoids are called tumoroids. Tumoroids maintain and preserve the histological structure, molecular genetic characteristics, and heterogeneity of the original tumor, which can represent the features of the patient's tumor in some degree.^{62, 63} Tumoroids can be used as good preclinical models for basic and clinical research related to tumors.^64-72 Tumor liquid biopsy samples or tumor cells collected by the Pap brush method have been considered as starting material for organoid cultures.^73-76 De Angelis et al.⁷⁷ constructed the mouse xenograft model by using colorectal circulating tumor cells to promote these tumor cells proliferation in order to generate sufficient materials to form tumoroids. In addition, whether by surgical resection, puncture biopsy, or samples collected by Pap brush, the isolated tumor cells usually included normal cells and/or blood cells (especially red blood cells), which might influence tumoroid growth.⁷⁷ A possible solution to this problem is to reduce or delete some factors necessary for the establishment of normal cell-derived organoids, as tumor cells reduce their dependence on them. To eliminate contamination of red blood cells, lysis is one method that can be adopted.⁷⁸

2.4 Multilineages organoids

To represent the niche of cells in an organism, the interactions between various regions and different cell populations in physiology and pathophysiology should be recapitulated as closely as possible. For example, the interactions between different brain regions contribute to the formation of certain brain regions.⁷⁹ Mesenchymal and endothelial cells have been found to exert indispensable functions in the development of the liver and are able to manipulate the behavior of hepatic progenitors.⁸⁰ Assembloids, considered as the next generation of organoids, can be established by coculturing the multiple-type cells or combinations of organoids with different cell lineages from other tissues or organs.^{79, 81, 82} Compared with single-type cell-derived organoids, assembloids can better reproduce interactions among different subregions or various cell lineages in organs.

Several studies fused cerebral organoids from different brain regions to capture the interactions between different brain regions in the process of brain development, including long-distance projections and interneuron migration.^83-85 A recent study by Andersen et al.⁸⁶ formed cortical, hindbrain/cervical spinal cord, and skeletal muscle organoids, and fused the three organoids to generate cortico-motor assembloids, which can represent the cortico-motor pathway functions (the cortical control of muscle contraction) in vitro long term. Similarly, Ogawa et al.⁸⁷ developed a novel cancer model of gliomas that was established by the artificial combination of brain organoids and glioblastoma cells, which can be used to study tumorigenesis and metastasis mechanisms.

Research based on the assembloid has also been extended to the peripheral nervous system. It has been reported that iPSCs can differentiate into spinal cord neurons and skeletal muscle cells simultaneously, and these cells can self-organize to form hybrid neuromuscular organoids in vitro.⁸⁸ Intestinal organoids cocultured with neural crest cells were confirmed to model the development of the enteric nervous system and motility disorders of the intestinal tract.⁸⁹

Assembloids resembling other tissues or organs have been reported by many studies. Takebe et al.^90-92 incubated iPSCs or human embryonic cells with human umbilical vein endothelial cells and human MSCs to generate 3D vascular and functional organ buds. Bergmann et al.⁹³ generated blood–brain barrier (BBB) organoids via coculturing human primary brain endothelial cells, astrocytes, and pericyte. The anterior and posterior gut spheroids derived from iPSCs were cocultured under 3D conditions to generate assembloids that could accurately mimic the continuous and dynamic process of human hepatobiliary and pancreatic organogenesis in vitro.⁹⁴ Similarly, Ng et al.⁹⁵ formed cardio-pulmonary assembloids by inducing iPSCs to differentiate cardiac and lung epithelial cells simultaneously, which is a promising platform for studying the interactions between the human heart and lung and tissue boundary formation during embryonic development. The teams of Chan et al. and Takebe et al. established multicellular hepato-biliary organoids from iPSCs, and these organoids have the potential to model complex liver diseases such as nonalcoholic fatty liver disease (NAFLD).^{96, 97} In addition, Tanimizu et al.⁹⁸ generated functional hepatobiliary organoids by combining EpCAM+ cholangiocytes and small hepatocytes, and found that a connection between hepatocytes and cholangiocytes was formed in the organoids.

3.1 Submerged culture

Submerged culture, developed by the group of Clevers, is the most widely used culture method for organoids.³⁷ In this protocol, cells or cell clusters are embedded in extracellular matrix (ECM) gels, then the mixture of cells and matrix gels is placed in a culture dish to form a dome, and medium is added to submerge the dome. ECM gels play the role of structural support and offering ECM signals, and common ECM gels include basement membrane extract, Matrigel, and Geltrex. The main components of the medium for the submerged culture include adDMEM/F12, penicillin/streptomycin, GlutaMAX, HEPES, B27, epidermal growth factor (EGF), FGF2, FGF10, Wnt3A, Noggin, R-spodin-1, Prostaglandin E2, N-Acetylcysteine, Nicotinamide, Y27632, A-8301, and SB202190.^{37, 99} The medium composition varies when forming organoids from different tissues, and which specific factors need to be added or removed usually depends on the requirements of the tissue from which they originate for the corresponding signal or hormone.¹⁰⁰

3.2 ALI culture

The 3D culture conditions for organoids can be achieved using ALI technology that was first proposed by Ootani et al.¹⁰¹ for the establishment of pancreatic and gastrointestinal tract organoids. The mechanically separated tissue fragments were homogeneously embedded in collagen gel, the mixture was laid flatly in an inner culture dish with a porous membrane underneath, and the top of the mixture was exposed to air. The medium was added in an outer culture dish. In this system, nutrients and growth substances are transferred by diffusion from the medium in the outer dish into the inner dish to meet the requirements of organoids.^{102, 103} Due to direct exposure to oxygen, ALI cultures have a higher oxygen supply than the submerged culture method. Kuo's group later established a variety of patient-derived tumoroids using the ALI method, including some rare tumor types such as bile duct ampullary adenocarcinoma.³⁸ The ALI culture system, combining two culture dishes, can support the growth of organoids and stromal cells simultaneously. It is worth noting that organoids formed with this approach are able to preserve the functional tumor-infiltrating lymphocytes (TILs), which can represent the complex tumor immune environment.^{38, 104}

3.3 Organoids-on-a-chip

Organ-on-a-chip is a microfluidic cell culture device that allows accurate control of the biophysical and biochemical environment for cell growth and simulates both cellular and microenvironmental conditions, as well as inter-tissue and multiorgan interactions.¹⁰⁵ A variety of organ-on-a-chips have been created to simulate corresponding organs in vitro, which are used for disease modeling and to study the function of related organs.^106-108

Although organ-on-a-chip has fundamental differences from organoids, the organoids-on-a-chip generated from the combination of organoid technologies and organ-on-a-chip can compensate for the shortcomings of the two technologies, and thus better serve as more effective preclinical models for simulating key features of target organ tissues. Cells in organoids-on-a-chip are randomly and spontaneously self-organized into 3D structures, which differs from the carefully designed organ-on-a-chip.¹⁰⁹ Currently, a number of studies have established organoids-on-a-chip of the brain, heart, gastrointestinal tract, liver, and pancreas.^110-116 Cho et al.¹¹⁰ developed a brain organoids-on-a-chip based on PDMS chips, and this system could increase the oxygen supply and promote nutrient/waste exchange to reduce the organoid cell death. Notably, this culture system could form mature brain organoids and be used to monitor the development of the overall human brain. A recent study has shown that the organoid-on-a-chip system can create a hypoxic gradient in the lumen of small intestinal organoids and maintain the intestinal microbial barrier.¹¹⁷

In addition to the above culture methods, 3D systems for organoids can be prepared by the hanging drop and rotational culture methods. The hanging-drop approach applied gravity and surface tension to hang the mixture of cells and droplets of specific medium from a plate.¹¹⁸ The rotational culture method can prevent cells from settling and improve the uptake of nutrients and oxygen by constantly rotating or stirring the cells, which has been used in the formation of brain and retinal organoids.^{119, 120} Jacob et al.¹²¹ generated patient-derived glioblastoma organoids that preserve the histological and genetic features and part of the microvasculature and immune microenvironment.

4.1 Disease modeling

4.1.4 Cancers

Currently, the most commonly used oncology models mainly include human tumor cell lines and patient-derived xenograft (PDX) models. However, these models have some unavoidable shortcomings. Tumor cell lines involve primary (originated from patients) and immortalized tumor cells. Although primary cancer cells preserve some features of the parental tumor, the slow growth speed, short lifespan, and lack of complexity of tumors limit their applications. The immortalized cells have unlimited proliferation capacity, but they usually fail to represent the phenotypes and lose genetic heterogeneity of the original tumor during long-term culture and passages, which may increase the failure rate of clinical drug screening trials.¹⁹⁷ The 2D culture systems are unable to mimic the in vivo cellular growth conditions, and the 2D cultures fail to represent the tumor heterogeneity accurately. PDX models are constructed by transplanting human tumor cells into mice and promoting these cells to grow and form tumors. Xenograft models can maintain the relatively intact biological features of parental tumors as well as the 3D structure and tumor stroma. Studies have successfully generated several tumor PDX models, such as lung, colorectal, pancreatic, breast, prostate, and ovarian tumors.^198-202 However, several shortcomings restricted them to being excellent preclinical models. Xenograft models are usually established from a small number of tumor tissues, which cannot completely inherit the genetic mutations from the primary tumor, and the stroma of the human tumor is gradually substituted by murine stroma with the PDXs growth.²⁰³ Many research results based on the PDX models have not been confirmed in human trials.²⁰⁴ Furthermore, the economic and time costs of PDX models are high with a low success rate.²⁴ Tumoroids retain parental tumor heterogeneity and histopathological features and reserve their 3D structure after long-term culture^{32, 33, 205-207} (Table 1). Papaccio et al.²⁰⁸ reported that patient-derived colorectal tumoroids represented the morphology and immunohistochemistry characteristics and genomic and transcriptomic profile of corresponding tissues, and the response to anticancer drugs varied among these tumoroids derived from different patients.

TABLE 1. Comparison of the current preclinical models for cancer research.

	2D tumor cell lines	Patient-derived xenografts	Tumoroids
Success rate of establishment	Generally high (but some special tumor types are low)	Relatively low	Relatively high
Maintenance	The easiest	Little difficult	Easy
Genetic manipulation	Able	Unable	Able
Genome-wide screening	Able	Unable	Able
Relative cost	Low	High	Relatively high
High-throughput assay	Able	Unable	Able
Expansion	Quick	Relatively low	Quick
Reproducibility	High	Moderate	Relatively low
Ability to recapitulate tumor development biology	Low	Low	High
Tumor immune microenvironment	Unable to recapitulate	Partial recapitulation	Partial recapitulation
Tumor heterogeneity	Unable to recapitulate	Retain, (but heterogeneity may be lost partly in long-term culture)	Retain parental tumor heterogeneity
Ability of personalized treatment	Low	Moderate	High
Complexity	Low complexity	High complexity (enable to reproduce the cell types and the tumor cell–stroma cell interactions of the primary tumor and can be used to study metastasis)	High complexity (recapitulate histological and genetical features of primary tumors)

The role of mutations in genes or structures in tumor development is difficult to observe dynamically or to intervene. Therefore, the exploration of the tumorigenesis mechanism is usually performed with difficulties. Organoid technology enables in vitro simulation of the entire process of tumor development.⁴⁸ According to organoid models, the accumulation of specific tumor-driving gene mutations has been found to play a crucial role in tumorigenesis.²⁰⁹ The combination of genome editing and organoids offers new opportunities to study the role of pathogenic gene mutations. With CRISPR-Cas9 technology, the oncogene c-MYC associated with HCC was introduced into normal liver organoids.²¹⁰ Excessive mitochondrial endoplasmic reticulum coupling occurred in these organoids and altered mitochondrial fission and aerobic respiration, finally resulting in HCC tumorigenesis. Human colorectal tumoroids have been utilized to discover three tumor suppressor genes (Acvr1b, Acvr2a, and Arid2) and identified the function of Trp53 in liver metastasis of colorectal cancer (CRC).²¹¹ Tumoroids serve as an advanced platform that is highly similar to the physiology and microenvironment features of in vivo tumors to propel our fundamental knowledge of tumorigenesis, progression, metastasis, and recurrence. The applications of organoids in modeling diseases are summarized in Table 2.

TABLE 2. Applications of organoids in disease modeling.

Organs or tissues	Diseases		Cell sources	References
Brain	Genetic diseases	Primary microcephaly	Human iPSCs and ESCs	148, 149
		Rett syndrome	Human ESCs and iPSCs	150
		Tuberous sclerosis complex	Human iPSCs	151, 152
		Fragile X syndrome	Human iPSCs	153
		Down syndrome	Human iPSCs	154
	Degenerative diseases	Parkinson's disease	Human iPSCs	45
		Alzheimer's disease	Human iPSCs	46
	Infection	ZIKV infection	Human ESCs and iPSCs	156, 220
		HSV-1 infection	Human ESCs	156
		Human cytomegalovirus infection	Human iPSCs	163
		SARS-CoV-2 infection	Human iPSCs	174
	Tumor	Glioblastoma	Patient-derived tumor cells	64, 121
		Medulloblastoma	Human iPSCs	65
		Glioma	Patient-derived tumor cells	66
Retina	Genetic diseases	Nonsyndromic CLN3 disease	Human iPSCs	142
		Retinitis pigmentosa	Human iPSCs	143
		Leber congenital amaurosis	Human iPSCs	144, 145
	Tumor	Retinoblastoma	Human iPSCs and ESCs	236
Air ways	Genetic diseases	CF-related air way diseases	Human ASCs	132
	Infection	Respiratory syncytial virus infection	Human ASCs	132
		SARS-CoV-2 infection	Human iPSCs and ASCs	10, 161, 174, 175
		Influenza virus infection	Human ASCs	161
		Cryptosporidium infection	Human ASCs	180
	Tumor	Lung adenocarcinoma	Patient-derived tumor cells	71, 72
		Nonsmall-cell lung cancer	Patient-derived tumor cells	132, 216, 217
Gastrointestinal tract	Genetic diseases	CF-related intestinal diseases	Human ASCs	134, 137
	Infection	SARS-CoV-2 infection	Human ASCs	10, 177
		H. pylori infection	Human iPSCs and ASCs	50, 182
		Human norovirus infection	Human ASCs	159, 160
		Cryptosporidium infection	Human ASCs	180
	Tumor	Neuroendocrine carcinoma	Patient-derived tumor cells	33, 69
		Colorectal cancer	Patient-derived tumor cells	38, 208, 216, 217, 232
		Gastric cancer	Patient-derived tumor cells	184, 251
Hepatobiliary	Genetic diseases	Primary sclerosing cholangitis	Human ASCs	59
		α1-Antitrypsin deficiency	Human ASCs	112, 113
		Alagille syndrome	Human ASCs and iPSCs	113, 114
		Wilson's disease	Dog ASCs	115, 116
		Wolman disease	Human iPSCs	117
		CF-related bile duct disease	Human ESCs	135
	Metabolic diseases	Nonalcoholic fatty liver disease	Human iPSCs, ASCs	97, 127, 194
		Alcoholic liver disease	Human ESCs	196
	Infection	Rotavirus infection	Human ESCs and ASCs	162
		Viral hepatitis	Human iPSCs, ASCs, and ESCs	167-172
		Salmonella Typhi infection	Mouse ASCs	186
	Fibrosis	Liver fibrosis	Human iPSCs	48
	Tumor	Cholangiocarcinoma	Patient-derived tumor cells	15, 30, 33, 205, 206
		Gallbladder adenoma	Human ASCs	32
		Gallbladder carcinoma	Patient-derived tumor cells	32, 33
		Bile duct ampullary adenocarcinoma	Patient-derived tumor cells	38
		Hepatocellular carcinoma	Patient-derived tumor cells and human iPSCs	205, 207, 233
Pancreas	Genetic diseases	Pancreatic dysplasia	Human iPSCs	48
		Wolfram syndrome	Human iPSCs	128
		Congenital hyperinsulinism	Human ESCs	129
	Tumor	Pancreatic ductal adenocarcinoma	Patient-derived tumor cells	231, 258, 264
Thyroid	Autoimmune diseases	Hashimoto's thyroiditis	Human ASCs	58
		Graves’ hyperthyroidism	Human and mouse ASCs	60
	Tumor	Papillary thyroid cancer	Patient-derived tumor cells	241
Kidney	Genetic diseases	Polycystic kidney disease	Human iPSCs	19
	Injury	Kidney injury	Human iPSCs	20
	Infection	SARS-CoV-2 infection	Human iPSCs	176, 179
	Tumor	Renal cell carcinoma	Patient-derived tumor cells	257
Heart	Genetic diseases	Hypoplastic left heart syndrome	Human iPSCs	140
		Pregestational diabetes-induced congenital heart defects	Human iPSCs	141
Salivary gland	Tumor	Salivary gland tumor	Patient-derived tumor cells	38, 68
Mammary gland	Tumor	Breast cancer	Patient-derived tumor cells	62, 198, 261
Prostate gland	Tumor	Prostate cancer	Patient-derived tumor cells	214
Lacrimal gland		Dry eye disease	Mouse and human ASCs	226
Vasculature	Metabolic diseases	Diabetic vasculopathy	Human iPSCs	47
Blood–brain barrier	Infection	Plasmodium falciparum infection	Human ASCs	181
		Lyme neuroborreliosis	Human ASCs	182

• ASCs, adult stem cells; CF, cystic fibrosis; ESCs, embryonic stem cells; iPSC, induced pluripotent stem cells; SARS-CoV-2, severe acute respiratory syndrome coronavirus 2; ZIKV, Zika virus.

It has been widely accepted that the tumor immune microenvironment plays an essential role in tumor formation and progression. Based on the cancer immunoediting theory, the immune system can inhibit or promote tumor growth in different stages.²¹² Despite advances in immunotherapy, a part of patients present with low responses to this treatment. One of the hot topics in the field of tumor immunotherapy is the identification of patients who are sensitive to immunotherapy. Evidence has shown that the tumor immune microenvironment is recapitulated via coculturing tumoroids and stromal cells such as TILs and cancer-associated fibroblasts (CAFs)²¹³ (Figure 4). Zhang et al.²¹⁴ incubated tumoroids derived from prostate cancer patients and CAFs and found that neuregulin 1 released by CAFs could activate human EGF receptor 3 in cancer cells, leading to antiandrogen therapy resistance. Kuo et al. successfully generated patient-derived tumoroids from 100 patients with 28 distinct tumor subtypes with ALI culture system, which retained a variety of immune cells such as T cells, B cells, NK cells, and macrophages, and the T cell receptor spectrum of parental tumors. However, with time going on, the immune components of ALI-cultured tumoroids would decrease. Treatment with nivolumab in these tumoroids could screen for specific patients who respond to immunotherapy.^{38, 215} The interactions between tumor cells and T cells have been modeled by tumoroid and peripheral blood mononuclear cell (PBMC) coculture systems. Tumor-reactive T cells were generated by coculturing PBMCs and tumoroids, and they have tumor-specific T cell responses.^{216, 217} Liu et al.²¹⁸ established autologous organoid- killing models to confirm that high-affinity neoantigens had higher antitumor activity in HCC patients. With a similar method, a recent RCT study (NCT03026140) demonstrated that there existed an association between induced T cell reactions in vitro and patient response.²¹⁹

4.2 Drug research

Organoids have distinct advantages in that they can recapitulate in vivo physiological functions and features of organs or tissues, excelling in a wide range of models for drug-related research. As described above, ZIKV infection contributes to birth defects and miscarriage. A work by Li et al.²²⁰ demonstrated that methylene blue protected brain organoid cells from ZIKV infection via blocking viral protease NS3 and NS2B interactions. Another recent study represented the HEV–host interactions in liver organoids and reported that brequinar and homoharringtonine are potent anti-HEV drugs.¹⁷¹ Bacterium-infected intestinal organoids have been utilized to serve as advanced platforms for drug discovery. Bacitracin, an antibiotic for local application, has been identified to inhibit the activity of Clostridium difficile and its toxin B.²²¹ Islet organoids were used for drug screening in diabetes.²²² Based on 3D culture, GLIS3−/− human ESCs (hESCs) were induced to act as a high-throughput platform for drug identification in GLIS3-associated diabetes.²²³ High glucose metabolism could stabilize and activate HIF-1α, and upregulate some HIF-1α target genes. PX-478, a HIF-1α inhibitor, was employed to treat human islet organoids with chronic high glucose exposure, enabling the glucose-induced insulin secretion stimulation index increase, which was considered as a potential antidiabetic agent.²²⁴ Moreover, the lacrimal gland organoids are reported as promising tools that allow high-content drug screening.^{225, 226}

Patient-derived organoids are advanced models for discovering and testing novel drugs.²²⁷ Based on the results of drug sensitivity tests, patients are categorized to find the similarities in genetic mutations or epigenetics in those who respond to specific therapeutic regimens, which may help advance the precision of antitumor treatment.^{228, 229} The L1 cell adhesion molecule (L1CAM) is a trigger factor of metastasis and is upregulated in tumor that have undergone neoadjuvant chemotherapy. Ganesh et al.²³⁰ indicated that knockdown L1CM human colorectal tumoroids presented improved sensitivity to irinotecan. The coculture system of pancreatic ductal adenocarcinoma (PDAC) organoids and CAFs showed resistance to gemcitabine, 5-FU, and paclitaxel, with increased epithelial-to-mesenchymal transition (EMT) gene expression in these organoid cells.²³¹ Colorectal tumoroids were used to perform drug sensitivity assays and pharmacogenomics analysis, and results showed that the paclitaxel sensitivity was linked to the checkpoint with forkhead and ring finger domains (CHFR) silencing in organoid as well as in xenograft models.²³² Organoids can be cultured in a short timescale with high generation efficiency, which is valuable for extending the applicable scope of existing medicines. CF patient-derived organoids were employed in a high-throughput compound assay to identify potential drugs to treat individuals having rare CFTR mutations.¹³⁷ Yuan et al.³² performed a drug sensitivity test for 29 antitumor compounds approved by the United States Food and Drug Administration (US FDA) in human gallbladder tumoroids, and histone deacetylase (HDAC) inhibitors, including vorinostat and curcumin, significantly suppressed the growth of GBC tumoroids. Furthermore, CUDC-907, a dual PI3K/HDAC inhibitor, presented a higher level of tumor suppressive activity. PCSK9 has been reported as a therapeutic target for patients with dyslipidemia or hypercholesterolemia, and overexpression of PCSK9 is associated with oncogenesis and enhances the malignant phenotypes of CRC with APC/KRAS mutations. Wong et al.²³³ found that blocking PSCK9 significantly suppressed the growth of human APC/KRAS colorectal tumoroids. The protein synthesis inhibitor omacetaxine has been approved by the US FDA to treat patients with chronic myelogenous leukemia.²³⁴ However, in a recent study, this drug was proven to be a highly effective compound that could repress the growth of HCC patient-derived organoids and promote tumoroid cell apoptosis. Thus, omacetaxine has the potential to be a new option for HCC treatment.²³⁵ Watanabe et al.²³⁶ established human PDAC tumoroids for drug screening, and the CHK inhibitors exhibited effective antitumor ability, which was found to be effective against breast and ovarian cancers and has been proven in clinical trials (NCT03495323, NCT02203513). Sunitinib has been approved to treat kidney cancer and imatinib-resistant gastrointestinal stromal tumors. At present, sunitinib has been identified as a potential agent for the treatment of retinoblastoma with minimal toxicity to normal retinal cells.²³⁷

Advances in organoid technologies allow for the development of efficient therapies or combination regimens. The nicotinamide adenine dinucleotide phosphate oxidase (NOX) can produce ROS to promote EMT of cells, eventually causing cancer, and NOX4 plays an important role in the development of various tumors.²³⁸ Fangchinoline, a small molecule extracted from Menispermaceae, was found to exert antitumor effects in nonsmall cell lung cancer (NSCLC) organoids via inhibition of NOX4 to reduce ROS, hamper Akt-mTOR pathway activation and decrease EMT and malignant phenotypes.²³⁹ Ghate et al treated patient-derived colon tumoroids with the VprBP inhibitor B32B3 and found that B32B3 could restrain H2AT120 phosphorylation and restart the normal transcriptional program to impair the proliferation activity of colon tumoroids.²⁴⁰ BRAFV600E inhibitor monotherapy was employed to treat human papillary thyroid tumoroids with the BRAFV600E mutation and exhibited mild antitumor activity. On the basis of BRAF inhibitors, combining MEK, RTK inhibitors, or chemotherapies could remarkably decrease the viability of tumoroid cells.²⁴¹ AT-rich interaction domain 1A (ARID1A) is one of the subunits of the BRG1- or HBRM-associated factor complex and has been demonstrated to have tumor suppressor effects.^{242, 243} ARID1A mutation or deficiency has been shown to contribute to facilitating the aggressiveness of tumors,²⁴⁴ and it has been identified that most gastric cancer patients carry ARID1A mutations. Recent research by Loe et al.²⁴⁵ provided a novel combination therapy of TP06 (epigenetic inhibitor) and Nutlin-3 (p53 agonist) to treat gastric tumoroids with Arid1a heterozygosity, exhibiting a robust inhibition of tumor growth.

Other applications of organoids in drug-related research also include toxicity assessment and drug safety evaluation. The liver and kidney are the primary organs and play essential roles in the processes of drug metabolism and excretion. Therefore, they are vulnerable to drug-related injuries. The traditional models for toxicity assessment include 2D cell lines and animal models; however, these models have always suffered from some insurmountable drawbacks.^{246, 247} In addition, the expression and function of enzymes and proteins related to drug metabolism as well as metabolic functions, vary between species, making it impossible to accurately assess drug toxicity.²⁴⁶ Organoids highly resemble the structure and metabolism characteristics of original organs or tissues, which provide excellent preclinical models for toxicity assessment and drug safety evaluation. Under the condition of differentiation into the hepatic lineage, human ASC-derived intrahepatic cholangiocyte organoids (ICOs) can represent the metabolism features of the liver, such as the expression of CYP enzymes.¹²³ Shi et al.²⁴⁸ identified the associations between necroptosis and bile duct disease via ICOs, which could serve as a useful ex vivo model for biliary cytotoxicity assessment. Bouwmeester et al.²⁴⁹ established hepatocyte-like ICOs and detected the expression and activity of drug metabolism-related genes to confirm the ability of organoids in ex vivo toxicity assessment. Zhang et al.²⁵⁰ developed a high throughput screening platform based on the human liver organoid-on-a-chip for drug-induced liver injury that pooled multiomics such as biomarker/analyte detection, high-content imaging-enabled phenotyping, and single-cell RNA sequencing. The authors demonstrate the effectiveness of this platform by testing a set of known hepatotoxic drugs and comparing the results to clinical data. Another study demonstrated the potential utility of hepatic organoids for hepatotoxicity and drug safety assessment by conducting a functional analysis of CYP450-mediated metabolic ability.²⁵¹ To test the potential nephrotoxicity of Esculentoside A, Gu et al.²⁵² exposed iPSC-derived kidney organoids to the compound and monitored changes in cell viability, morphology, and gene expression. They found that exposure to Esculentoside A resulted in decreased cell viability and altered gene expression patterns, indicating that organoids offered a promising approach for assessing the toxic effects of compounds. What's more, the side effects of most anticancer compounds involve gastrointestinal symptoms such as abdominal pain, vomiting, nausea, and diarrhea. Serious gastrointestinal reactions may force the patient to discontinue treatment, leading to a dismal survival outcome and poor quality of life. However, the underlying mechanisms of gastrointestinal toxicity caused by many antineoplastic drugs have not been fully clarified. Recent studies forecasted the gastrointestinal toxicity caused by gefitinib and doxorubicin by evaluating the viability and apoptosis of the colon and small intestine after exposure to the two compounds. Furthermore, the possible molecular mechanisms of gefitinib and doxorubicin-triggered intestinal toxicity were explored by transcriptomic analysis.^{253, 254}

In conclusion, organoids are an important tool for assessing the effects and toxicity of drugs, understanding drug metabolism and distribution, predicting drug safety and efficacy, and providing better guidance for drug development and clinical application. The use of organoids in drug research has revolutionized the drug development process. Organoids provide a powerful tool for modeling human physiology and disease, which can improve drug discovery, reduce the failure rate of clinical trials, and accelerate the development of new therapies.

4.3 Precision medicine

Organoids have shown great potential in the field of precision medicine, which aims to tailor medical treatments to individual patients based on their specific genomics and metabolomics.²⁵⁵ By providing a more physiologically relevant and personalized model of human organs or tissues, organoids can be used to predict individual patient responses to drugs and other treatments.^{256, 257}

One potential application of organoids in precision medicine is in the development of personalized cancer treatments. PDOs can be used to test the efficacy of different chemotherapy drugs and identify the most effective treatment for that patient.^{258, 259} This approach is more accurate than traditional methods of testing drugs on cancer cell lines, which do not fully capture the genetic diversity of individual tumors. An article by Khan et al. described the application of organoids to predict the response of patients presenting with metastatic digestive system tumors to various chemotherapy drugs and targeted drugs. The researchers found that the organoids accurately forecasted which treatments would be effective in the patient and which would not, with significantly high specificity (93%) and sensitivity (100%).²⁶⁰ Similar work was carried out by Yao et al., who established locally advanced rectal cancer patient-derived organoids to construct a biobank. The study demonstrated that rectal tumoroids could recapitulate the patient's response to neoadjuvant chemoradiation in vitro, with an accuracy rate of 86%, and also was able to identify patients who were likely to have a complete response to chemoradiation therapy, allowing clinicians to tailor treatment to the individual patient.²⁶¹ According to the study by Lyudmyla, the drug sensitivity results of PDAC patient-derived organoids were highly consistent with the clinical response of patients, and the PDO forecasted drug response was also linked to tumor cellularity.²⁶² Furthermore, studies have identified the feasibility that PDOs could serve as platforms for fast drug screening and allowed patients to achieve the most appropriate therapeutic regimens.^{262, 263} It is worth noting that, in addition to directly guiding patients on medication, the overall analysis of tumoroids can be applied in the discovery of biomarkers for clinical treatment response. The team of Burkhart suggested that the clinical sequencing results of PDAC patients who have better responses to chemotherapies tended to have fewer mutations in KRAS, TP53, and SMAD4 and the specific pharmacotype of PDOs had potential as a forecasted biomarker for the response of PDAC patients to chemotherapies via an ongoing clinical trial (NCT03563248).²⁶⁴ Target therapy is a precision medicine approach that targets specific molecular markers or signaling pathways of tumors and selects specific drugs for treatment.²⁶⁵ Targeted therapy is a part of precision medicine that uses specific compounds to inhibit specific molecular markers or signaling pathways of tumors or other diseases. Organoids are also used to perform target drug screening and discover potential therapeutic targets owing to the important roles of organoids in target therapy theories.^{100, 266} Ovarian tumor organoids derived from patients with three tumor types had been used as a high-throughput screening platform to test the sensitivity to 240 protein kinase inhibitors by Phan et al.,²⁶⁷ and this platform allowed rapidly obtaining drug sensitivity results for ovarian cancers. Yuan et al.³² screened 20 US FDA-approved targeted drugs with low toxicity to normal gallbladder organoids and found that HDAC inhibitors could significantly decrease the growth of the gallbladder tumoroids. After further study, they demonstrated that the dual phosphatidylinositol-4,5-bisphosphate 3-kinase (PI3K) and HDAC inhibitor CUDC-907 had higher antitumor activity than the HDAC inhibitor alone in the gallbladder tumoroid and xenograft mouse models.³² A novel organoid culture system combining suspension and rotating culture methods was developed to cultivate colorectal tumoroids on a large scale for drug screening with high accuracy, robustness, and reproducibility because this method could improve the scalability and decrease the variability of organoids. The study tested 56 anticancer agents, of which 47 were inhibitors with small molecules that targeted specific tumor-associated pathways, and suggested that the tumor drug response heterogeneity was attributed to the diversity of genes or epigenetics. Furthermore, based on the gene−drug analysis, a significant correlation between the BRAFV600E mutation and vemurafenib was observed as well as TP53 mutations and the MDM2 inhibitor nutlin-3.²³² Organoids present with the potential as promising tools or models to explore the underlying drug resistance mechanisms and help customize the optimal treatment plan. Zhao et al.²⁶⁸ analyzed hepatobiliary tumoroids with various drug susceptibilities using single-cell transcriptome sequencing technology. CD44+ hepatoma cells were found to have the ability of broad-spectrum drug resistance and metabolic advantages. Lee et al. found that SHP099, an inhibitor of Src homology 2 domain-containing phosphatase 2 (SHP2), could abrogate receptor tyrosine kinase (RTK)-induced reactivation of the MAPK/ERK kinase (MEK)/extracellular regulated kinase (ERK), and protein kinase B (AKT) signaling pathways to eliminate sorafenib resistance.²⁶⁹ To verify this result, they treated HCC patient-derived organoids with SHP099 and sorafenib and showed that the combination treatment significantly inhibited tumor cell growth and that the HCC cells in these organoids were sensitive to sorafenib again. ML264, a Kruppel-like factor 5 (KLF5) inhibitor, was found to be a suppressor of the KLF5/Bcl-2/caspase3 signaling pathway and can restore the sensitivity to oxaliplatin in oxaliplatin-resistant colorectal tumoroids by the inhibition of antiapoptotic effects.²⁷⁰

Organoids can also be used to study rare genetic diseases and identify personalized treatments. By deriving organoids from patients with genetic diseases, researchers can study the effects of different drugs and gene therapies on these tissues, and develop tailored treatments for individual patients. Sampaziotis et al.²⁷¹ applied 3D culture technology to construct CF organoid models from iPSC-derived cholangiocytes and explored the response of the CF organoids to VX-809 CF therapy. As mentioned above, FIS is considered as a prospective biomarker to predict the response to CFTR-modulating drugs. Technological advances in genetic engineering, especially CRISPR–Cas9 genome editing, allow gene repair to be a promising treatment for some diseases, and organoids provide a good platform to develop and validate novel gene therapies.²⁷² Schwank et al.²⁷³ pioneered the successful application of CRISPR/Cas9 to human-derived organoids. They restored the CFTR function of intestinal organoids by correcting the common mutation F508del in CF. More recently, Geurts et al.²⁷⁴ employed CRISPR-based adenine base editors that enabled A-T to G-C base changes to successfully correct the W1282X and R553X mutations and achieve functional CFTR rescue in human rectal and airway organoids. A clinical trial (NCT04254705) evaluates the response to CFTR-modulators in intestinal organoids of CF patients with R334W mutations.

Finally, organoids can be used to study the effects of environmental toxins and other factors on human tissues. By exposing organoids to different environmental conditions, researchers can study the effects of air pollution, toxic chemicals, and other factors on human health, and identify personalized strategies for reducing exposure and preventing disease. For example, Kim et al.²⁷⁵ exposed human iPSC-derived alveolar organoids to diesel PM2.5 to investigate its developmental toxicity, and the authors showed that diesel PM2.5 could upregulate the oxidative stress and EMT expression to impair alveolar epithelium growth and contribute to high susceptibility to SARS-CoV-2. The lung toxicity of common air pollutants including benzo(a)pyrene, nano-carbon black, and nano-SiO2 has been assessed with human iPSC-derived AT2-like cell organoids.²⁷⁶ Meanwhile, human airway organoids were employed as models for toxicological assessment of emerging inhaled pollutants of tire wear particles.²⁷⁷ Nicotine exposure in pregnant women has been shown to cause harmful birth outcomes and effects on cerebral development.²⁷⁸ Several studies have investigated the role of nicotine in abnormal human brain development and the potential mechanisms with organoid system models.^{279, 280} Heavy metals are pervasive and persistent environmental toxins with the feature of accumulation in organisms, which may lead to multiorgan damage. The liver and cardiac organoids have been used to evaluate the toxic effects of lead, mercury, and thallium, and these heavy metals were found to inhibit the heart rates of heart organoids.²⁸¹ Through the mouse intestinal organoid model, it was found that excessive intake of cadmium could activate the Notch pathway, increase the synthesis of ROS, cause intestinal mucosal damage, and more susceptible to Salmonella infection.²⁸² In addition, the brain organoids treated with Cd exhibited increased neuron apoptosis, disrupted proliferation of neural progenitor cells, and change gene expression profiles, leading to neuroinflammation and ciliogenesis restriction.²⁸³ However, Cd was not prone to hamper the neural differentiation of cerebral organoids. Organic pollutants with chemical toxicity are difficult to be degraded, and tend to accumulate in organisms in various ways, causing dysfunction and failure of human organs.²⁸⁴ Evidence has pointed out that polybrominated diphenyl ethers are more likely to disrupt the differentiated NPCs in an hESC neural differentiation model and exert their cytotoxicity relying on the developmental stage.²⁸⁵ Bisphenols are widely used to produce epoxy resins, and polycarbonate plastics, which have been shown to have endocrine disruptor effects and developmental toxicity in mammalian embryos.^{286, 287} Recently, the retinotoxicity of BPA, TBBPA, and TBBPS has been evaluated with human retinal organoids derived from ESCs.²⁸⁸ It was reported that all three bisphenols could adversely affect retinal organoid development and that TBBPS had higher toxicity. Furthermore, bisphenols induced retinotoxicity in a time-dependent manner. Meanwhile, exposure to BPS and BPF, the alternative chemicals of BPA, could increase the branches and alter the protein expression of mammary organoids, which differed from those induced by estrogen and might raise the risk of breast cancer occurrence.²⁸⁹ Nanomaterials can be utilized as powerful and flexible tools for the diagnosis and treatment of human diseases as well as engineering and environmental protection fields. However, nanoparticles have been pointed to lay an adverse influence on the nervous, respiratory, circulatory, and reproductive systems and could increase the risk of malformations and cancer.^290-295 Organoid models open a new door for studying the toxicological effects of nanomaterials. Mekky et al.²⁹⁶ offered confirmation of the feasibility of liver organoids for the hepatotoxic assessment of Mg nano. The work by Zuo's team developed kidney organoids as a toxicity screening platform to test black phosphorus quantum dots.²⁹⁷ Overall, the use of organoids in precision medicine has the potential to revolutionize the way we develop and deliver medical treatments, by providing more accurate and personalized models of human tissues that can be used to predict individual patient responses to different drugs and environmental factors. Given the enormous potential of organoids in biomedical applications such as drug discovery, efficacy and safety testing, and clinical personalized medicine, several organoid-based preclinical or clinical trials are already registered or underway (Table 3).

4.4 Regenerative medicine

Regenerative medicine refers to biological and engineering methods to repair, regenerate, or replace damaged or absent cells, tissues, or organs to restore normal structure and function. Organ transplantation is crucial for treating patients suffering from organ failure, but it faces various challenges, such as severe graft rejection and a growing shortage of donors. To overcome these obstacles, in vitro-cultured organoids have emerged as a promising alternative, offering an unlimited supply of potential donors for autologous transplantation therapy and tissue repair. Several experiments have clarified that organoids transplanted into animals could restore impaired organ function.^298-301 Yang et al.³⁰² constructed bioprinted hepatorganoids using 3D printing technology and transplanted them into immunodeficient mice with tyrosinemia type I and liver failure. The organoids could form functional vasculature systems after transplantation. The serum levels of liver function biomarkers significantly declined, indicating alleviation of liver injury and an apparent therapeutic effect of hepatorganoids on tyrosine metabolism defects. Implantation of pancreatic islet-like organoids generated by planting pancreatic islet cells into a bioscaffold has the ability to restore insulin secretion and decrease glucose levels in type 1 diabetic mice.³⁰³ Human brain organoids could keep survival, form long lateral hypothalamus projections and functionally incorporate into the brain circuits after transplantation into the medial prefrontal cortex of mice.³⁰⁴

Moreover, there are still some patients presenting with the dysfunction or defects of certain tissues or organs such as biliary atresia, bile tract injury, and short bowel syndrome due to congenital and acquired factors, for which effective therapeutic regimens are usually unavailable. The emergence and advancement of organoid technology provides powerful support for the generalization and application of tissue repair and regeneration. Sampaziotis et al.^{305, 306} pioneered the use of human bile duct epithelial organoids to repair the gallbladder and bile duct of mice. Cholangiocyte organoids were generated using normal human bile duct tissue. After being marked by a green fluorescent protein, these organoids were seeded on polyglycolic acid or densified collagen scaffolds to repair the gallbladder or bile duct of immunodeficient mice. The results showed that the mice transplanted with cholangiocyte organoids had extended survival, and their bile ducts were unobstructed, without manifestations of obstructive jaundice and increased bilirubin and alkaline phosphatase. More recently, a study injected human-derived gallbladder organoids marked by red fluorescent protein into the intrahepatic ducts of isolated human livers.³⁰⁷ The authors discovered red fluorescent cells in the injected bile ducts, without duct dilatation or obstruction, and the transplanted cholangiocytes expressed key biliary markers. The results implied that organoids can be applied to repair human bile ducts. Similar findings were described in a study by Roos et al.³⁰⁸ Bile cholangiocyte organoids rapidly repopulate decellularized extrahepatic biliary duct scaffolds and restore the monolayer of cholangiocyte-like cells in vitro. Jejunum organoids derived from 12 kids with intestinal failure were seeded into human intestinal scaffolds and able to differentiate into columnar epithelial cells with crypt units that fully covered the scaffolds, which could reappear several physiological jejunal functions.³⁰⁹ Mouse transplantation experiments exhibited that these grafts survived and built a luminal structure. Similarly, Sato's team recently reported a small intestinalized colon (SIC) generated by transplanting small intestinal epithelium onto the colon surface.³¹⁰ The authors suggested that SIC could form the nascent villus and subepithelial lymphatic structures that are only observed in the small intestine. Furthermore, in SBS rats, xenotransplanted SIC could establish a complete vascular system and exert small intestine function, leading to improved survival and a low risk of intestinal failure.