摘要
Los Organoides (O) son un tipo de cultivo celular 3D, que reproducen las características morfológicas y funcionales de diversos órganos o tejidos en un entorno in vivo. Se logran a través de la proliferación y diferenciación de Células Madres (CM) en distintas líneas celulares con capacidad de autoorganizarse. Son capaces de reproducir forma, función, expresión génica o repuesta a estímulos de la misma forma que el órgano original. Esto le ha permitido servir de base para múltiples investigaciones en el ámbito médico y odontológico. En los últimos años, se ha podido recrear con éxito, prácticamente, todos los órganos de nuestro cuerpo, como pulmones, hígado, tracto reproductivo, cerebro y muchos otros (Bartfeld, 2021). De la misma forma, son varias las líneas de investigación odontológicas desarrolladas. En específico, la creación de O de órganos orales como dientes y glándulas salivales, son las más reportadas (Oshima et al., 2017). Sin embargo, no son del común conocimiento del odontólogo general. Esta revisión sistemática exploratoria, tiene como objetivo presentar una visión general de la evidencia acumulada, determinado las áreas odontológicas de investigación, así como sus resultados. La investigación odontológica, en base al uso de O, es de alta calidad y de vanguardia, mostrando resultados prometedores, que auguran un gran futuro, tanto para la odontología como para los pacientes.
Organoids (O) are a type of 3D cell culture, which reproduce the morphological and functional characteristics of various organs or tissues in an in vivo environment. They are achieved through the proliferation and differentiation of Stem Cells (SC) into different cell lines with the ability to self-organize. They are capable of reproducing form, function, gene expression, or responses to stimuli in the same way as the original organ. This has allowed it to serve as the basis for multiple investigations in the medical and dental field. In recent years, it has been possible to successfully recreate practically all human organs, such as the lungs, liver, reproductive tract, brain and many others (Bartfeld, 2021). In the same way, there are several lines of dental research developed, specifically, the creation of O from oral organs such as teeth and salivary glands, are the most reported (Oshima et al., 2017). However, they are not common knowledge of the general dentist. This exploratory systematic review aims to present an overview of the accumulated evidence, determining the dental research areas, as well as their results. Dental research, based on the use of O, is of high quality and cutting-edge, showing promising results and a favorable future, both for dentistry and for patients.
摘要
Organoids,recognized as invaluable models in tumor and stem cell research,assume a pivotal role in the meticulous analysis of diverse datasets pertaining to their growth dynamics,drug screening processes and related phenomena.However,the manual scrutiny and conventional statistical methodologies employed in handling organoid data often grapple with challenges such as diminished precision and efficiency,heightened complexity,escalated human resource requirements,and a degree of subjectivity.Acknowledging the remarkable efficacy of artificial intelligence(AI)in the realms of biology and medicine,the incorporation of AI into organoid research stands poised to enhance the objectivity,precision and expediency of analyses.This integration empowers organoids to more effectively fulfill objectives such as disease modeling,drug screening and precision medicine.Notably,significant strides have been made in AI-driven analyses of organoid image data.The amalgamation of deep learning into image analysis facilitates a more meticulous delineation of the microstructural intricacies and nuanced changes within organoids,achieving a level of accuracy akin to that of experts.This not only elevates the precision of organoid morphology and growth recognition,but also contributes to substantial time and cost savings in research endeavors.Furthermore,the infusion of AI technology has yielded breakthroughs in the processing of organoid omics data,resulting in heightened efficiency in data processing and the identification of latent gene expression patterns.This furnishes novel tools for comprehending cellular development and unraveling the intricate mechanisms underlying various diseases.In addition to image data,AI techniques applied to diverse organoid datasets,encompassing electrical signals and spectra,have realized an unbiased classification of organoid types and states,embarking on a comprehensive journey towards characterizing organoids holistically.In the pivotal domain of drug screening for organoids,AI emerges as a stalwart companion,providing robust support for real-time process monitoring and result prediction.Leveraging high-content microscopy images and sophisticated deep learning models,researchers can dynamically monitor organoid responses to drugs,effecting non-invasive detection of drug impacts and amplifying the precision and efficiency of drug screening processes.Despite the significant strides made by AI in organoid research,challenges persist,encompassing hurdles in data acquisition,constraints in sample quality and quantity,and quandaries associated with model interpretability.Overcoming these challenges necessitates dedicated future research efforts aimed at enhancing data consistency,fortifying model interpretability,and exploring methodologies for the seamless fusion of multimodal data.Such endeavors are poised to usher in a more comprehensive and dependable application of AI in organoid research.In summation,the integration of AI technology introduces unparalleled opportunities to organoid research,resulting in noteworthy advancements.Nevertheless,interdisciplinary research and collaborative efforts remain imperative to navigate challenges and propel the more profound integration of AI into organoid research.The future holds promise for AI to assume an even more prominent role in advancing organoid research toward clinical translation and precision medicine.
摘要
In recent years,significant progress has been made in the study of endometrial epitheli-al organoids in the field of reproduction.Traditional two-dimensional cell culture models and animal ex-periments fail to accurately replicate the three-di-mensional structure and physiological functions of the endometrium,limiting the in-depth exploration of its normal physiological mechanisms and related disease mechanisms.Emerging organoid technolo-gies have provided new avenues for research.These organoids,formed by self-organization of stem cells or progenitor cells in a three-dimensional culture system,faithfully recapitulate the character-istics of endometrial glands in situ.Not only can these organoid models mimic the changes in the endometrium at different stages of the menstrual cycle,but they can also simulate the interaction be-tween the fertilized embryo and the endometrium.Moreover,organoid systems have become essential tools for fundamental research in the field of repro-duction and for disease research,including studies related to reproductive biology,drug screening and development,disease mechanism exploration,drug action mechanisms,drug combination therapies,and targeted therapies.These studies have provid-ed novel insights and methods for a deeper under-standing of the biological properties of the endome-trium,its disease mechanisms,and the develop-ment of therapeutic strategies for related disorders.
摘要
OBJECTIVE To construct an insulin-resistant(IR)small intestinal organoid model of mice and study the protective effect of flavanomarein(FM)on the intestinal mucosal barrier in the model.METHODS ①Small intestinal organoid models of C57BL/6J and db/db of mice were constructed.The expressions of Ki-67,E-cadherin(E-cad),lysozyme(Lyz)and mucin-2(Muc-2)in small intestinal organ-oids were detected by 3D immunofluorescence.RT-qPCR was used to detect the expressions of fibro-nectin(Fn),glucagon-like peptide-1(GLP-1)and peotide YY(PYY)mRNA while Western blotting was used to detect the expressions of Fn,GLP-1 and PYY protein.The Lyz secretion level was detected by ELISA.② Small intestinal organoids were divided into five groups:C57BL/6J mice 'small intestinal organ-oids as the normal control group,db/db mice' intestinal organoids as the IR model group,db/db mice small intestinal organoids with flavanomarein 25,50 and 100 μmol·L-1 intervention for 48 h as IR model+ FM groups.RT-qPCR was used to detect the expression of Lyz mRNA while Western blotting was used to detect the expression of Lyz protein.RESULTS ① On the 6th day of small intestinal organoid culture,a ring structure with a clear luminal structure was formed and an IR mouse small intestinal organoid model was established.3D Immunofluorescence detection showed that the established small intestinal organoids all expressed Ki-67,E-cad,Lyz and MUC-2.Compared with the normal control group,the expres-sion of Fn mRNA in the IR model group was significantly increased(P<0.05)while the expressions of GLP-1 and PYY mRNA were significantly decreased(P<0.05).Compared with the normal control group,the expression of Fn protein in the IR model group was significantly decreased(P<0.05)while the expressions of GLP-1 and PYY protein were significantly increased(P<0.05).ELISA results showed that compared with the normal control group,the secretion levels of Lyz in the IR model group were signifi-cantly decreased(P<0.01).② RT-qPCR results showed that compared with the normal control group,the expression of Lyz mRNA in the IR model group was significantly decreased(P<0.01).Compared with the IR model group,the expression of Lyz mRNA in the IR model+FM 50 and 100 μmol·L-1 groups was significantly increased(P<0.05,P<0.01).Western blotting results showed that compared with the normal control group,the expression of Lyz protein in the IR model group was significantly decreased(P<0.01).Compared with the IR model group,the expression of Lyz protein in the IR model+FM 50 and 100 μmol·L-1 groups was significantly increased(P<0.05,P<0.01).CONCLUSION The constructed IR mouse small intestinal organoid model provides a more complete in vitro research model for exploring the pathophysiological mechanism by which drug interventions help repair the intestinal mucosal barrier.FM may maintain the intestinal mucosal barrier by reversing the decrease in Lyz expression levels in IR mice,thereby improving IR.
摘要
Organoids are novel in vitro models that can effectively simulate the complexities of tumor microenvironments.Compared to tra-ditional preclinical models,organoids retain most of the histological and molecular properties of the primary tumor;therefore,they are more useful for studying tumor heterogeneity,underlying functional pathways,and immune microenvironments as well as for research on biomarker discovery,drug screening,and individual chemotherapy.Furthermore,current limitations,challenges such as low modeling suc-cess rates,high costs,and lack of standardization are expected to be overcome by continued innovations in bioengineering technologies and interdisciplinary integration.This article reviews the advantages,establishment processes,and prospects and challenges associated with the clinical application of organoids in bladder cancer.
摘要
Bone organoids are cellular structures cultured in vitro that can mimic the structure and function of real bone tissues. Currently, significant progress has been made in the researches of bone organoids, cartilage organoids, bone callus organoids, etc. These organoids can be constructed using combinations of stem cells or specific cell types and are characterized with the potential and function of osteogenesis. Despite the immense potential applications of bone organoids, their construction still faces several challenges. For instance, there are ongoing controversies regarding the types, sources, identification, and isolation methods of skeletal stem cells. Additionally, further research is needed to select and optimize extracellular matrices suitable for bone organoid construction. Vascularization of bone organoids is a crucial factor limiting their size. Meanwhile, breakthroughs in artificial intelligence technology offer new thoughts for the construction of bone organoids. Hurdles in fundamental researches and practical needs such as bone defect repair create new opportunities for the study of bone organoids. For this purpose, the authors systematically elucidated the current researches and challenges in the construction of bone organoids and discussed countermeasures to address these challenges, aiming to provide reference for researches and translational applications of bone organoids.
摘要
Objective:To construct a double-layer bone-on-a-chip containing bone matrix, with which the process of osteoblast and osteoclast differentiation in vitro is stimulated, aiming to provide a new platform for the development of osteoporosis medications. Methods:Software WorkSoild was used to design the double-layer and double-channel bone-on-a-chip and the template was fabricated by photolithography. With polydimethylsiloxane (PDMS) as the raw material, the main body of the chip was prepared by mold fabrication. The inlets and outlets of the four channels of the culture room were separated with bovine cortex bones and sealed with liquid storage columns. In the chip verification experiment, chips were divided into osteogenic and osteoclastic induction groups and osteogenic and osteoclastic control groups. In the osteogenic and osteoclastic induction groups, precursor cells of mouse embryonic osteoblast, MC3T3-E1 and mouse macrophage RAW264.7 were inoculated on the chip separately. Osteogenic induction lasted 14 days and osteoclastic induction 7 days. MC3T3-E1 cells and RAW264.7 cells were not induced in the osteogenic and osteoclastic control groups. The following indicators were observed: (1) Appearance and sealing performance of the chip: After the chip was prepared, photos were taken to observe its appearance and sealing tests were conducted to observe its sealing performance. (2) Biocompatibility: At 3 days after MC3T3-E1 cells were inoculated onto the chip and cultured and at 1, 3 and 5 days after RAW264.7 cells were inoculated onto the chip and cultured, the cell survival was observed with calcein acetoxymethyl ester/propidium iodide (AM/PI) staining and Cell Counting Kit 8 (CCK-8). (3) Osteogenic differentiation: Alkaline phosphatase (ALP) staining and alizarin red staining were performed on the cells in the osteogenic induction group to observe the osteogenic induction. RNA was collected from the osteogenic induction group and the osteogenic control group, the expression of osteoblast marker Runt-related transcription factor 2 (RUNX2), osteocalcin (OCN) and type I collagen (COL1A1) was detected by real-time florescent quantitative PCR (qPCR), and the differentiation degree and osteogenic ability of osteoblasts were observed. (4) Osteoclast differentiation: tartrate-resistant acid phosphatase (TRAP) staining was performed on cells in the osteoclastic induction group to observe osteoclast differentiation. RNA was extracted from the osteoclastic induction group and the osteoclastic control group for qPCR of osteoclast differentiation-related genes, and the expression levels of the osteoclast marker gene TRAP, cathepsin K (CTSK) and dendritic cell specific transmembrane protein (DC-STAMP) were detected.Results:The double-layer bone-on-a-chip containing bone matrix was 3 cm×3 cm in size and transparent as a whole. The structure of the system on the chip system was compact and had no seepage. It was shown by calcein AM/PI staining that at 3 days after MC3T3-E1 cells and RAW264.7 cells were cultured, very few red fluorescent dead cells were found. CCK-8 test showed that within 5 days after being cultured, the cell viability was all above 90%, indicating that the biocompatibility of the chip was good and the cells could survive and proliferate normally. The results of ALP and alizarin red staining showed that MC3T3-E1 cells successfully differentiated into osteoblasts and produced calcified nodules in the osteogenic induction group at 14 days after the induction. The qPCR results showed that the relative expression level of RUNX2 in MC3T3-E1 cells in the osteogenic induction group was 4.98±0.74, which was significantly higher than that of the control group (0.99±0.03) ( P<0.01). The relative expression level of OCN in MC3T3-E1 cells was 7.98±0.76, which was significantly higher than that of the control group (1.00±0.06) ( P<0.01). The relative expression level of COL1A1 in MC3T3-E1 cells was 7.07±0.56, which was significantly higher than that of the control group (0.97±0.03) ( P<0.01). The TRAP staining results showed that the RAW264.7 cells in the osteoclastic induction group differentiated to giant multinucleated osteoclasts, and TRAP protein was expressed in large quantity in the osteoclasts. The results of qPCR showed that the relative expression level of TRAP in RAW264.7 cells in the osteoclastic induction group was 3.35±0.37, which was significantly higher than that of the control group (1.01±0.06) ( P<0.01). The relative expression level of CTSK in RAW264.7 cells was 3.46±0.79, which was significantly higher than that of the control group (1.01±0.05) ( P<0.01). The relative expression level of DC-STAMP in RAW264.7 cells was 1.92±0.12, which was significantly higher than that of the control group (0.98±0.08) ( P<0.01). Conclusions:The double-layer bone-on-a-chip containing bone matrix is compact in structure, can be cultured in vitro for a long time, has good biocompatibility and can be used for inducing osteogenic and osteoclast differentiation. Therefore, it is expected to provide a new research platform for exploring the mechanism of osteoporosis and medication screening.
摘要
Objective:To study the in vitro construction of functional and self-renewing cartilage organoids based on cartilage acellular extracellular matrix (ECM) microcarriers.Methods:Fresh porcine articular cartilage was taken. The merely crushed cartilage particles were set as natural cartilage group and ECM microcarriers of appropriate particle size, which were prepared by the acellular method of combining physical centrifugation and chemical extraction, were set as microcarrier group. Cartilage organoids were constructed by loading human umbilical cord mesenchymal stem cells (hUCMSCs) and human chondrocytes (hCho) with a ratio of 3∶1 with microcarriers through a rotating bioreactor. The organoids with different induction times were divided into 0-, 7-, 14-, and 21-day induction groups. The cell residues of the microcarrier group and natural cartilage group were evaluated by 4′, 6-diaminidine 2-phenylindole (DAPI) fluorescence staining and DNA quantitative analysis. The retention of microcarrier components was observed by Safranin O and toluidine blue stainnings, and the collagen and glycosaminoglycan (GAGs) levels in the microcarrier group and the natural cartilage group were determined by colorimetric method and dimethyl-methylene blue (DMMB) method. The microcarriers were further characterized by scanning electron microscopy and energy dispersive spectroscopy. The hUCMSCs cultured with Dulbecco′s Modified Eagle′s Medium (DMEM) supplemented with fetal bovine serum (FBS) in a volume fraction of 10% was used as the control group and the hUCMSCs cultured with the microcarrier extract was used as the experimental group. Subgroups of hUCMSCs cultured at 3 time points: 1, 3 and 5 days were set up in the two groups separately. Cell Counting Kit 8 (CCK-8) was used to detect the biocompatibility of the two groups. The cellular activity of the organoids of the 0-, 7-, 14-, and 21-day induction groups was detected by live/dead staining and the self-renewal ability of the cartilage organoids of the 14-day induced group was identified by Ki67 fluorescence staining. The organoids of the 7-, 14-, and 21-day induction groups were detected by RT-PCR in terms of the expression levels of chondrogenesis-related marker aggrecan (ACAN), type II collagen (COL2A1), SRY-related high mobility group-box gene-9 (SOX9), cartilage hypertrophy-and mineralization-related marker type I collagen (COL1A1), Runt-related transcription factor-2 (RUNX2), and osteocalcin (OCN). Colorimetric and DMMB assays were performed to determine the ability of organoids in the 0-, 7-, 14-, and 21-day induction groups to secrete collagen and GAGs.Results:The results of DAPI fluorescent staining showed that the natural cartilage group had a large number of nuclei while the microcarrier group hardly had any nuclei. The DNA content of the microcarrier group was (7.8±1.8)ng/mg, which was significantly lower than that of the natural cartilage group [(526.7±14.7)ng/mg] ( P<0.01). Saffranin O and toluidine blue staining showed that the microcarrier was dark- and uniform-colored and it kept a lot of cartilage ECM components. The collagen and GAGs contents of the microcarrier group were (252.9±1.4)μg/mg and (173.4±0.8)μg/mg, which were significantly lower than those of the natural cartilage group [(311.9±2.2)μg/mg and (241.3±0.7)μg/mg] ( P<0.01). Scanning electron microscopy showed that the surface of the microcarriers had uneven and interleaved collagen fiber network. The results of energy spectrum analysis showed that elements C, O and N were evenly distributed in the microcarriers, indicating that the composition of the microcarrier was uniform. The microcarrier had good biocompatibility and there was no statistical significance in the results of CCK-8 test between the control group and the experimental group after 1 and 3 days of culture ( P>0.05). After 5 days of culture, the A value of the experimental group was 0.53±0.02, which was better than that of the control group (0.44±0.03) ( P<0.05). In the 0-, 7-, 14-, and 21-day induction groups, hUCMSCs and hCho were attached to the surface of the microcarriers, with good cellular activity, and the live/death rates were (70.6±1.1)%, (80.5±0.6)%, (94.5±0.9)%, and (90.8±0.5)% respectively ( P<0.01). There were a large number of Ki67 positive cells in cartilage organoids. RT-PCR showed that the expression levels of ACAN, COL2A1, SOX9, COL1A1, RUNX2 and OCN were 1.00±0.09, 1.00±0.24, 1.00±0.18, 1.00±0.03, 1.00±0.06 and 1.00±0.13 respectively in the 7-day induction group; 4.16±0.28, 5.09±1.25, 5.65±1.05, 0.47±0.01, 1.68±0.02 and 0.21±0.06 respectively in the 14-day induction group; 13.42±0.92, 3.07±0.21, 1.84±1.08, 2.72±0.17, 2.91±0.18 and 3.32±1.20 respectively in the 21-day induction group. Compared with the 7-day induction group, the expression levels of ACAN, COL2A1, SOX9 and RUNX2 in the 14-day group were increased ( P<0.05), but COL1A1 expression level was decreased ( P<0.05), with no significant difference in OCN expression level ( P>0.05). Compared with the 7-day induction group, the expression levels of ACAN, COL1A1 and RUNX2 in the 21-day induction group were significantly increased ( P<0.01), with no significant differences in the expression levels of COL2A1, SOX9 and OCN ( P>0.05). Compared with the 14-day induction group, the expression levels of ACAN, COL1A1, RUNX2 and OCN in the 21-day group were increased ( P<0.05 or 0.01), with no significant difference in the expression level of COL2A1 ( P>0.05), but the expression level of SOX9 was decreased ( P<0.05). The contents of collagen in 0-, 7-, 14-and 21-day induction groups were (219.15±0.48)μg/mg, (264.07±1.58)μg/mg, (270.83±0.84)μg/mg and (280.01±0.48)μg/mg respectively. The GAGs contents were (171.18±1.09)μg/mg, (184.06±1.37)μg/mg, (241.08±0.84)μg/mg and (201.14±0.17)μg/mg respectively. Compared with the 0-day induction group, the contents of collagen and GAGs in 7-, 14-, and 21-day induction groups were significantly increased ( P<0.01), among which the content of collagen was the lowest in 7-day induction group ( P<0.01) but the highest in the 21-day induced group ( P<0.01); the content of GAGs was the lowest in the 7-day induced group ( P<0.01) but the highest in the 14-day induction group ( P<0.01). Conclusions:The microcarriers prepared by combining physical and chemical methods are decellularized successfully, with more matrix retention, uniform composition and on cytotoxicity. By loading microcarriers with hUCMSCs and hCho, cartilage organoids are successfully constructed in vitro, which are characterized by good cell activity, self-renewal ability, strong expression of genes related to chondrogenesis and secretion of collagen and GAGs. The cartilage organoids constructed at 14 days of induction have the best chondrogenic activity.
摘要
Objective:To construct 3D-bioprinted organoid artificial skin derived from adult stem cells and investigate their effects on repair of skin defect in mice.Methods:The cell suspension mixture was prepared with human skin keratinocytes, fibroblasts and vascular endothelial cells with a ratio of 2∶1∶1 and cultured in ultra-low attachment plates, and morphological changes of cell spheres were observed with an inverted phase contrast microscope. After 7 days of culture, cell spheres were collected and immunofluorescence staining was performed to characterize the expression and structural distribution of the epidermis, dermis and blood vessels. The artificial skin composed of skin organoids were printed through 3D printing and morphology of printed artificial skin and dressing was observed. Ten immunodeficient balb/c female mice were divided into hydrogel group and organoid group, with 5 mice in each group with the method of random number table. The full-thickness skin defect model with a diameter of 1 cm was established in all mice, and the wound was covered with the hydrogel dressings in hydrogel group and with 3D-printed skin organoids of the same size in organoid group. Wound healing and healing rate of the two groups were observed at 0, 4, 8, 12 and 16 days after modeling. At 16 days after modeling, HE staining was performed on wound skin samples to observe the epidermal keratosis and dermal epidermal junction of the wound surface and Masson staining to observe the density of collagen fibers and dermal fiber thickness of the wound surface.Results:(1) The cell suspension mixture of keratinocytes, fibroblasts and vascular endothelial cells could self-aggregate into cell spheres in the ultra-low attachment plates, and it was observed with the inverted phase contrast microscope that the volume of cell spheres gradually increased with the extension of culture time. (2) Immunofluorescence staining of the cell spheres showed that epidermal markers such as keratin (K)1, K10, and K14 were expressed in the outer layer of the cell spheres, and dermal markers such as vimentin (VIM) and vascular markers CD31 were expressed in the core, which indicated the epidermis was located in the outer layer of the sphere, and the dermis and blood vessels were located in the core of the sphere, with the same structural characteristics of the skin organoids. (3) The 3D-printed organoid artificial skin and hydrogel dressing were round and transparent, with a diameter of 10 mm and a thickness of 1 mm. (4) As shown in the general observation of the wound surface, the wound area of both groups decreased with the extension of treatment time. The wound of the organoid group healed faster, which showed obvious epithelization at 4 days after modeling and basic wound healing at 16 days after modeling. At 0 day after modeling, there was no obvious difference in the appearance of wound surface between the two groups. At 4 and 8 days after modeling, the wound healing rates were (31.7±1.0)% and (52.4±5.4)% in the organoid group, and (24.3±6.8)% and (45.4±7.0)% in the hydrogel group ( P>0.05). At 12 and 16 days after modeling, the wound healing rates were (78.6±8.0)% and (91.1±5.6)% in the organoid group, and were (58.5±5.4)% and (71.9±7.8)% in the hydrogel group ( P<0.01). (5) HE staining showed that in the organoid group epidermal keratinization was found better, with the epidermis being more intact and well attached to the dermis. Epidermal keratinization was not complete in hydrogel group and the epidermis and dermis were obviously separated. Masson staining showed the formation of collagen fiber structures in the wound surface of both groups, which were blue and reticular. The collagen fiber structure was more compact and the dermal fiber thickness was smaller in the organoid group, while the collagen fiber structure was loose and the dermal fiber thickness was greater in the hydrogel group. Conclusions:Adult stem cells of skin can successfully form skin organoids in 3D culture conditions and organoid artificial skin can be constructed with 3D bioprinting technology. Compared with hydrogel dressing, 3D-bioprinted organoid artificial skin can significantly improve the healing rate in mice, with better epidermal keratinization and closer attachment of the epidermis to the dermis. Moreover, the collagen fiber structure of the wound is more compact, with smaller dermal fiber in thickness.
摘要
In recent years, advancements in microfabrication technology and tissue engineering have propelled the development of a novel platform known as organoid-on-a-chip for drug screening and disease modeling. This platform integrates organoids and organ-on-a-chip technologies, emerging as a promising approach for in vitro modeling of human organs. Organ-on-a-chip leverages microfluidic device to simulate the physiological environment of specific organs, offering a more dynamic and flexible setting that can mimic a more comprehensive human biological context. However, the lack of functional vasculature has remained a major challenge in this technology. Vascularization is crucial for the long-term cultivation and in vitro modeling of organoids, which is of great significance in drug development and personalized medical approaches. The authors reviewed the research progress in the construction of vascularized organoid-on-a-chip including the methods for constructing in vitro vascularized models, vascularization of organoids, etc, which may serve as a reference for the construction of fully functional vascularized organoid-on-a-chip.
摘要
Large skin defect caused by severe trauma is a common clinical problem with high incidence, great harm, difficult treatment and poor prognosis, which not only seriously affects the quality of patients′ life, but also threatens their lives. Large skin defects are difficult to heal by themselves and the main treatment is skin transplantation. However, the source of the autologous flap is limited and may cause secondary damage to patients. The artificial skin has poor mechanical integrity that cannot be integrated, causing formation of scars, and also has the risk of immune rejection. Skin organoid technology can extremely simulate the human skin tissue and its functions. Thus, it can overcome the shortcomings of the current skin wound treatment to a certain extent and provide a new treatment for the patients with large skin defects. At present, the construction methods of skin organoids are relatively mature, but each method has its advantages and disadvantages, and the best method has not been determined yet. Moreover, the structure and function of skin organoids are relatively simple, so there is still a relatively big gap between skin organoids and real human skin. Hence, the authors reviewed the research progress in skin organoid construction strategies from organoids′ skin organoid technology, and construction methods of skin organoids, hoping to provide a reference for the construction of skin organoids with more complex structures and functions in the future.
摘要
Liver regenerative medicine can use functional liver cells to repair or replace damaged liver tissue and it is expected to be rapidly developed as an alternative treatment to liver transplantation. However, regenerative medicine requires cells with stable proliferation ability and liver cell characteristics. Liver organoids are derived from adult stem cells or pluripotent stem cells. They can be proliferated in large quantities and cultured for a long time in vitro, meanwhile maintain genetic stability, and simulate the structural and functional characteristics of organs in the body, providing a new strategy for liver regeneration. This article reviews liver organoids and their research progress in liver regenerative medicine, and discusses their application potential and existing limitations.
摘要
As cell aggregates in three-dimensional culture derived from primary tissues or stem cells, organoids possess the ability to self-organize into organotypic structures, mimic the cellular microenvironment, and represent tissue physiology. The thyroid′s follicular tissue plays a crucial role in thyroid hormone biosynthesis. Despite prolonged in vitro expansion of thyroid follicles from adult tissues and pluripotent stem cells have been expanded for a long time, the development of thyroid organoid technology still encounters numerous challenges. Establishing a comprehensive thyroid organoid that closely mimics the human body′s actual conditions remains a research challenge. This article reviews the development process of thyroid, the related applications of existing thyroid organoid models and the methods employed in the construction.
摘要
Organoids are a novel disease model that is self-assembled from stem cells or malignant tumors and is used in clinical research. They are similar to tissues and organs in the body and have partially functional 3D cell structures. There are two types of traditional models for liver cancer research, i.e., in vivo models (animal models of liver cancer established by induction) and in vitro cell experiments using corresponding cell lines. Organoids have the advantages of the two types of traditional models and show unique advantages in tumor research. Traditional models cannot fully reflect the microenvironment of cells, which often leads to the inconsistency with clinical research findings, and the emergence of new research models provides a new direction for the research on liver cancer. This article reviews the research advances in liver cancer organoids, in order to provide a new perspective for future research on liver cancer.
摘要
Intestinal organoids are constructed by crypts or stem cells from the intestine under the 3D support of the culture matrix. They contain all mature cells of the intestine, and have become a new and efficient platform for studying the mechanism of intestinal diseases. Compared with 2D cell culture, organoids can not only more effectively simulate the physiological structure and function of the intestine, but also better restore the true ecology of the intestine in different external environments. Therefore, it is more widely used in the study of pathogenesis of different intestinal diseases. This article reviewed the new progress of intestinal organoids culture, and the application and progress of intestinal organoids in the pathogenesis of inflammatory bowel diseases, colorectal cancer and celiac disease in recent years, and also discussed the application of intestinal organoids in drug research and development and screening.
摘要
Chronic obstructive pulmonary disease ( COPD ) major chronic disease threatening public health with complex pathological mechanisms. The change of the cell microenvironment of the lung is an important part of the pathophysiology of COPD. Cell culture technology is an important method to investigate the pathological mechanism of COPD and evaluate the pharmacological effect of medicine. Here we introduce the composition of the cell microenvironment of the lung, the change of the cell microenvironment in the pathological process of COPD, and summarize the application of in vitro model mimics cell microenvironment of COPD in the study of mechanism. In addition, we aim to put forward the ideas of the in vitro model establishment of cell microenvironment of COPD.
摘要
Organoids are in vitro three-dimensional(3D)multicellular cultures that are generated through deploying the self-renewal and self-organizing capacities of stem cells.They recapitulate key structural and functional features of corresponding organs or tissues,providing an ideal in vitro model and research platform for the study of developmental biology,regenerative medicine,disease modeling and drug development.The conventional organoid culture system mainly relies on manual operations with lengthy and complicated procedures,which generate organoid cultures of individual variations and batch differences,limiting their translational applications.Therefore,to engineer the organoid culture system by introducing microfluidic chip technology to enhance the throughput and automation level,is of great significance for achieving large-scale,homogeneous,and standardized organoid cultures.This article reviews the current research progress of high-throughput and automated organoid chips and discusses the main limitations and potential challenges for the future study.
摘要
Objective To explore novel methods for efficient respiratory viral infection of organoids by microinjection and polarity inversion techniques.Methods Lung tissue samples were obtained from 8-week-old male C57BL/6 mouse,and respiratory epithelial cells were extracted to establish a transwell organoid culture model.The green fluorescent protein(GFP)labeled influenza virus PR8(GFP-PR8)was quantitatively injected into organoids by improving the traditional microinjection platform,and morphologic changes in organoids and the immunofluorescence staining characteristics of tight junction proteins and microtubule proteins were observed.Polarity inversion apical-out(AO)was induced by suspension culture,and the morphological characteristics of polarity inversion was determined by HE staining.Normal and inverted organoids were infected with PR8,and the infection efficiency and expression differences of key pathway genes under different virus concentrations were observed.Results Ordinary organoids showed a significant increase in volume after microinjection.Following PR8 injection,the efficiency of infection was significantly higher in the apical region of organoids,accompanied by noticeable damage,as evidenced by significant down-regulation of tight junction proteins and microtubule protein expression.After suspension culture of the organoids,the polarity of ciliated cells gradually inverted outward over time,and the proportion of AO organoids stabilized on the 6th day.The efficiency of viral infection significantly increased in the inverted organoids,accompanied by significant cellular damage.After PR8 infection at 0.01 MOI,AO organoids showed significant changes in the inflammatory pathway and differentiation-related genes,with the opposite trend observed after higher concentration of PR8 infection.Conclusion Both polarity inversion and microinjection techniques significantly enhance the efficiency of influenza virus infection in organoids,thereby facilitating organoid widespread application in the field of respiratory tract infections.
摘要
Objective To establish in vitro the small intestinal organoid culture system and to investigate the effect of lipopolysaccharide(LPS)on the growth of small intestinal organoids and the secretion of inflammatory factors.Methods In vitro,the small intestinal crypt cell mass of C57BL/6 mice was aseptically isolated,collected and embedded in organoid matrix.Under the support of complete medium,the small intestinal organoids with three-dimensional multi-leaf structure with small intestinal epithelioid structure were formed.The small intestinal organoids were subcultured after 5-7 d culture.On the third day after passage,the small intestinal organoids were randomly divided into different mass concentrations of LPS groups(0,150,175,200,225,250,275 and 300 mg/L).After 24 h and 48 h of LPS induction,morphological changes of small intestinal organoid growth and differentiation were observed.CCK-8 method was used to detect the effect of different time points and mass concentrations of LPS on the proliferative activity of small intestinal organoids after induction of inflammation.The effects of four different mass concentrations of LPS(0,175,200 and 225 mg/L)on expression levels of granulocyte-macrophage colony stimulating factor(GM-CSF),interleukin(IL)-1α,IL-6 and IL-10 in organoid culture supernatant at different times were detected by enzyme-linked immunosorbent assay(ELISA).Results The mouse small intestinal organoid culture system was preliminarily constructed.After different time and mass concentration of LPS induced inflammation of small intestinal organoids,it was observed by morphology that small intestinal organoids would have different degrees of expansion and apoptosis in lumen.The proliferation,differentiation and budding of damaged intestinal epithelial crypts or intestinal stem cells were also inhibited to varying degrees,indicating that the growth of small intestinal organoids would be limited to varying degrees after induced inflammation.The proliferation activity of small intestinal organoids decreased to varying degrees after 24 h and 48 h of LPS induction at 175-225 mg/L(P<0.05),but the cell viability was still greater than 50%.The levels of IL-1α,IL-6 and GM-CSF partially increased after induction with 200 mg/L and 225 mg/L LPS for 24 h and 48 h(P<0.05).The level of IL-10 decreased after induction with 200 mg/L LPS for 24 h and 48 h(P<0.05).Conclusion In this study,a model of intestinal inflammatory injury in vitro induced by LPS with different mass concentrations and time points is preliminarily constructed,which provides a more reliable research platform for the mechanism research of intestinal diseases and the screening of effective drugs in the future.
摘要
Objective To establish a culture method for micropapillary lung adenocarcinoma organoids and conduct targeted drug screening.Methods Organoids were extracted and cultured from a surgical tissue sample of a patient diagnosed with micropapillary lung adenocarcinoma,and the growth of lung cancer organoids was observed and recorded dynamically.The morphological and gene expression characteristics of tumor cells between lung cancer organoids and parental tissue were compared using hematoxylin eosin(HE)staining and immunohistochemical methods.Real time fluorescence quantitative polynucleotide chain reaction(qRT-PCR)method was used to detect gene mutations in lung cancer parental tissue and organoids.Finally,based on results of genetic testing,targeted drugs were selected and their therapeutic effects were verified.Results We have successfully cultured spherical organoids from micropapillary lung adenocarcinoma tissue,which can be passaged for at least 3 generations.HE staining results showed that the morphology of tumor cells in organoids was roughly consistent with that of parental tissue.The immunohistochemical results showed that the protein expression levels of various genes in lung cancer organoids and parental tissue were roughly the same.Results of gene mutation analysis showed that the mutated genes in lung cancer parental tissue and organoids were consistent,both reflecting RET fusion.The screening results of targeted drugs based on lung cancer organoids showed that vandertinib had the best anti-tumor effect in vitro.Conclusion Drug screening experiments based on micropapillary lung adenocarcinoma organoids can screen highly efficient targeted drugs in a short period of time,which may benefit patients with micropapillary lung adenocarcinoma.