For over 150 years, researchers have studied the (patho)physiology of the endocrine pancreas and devised treatment options for diabetes mellitus (DM). However, no cure has been developed so far. In dogs, diabetes mellitus type 1 (T1DM) is the most common presentation. Treatment consists of twice daily insulin injections, monitored by spatial blood glucose measurements. Even though dogs were instrumental in the discovery of insulin and islet transplantations, the treatment in diabetic dogs has remained unchanged for decades. Providing twice daily insulin injections is demanding for both owners and dogs and may result in hypoglycaemic events, creating the need for new treatment strategies. Novel regenerative medicine-based tools, such as improved β-cell culture protocols and artificial devices, have sparked hope for a cure. In human medicine, emerging technologies such as the transplantation of insulin-producing β-cells, generated by stem cell differentiation, with or without an encapsulation device, are currently tested in phase I/II clinical trials. As the pathogenesis of T1DM is remarkably similar between humans and dogs, novel treatment methods could be implemented in canine medicine. This review briefly summarises the physiology of the canine endocrine pancreas and the pathophysiology of canine DM before exploring current and possible future treatment options for canine DM.

Studying human placental development and function presents significant challenges due to the inherent difficulties in obtaining and maintaining placental tissue throughout the course of an ongoing pregnancy. Here, we provide a detailed protocol for generating trophoblast organoids from chorionic villi obtained during ongoing pregnancy. Our method results in efficient generation of trophoblast organoids from chorionic villus sampling, does not require preselection of chorionic villi, and controls contamination of decidual gland organoids. The resulting trophoblast organoids spontaneously form syncytiotrophoblasts that start secreting hCG hormone amongst other placenta-specific factors. Our approach facilitates the generation of trophoblast organoids from a variety of genetic backgrounds, including trisomies and gene mutations, and can be aligned with prenatal diagnostic routines. The protocol requires up to 14 days and can be carried out by users with expertise in cell culture.

Osteosarcomas are the most common primary malignant bone tumors and mostly affect children, adolescents, and young adults. Despite current treatment options such as surgery and polychemotherapy, the survival of patients with metastatic disease remains poor. In recent studies, punicalagin has reduced the cell viability, angiogenesis, and invasion in cell culture trials. The aim of this study was to examine the effects of punicalagin on osteosarcomas in a 3D in vivo tumor model. Human osteosarcoma biopsies and SaOs-2 and MG-63 cells, were grown in a 3D in vivo chorioallantoic membrane (CAM) model. After a cultivation period of up to 72 h, the tumors received daily treatment with punicalagin for 4 days. Weight measurements of the CAM tumors were performed, and laser speckle contrast imaging (LSCI) and a deep learning-based image analysis software (CAM Assay Application v.3.1.0) were used to measure angiogenesis. HE, Ki-67, and Caspase-3 staining was performed after explantation. The osteosarcoma cell lines SaOs-2 and MG-63 and osteosarcoma patient tissue displayed satisfactory growth patterns on the CAM. Treatment with punicalagin decreased tumor weight, proliferation, and tumor-induced angiogenesis, and the tumor tissue showed pro-apoptotic characteristics. These results provide a robust foundation for the implementation of further studies and show that punicalagin offers a promising supplementary treatment option for osteosarcoma patients. The 3D in vivo tumor model represents a beneficial model for the testing of anti-cancer therapies.

In this issue, we are pleased and honored to have an interview with Professor Hans Clevers, who is the Advisory Board Member of Organoids [...]

Existing mRNA COVID-19 vaccines have shown efficacy in reducing severe cases and fatalities. However, their effectiveness against infection caused by emerging SARS-CoV-2 variants has waned considerably, necessitating the development of variant vaccines. Ideally, next-generation vaccines will be capable of eliciting broader and more sustained immune responses to effectively counteract new variants. Additionally, in vitro assays that more closely represent virus neutralization in humans would greatly assist in the analysis of protective vaccine-induced antibody responses. Here, we present findings from a SARS-CoV-2 VLP vaccine encompassing three key structural proteins: Spike (S), Envelope (E), and Membrane (M). The VLP vaccine effectively produced neutralizing antibodies as determined by surrogate virus neutralization test, and induced virus-specific T-cell responses: predominantly CD4+, although CD8+ T cell responses were detected. T cell responses were more prominent with vaccine delivered with AddaVax compared to vaccine alone. The adjuvanted vaccine was completely protective against live virus challenge in mice. Furthermore, we utilized air–liquid-interface (ALI)-differentiated human nasal epithelium (HNE) as an in vitro system, which authentically models human SARS-CoV-2 infection and neutralization. We show that immune sera from VLP-vaccinated mice completely neutralized SARS-CoV-2 virus infection, demonstrating the potential of ALI-HNE to assess vaccine induced Nab.

Organoids have emerged as a powerful tool for studying organ development, disease modeling, and drug discovery due to their ability to mimic the in vivo structure and function of organs in a three-dimensional in vitro model. During in vivo organ maturation, the process of vascularization is crucial for the provision of nutrients and oxygen to cells and the removal of waste products as the organ increases in size. Similarly, organoids can grow to sizes greater than the millimeter scale, yet transport of oxygen and nutrients to the center becomes increasingly difficult, often resulting in the formation of a necrotic core. Herein, we provide a concise summary of the recent development of methods to initiate and maintain vascularization of organoids. Broadly, vascularization of organoids has been achieved primarily by two means: generating organoids that contain endothelial cells or employing the secretion of vascular growth factors to promote vascularization. Growth factors play a fundamental role in regulating blood vessel formation through chemical signals that cause changes in the cell–cell adhesions and ultimately the migration of endothelial cells. Furthermore, models with perfusable systems demonstrate that through the application of growth factors and cells, the vascular network in vascularization-based organoids can administer biological substances to the interior of the organoid, opening up new possibilities for long-term organoid culture in vitro. This goal is being realized through the development of bioengineering tools, such as vascularized organoids on a chip, which are currently tested for various organ systems, including the lung, brain, kidney, and tumors, with applications in cancer angiogenesis and metastasis research. Taken together, our review underlines the vast potential of vascularized organoids to improve the understanding of organ development, while also proposing exciting avenues of organoid-on-a-chip and disease modeling.

While research on stem cell-derived tissues and organoids is rapidly expanding, the technically related creation of complex embryoids has recently excited a vivid discussion since it raises ethical questions about individuation and the possible gain of viability. The present study focuses on the onset of organismic development and the proposed biological and legal definitions for the terms embryo, embryoid, and organoid. It is concluded that such considerations have become important for investigators’ choices of the appropriate in vitro model systems, allowing the formation of organoids vs. complex embryoids.

Meningiomas are the most common tumours of the central nervous system. According to the World Health Organization (WHO), this disease is classified into three different grades: 80% of meningioma patients present with benign grade I tumours, while less than 2% present with malignant grade III meningiomas. Despite affecting thousands of people worldwide, much remains unknown about this disease, and the development of systemic treatments is still far behind in comparison to other types of tumours. Therefore, forming 3D structures (spheroids and organoids) could facilitate research on the mechanisms of formation, proliferation, migration, and invasion of these, for the most part, benign tumours, while also helping in the process of drug development. To date, there are three published methods for the formation of meningioma organoids primarily derived from patient tissue samples. Organoids offer many advantages in the development of treatments because they recapitulate the cellular complexity within tumours. These new methodological advances could open a substantial number of possibilities for the further characterisation and treatment of meningiomas. This review includes an overview of the disease and a description and comparison of established protocols for meningioma organoid formation.

A three-dimensional cell culture in hydrogel beads can support cell growth and differentiation into multi-cellular structures, and these gel beads could be used as building blocks for more complex three-dimensional assemblies. This requires hydrogel beads that are robust enough to sort via FACS yet can be degraded by cell-secreted enzymes. Collagen polymers form hydrogels that are excellent cell growth substrates; however, collagen-containing hydrogel beads typically include additional polymers that limit their degradation. Here, we introduce a simple microfluidic method to generate robust, sortable, cell-laden collagen hydrogel beads. We use on-device pH control to trigger collagen gelation without exposing cells to low pH, ensuring high cell viability. We fabricate microfluidic devices to generate droplets with a wide size range, as demonstrated by production of both small (~55 µm diameter) and large (~300 µm diameter) collagen gels. All hydrogels are sufficiently robust to allow for sorting using FACS. Moreover, high cell viability is maintained throughout the process.

The generation of gastrointestinal tissues from human pluripotent stem cells has provided unprecedented insight into the molecular mechanisms that drive the patterning of the primitive gut tube. Previous work has identified bone-morphogenetic-protein (BMP) signaling as an important mediator of mid/hindgut versus foregut and hindgut versus midgut cell fate choice. Inhibition of BMP signaling during gut tube morphogenesis inhibits the expression of the pan-intestinal transcription factor CDX2. Treatment of CDX2+ mid/hindgut cultures with BMP patterns them into hindgut, which gives rise to colonic organoids (HCOs). While the role for BMP signaling is clear, the molecular mechanisms through which BMP signaling patterns the mid/hindgut and colon remain unclear. BMPs bind to BMP receptors, activating a signaling cascade that results in the activation of SMADs, which function as transcription factors. We hypothesized that one of these factors, SMAD1, would be necessary for establishing the CDX2 domain and the colon domain. Unexpectedly, endoderm derived from SMAD1-deficient induced pluripotent stem cells was capable of inducing CDX2 in response to WNT and FGF signaling. In addition, CDX2+ gut tube cultures could activate posterior HOX genes in response to BMP. However, examination of HCOs following cytodifferentiation revealed that SMAD1-deficient HCOs ectopically expressed small-intestinal markers despite expressing posterior HOX genes. These results indicate that there is redundancy of SMADs during early hindgut patterning but that SMAD1 is required for the inhibition of small-intestinal gene expression in HCOs.