Plant Tissue Culture: Industrial Relevance and Future Directions.

Plant tissue culture has evolved in the last decades with several types of cultures being developed to promote a more sustainable food production system. Moreover, these cultures can be applied for the production of relevant metabolites with medicinal potential, thus contributing to nutrition and healthcare. Importantly, plant micropropagation has enabled agricultural expansion and tissue culture has emerged as a promising production alternative for several plants and their metabolites in the food, cosmetic, and pharmaceutical industries. Plant tissue cultures present several advantages over conventional propagation techniques as they are season independent, enabling a continuous supply of the plants/compounds of interest, with the guarantee of high phytosanitary quality. In addition, genetic uniformity is generally maintained, thus reducing chemical variability that can compromise safety and efficacy. Nevertheless, despite their undeniable potential, with many researchers focusing on new strategies to improve production yield in cell cultures, such as with the use of elicitors or resorting to metabolomics engineering, an effective and lucrative large-scale production has yet to be obtained. Indeed, only a few compounds with market value are produced in this regard and several limitations such as contaminations, low culture yield and production costs still need to be overcome in order to take advantage of the full potential of these techniques.

Predictive Value of Swab Cultures for Cryopreserved Flaps During Delayed Cranioplasties.

OBJECTIVE: To assess the predictive value of swab cultures of cryopreserved skull flaps during cranioplasties for surgical site infections (SSIs). METHODS: A retrospective review was conducted of consecutive patients who underwent delayed cranioplasties with cryopreserved autografts between 2009 and 2017. The results of cultures obtained from swabs and infected surgical sites were assessed. The accuracy, sensitivity, and specificity of swab cultures for SSIs were evaluated. RESULTS: The study included 422 patients categorized into two groups, swab and nonswab, depending on whether swab cultures were implemented during cranioplasties. The overall infection rate was 7.58%. No difference was seen in infection rates between groups. There were 18 false-positive and no true-positive swab culture results. All bacteria between swab cultures and SSI cultures were discordant. Meanwhile, there were 19 false-negative swab cultures. The results showed high specificity but low sensitivity for swab cultures to predict SSI occurrence and the pathogens. CONCLUSIONS: Owing to low accuracy and sensitivity, swab cultures of cryopreserved autografts should not be routinely performed during delayed cranioplasties.

Science shines in a new virtual SY-Stem.

The third 'Symposium for the Next Generation of Stem Cell Research' (SY-Stem) was held virtually on 3-5 March 2021, having been cancelled in 2020 due to the COVID-19 pandemic. As in previous years, the meeting highlighted the work of early career researchers, ranging from postgraduate students to young group leaders working in developmental and stem cell biology. Here, we summarize the excellent work presented at the Symposium, which covered topics ranging from pluripotency, species-specific aspects of development and emerging technologies, through to organoids, single-cell technology and clinical applications.

Modeling colorectal cancers using multidimensional organoids.

Organoids have revolutionized cancer research as highly adaptable models that enable an array of experimental techniques to interrogate tissue morphology and function. Because they preserve the genetic, phenotypic, and behavioral traits of their source tissue, organoids have gained traction as the most relevant models for drug discovery, tracking therapeutic response and for personalized medicine. As organoids are indisputably becoming a mainstay of cancer research, this review specifically addresses how colon-derived organoids can be perfected as multidimensional, scalable, reproducible models of healthy, pre-neoplastic and neoplastic conditions of the colon and for use in high-throughput "Phase-0" human clinical trials-in-a-dish.

Advances in modelling the human microbiome-gut-brain axis in vitro.

The human gut microbiome has emerged as a key player in the bidirectional communication of the gut-brain axis, affecting various aspects of homeostasis and pathophysiology. Until recently, the majority of studies that seek to explore the mechanisms underlying the microbiome-gut-brain axis cross-talk, relied almost exclusively on animal models, and particularly gnotobiotic mice. Despite the great progress made with these models, various limitations, including ethical considerations and interspecies differences that limit the translatability of data to human systems, pushed researchers to seek for alternatives. Over the past decades, the field of in vitro modelling of tissues has experienced tremendous growth, thanks to advances in 3D cell biology, materials, science and bioengineering, pushing further the borders of our ability to more faithfully emulate the in vivo situation. The discovery of stem cells has offered a new source of cells, while their use in generating gastrointestinal and brain organoids, among other tissues, has enabled the development of novel 3D tissues that better mimic the native tissue structure and function, compared with traditional assays. In parallel, organs-on-chips technology and bioengineered tissues have emerged as highly promising alternatives to animal models for a wide range of applications. Here, we discuss how recent advances and trends in this area can be applied in host-microbe and host-pathogen interaction studies. In addition, we highlight paradigm shifts in engineering more robust human microbiome-gut-brain axis models and their potential to expand our understanding of this complex system and hence explore novel, microbiome-based therapeutic approaches.

[Tridimensional in vitro models of nervous and immune systems in the skin]. / Modélisation tridimensionnelle in vitro des systèmes nerveux et immunitaire de la peau.

The immune system and the sensory nervous system are responsible for perceiving danger under distinct yet complementary forms. In the last few years, neuroimmune interactions have become an important topic of dermatological research for conditions including wound healing, atopic dermatitis and psoriasis. We present here a selection of tridimensional in vitro models that reproduce skin structure and integrate an immune or a sensory function. Future evolutions of such models are expected to greatly contribute in a better understanding of reciprocal influences between sensory nervous system and immune system.

TITLE: Modélisation tridimensionnelle in vitro des systèmes nerveux et immunitaire de la peau. ABSTRACT: Le système immunitaire et le système nerveux sensoriel sont responsables de la perception du danger, sous des formes distinctes mais complémentaires. Ces dernières années, les interactions neuro-immunes se sont imposées comme un axe de recherche important en dermatologie pour comprendre la cicatrisation, la dermatite atopique ou le psoriasis. Nous présentons ici une sélection de modèles tridimensionnels in vitro reproduisant la structure de la peau et intégrant une fonction immunitaire ou sensorielle. Les évolutions futures de ces modèles permettront d'obtenir une vision aussi complète que possible des influences réciproques entre système immunitaire et système nerveux sensoriel.

[Dental stem cells: myth or hope in neuroregenerative medicine?] / Cellules souches dentaires : mythe ou espoir en médecine neurorégénératrice ?

The use of dental stem cells has raised many hopes in the development of new treatments for neurodegenerative diseases. According to current statistics, about 1 in 6 people in the world would be affected by a neurological disease. This number continues to increase as the world's population ages, making neurodegenerative diseases probably the one of the major challenges of public health in the 21st century. Neurodegenerative diseases are characterized mainly by a progressive loss of cognitive abilities and patient autonomy related to loss and degeneration of neurons in brain structures. Unfortunately, today, the only treatments available for this type of disease do only relieve the symptoms, they do not treat them, and few clinical trials have been truly convincing to date. Hence, hope lies for these diseases in the development of other therapeutic approaches. As such, dental stem cells could be a promising area of research because of their rapid growth, their great capacity for differentiation into different types of cells (among neuronal ones for some of them) and how easy they can be obtained, without raising ethical issues as for example for embryonic stem cells.

[Retinal organoids as a new tool for understanding and treating retinal diseases]. / Les organoïdes de rétine - Un nouvel outil pour comprendre et traiter les maladies rétiniennes.

Generation of retinal organoids from pluripotent stem cells represents an important advance in the study of retinal development and offer new perspectives for the study of retinal diseases missing suitable animal models. Understanding the key stages of retinal development in vertebrates enabled to design protocols to generate self-organized three-dimensional structures derived from pluripotent stem cells and containing all retinal cell types. In addition to their application in basic research, such as the characterization of molecular and cellular mechanisms in retinal pathophysiology, these miniature organs also open up encouraging prospects in the field of cell therapy or the screening of therapeutic molecules, although some obstacles remain to be overcome.

TITLE: Les organoïdes de rétine - Un nouvel outil pour comprendre et traiter les maladies rétiniennes. ABSTRACT: Les organoïdes de rétine dérivés de cellules souches pluripotentes représentent une avancée importante pour l'étude du développement de la rétine et offrent de nouvelles possibilités pour l'étude des maladies associées difficilement modélisables chez l'animal. La compréhension des étapes clefs du développement de la rétine chez les vertébrés a conduit à la mise au point de protocoles permettant d'obtenir, à partir de cellules souches pluripotentes, des structures tridimensionnelles auto-organisées contenant l'ensemble des types cellulaires de la rétine. Outre les applications en recherche fondamentale, ces organes miniatures ouvrent des perspectives encourageantes dans le domaine de la thérapie cellulaire ou le criblage de molécules thérapeutiques.

[Emergence of 3D human fatty liver models engineered in the laboratory]. / L'émergence des modèles miniatures de foie gras humain en 3D générés en laboratoire.

Organoids offer an elegant approach to model human diseases and test new drugs. Nonalcoholic fatty liver disease (NAFLD) whose incidence has dramatically increased in recent years with the rise of obesity, is defined by triglyceride accumulation in hepatocytes, inflammation, liver injury, and progression to fibrosis. There is currently no approved therapy but many pathways are being explored. Two American teams have created mini-steatotic livers using different approaches, both using induced pluripotent stem cells (iPS), thus offering new tools to test developing drugs.

TITLE: L'émergence des modèles miniatures de foie gras humain en 3D générés en laboratoire. ABSTRACT: Les organoïdes constituent une approche de choix pour modéliser a minima une maladie humaine et tester l'efficacité thérapeutique de certaines drogues. La stéatopathie métabolique ou maladie du foie gras, dont l'incidence a considérablement augmenté avec l'accroissement de l'obésité dans les pays développés, se caractérise par l'accumulation de triglycerides dans l'hépatocyte et une atteinte hépatique pouvant évoluer vers la fibrose. Il n'existe pas de traitement efficace, mais de nombreuses pistes sont actuellement explorées. Deux équipes américaines ont récemment utilisé les cellules souches pluripotentes induites (iPS) et la culture muticellulaire pour modéliser un mini-foie stéatosique par deux approches différentes, offrant ainsi de nouveaux outils pour tester les drogues en cours de développement.

Microphysiological Systems: A Pathologist's Perspective.

High-throughput in vitro models lack human-relevant complexity, which undermines their ability to accurately mimic in vivo biologic and pathologic responses. The emergence of microphysiological systems (MPS) presents an opportunity to revolutionize in vitro modeling for both basic biomedical research and applied drug discovery. The MPS platform has been an area of interdisciplinary collaboration to develop new, predictive, and reliable in vitro methods for regulatory acceptance. The current MPS models have been developed to recapitulate an organ or tissue on a smaller scale. However, the complexity of these models (ie, including all cell types present in the in vivo tissue) with appropriate structural, functional, and biochemical attributes are often not fully characterized. Here, we provide an overview of the capabilities and limitations of the microfluidic MPS model (aka organs-on-chips) within the scope of drug development. We recommend the engagement of pathologists early in the MPS design, characterization, and validation phases, because this will enable development of more robust and comprehensive MPS models that can accurately replicate normal biology and pathophysiology and hence be more predictive of human responses.

Progress of co-culture systems in cartilage regeneration.

INTRODUCTION: Cartilage tissue engineering has rapidly developed in recent decades, exhibiting promising potential to regenerate and repair cartilage. However, the origin of a large amount of a suitable seed cell source is the major bottleneck for the further clinical application of cartilage tissue engineering. The use of a monoculture of passaged chondrocytes or mesenchymal stem cells results in undesired outcomes, such as fibrocartilage formation and hypertrophy. In the last two decades, co-cultures of chondrocytes and a variety of mesenchymal stem cells have been intensively investigated in vitro and in vivo, shedding light on the perspective of co-culture in cartilage tissue engineering. AREAS COVERED: We summarize the recent literature on the application of heterologous cell co-culture systems in cartilage tissue engineering and compare the differences between direct and indirect co-culture systems as well as discuss the underlying mechanisms. EXPERT OPINION: Co-culture system is proven to address many issues encountered by monocultures in cartilage tissue engineering, including reducing the number of chondrocytes needed and alleviating the dedifferentiation of chondrocytes. With the further development and knowledge of biomaterials, cartilage tissue engineering that combines the co-culture system and advanced biomaterials is expected to solve the difficult problem regarding the regeneration of functional cartilage.

Challenges in Bio-fabrication of Organoid Cultures.

Three-dimensional (3D) organoids have shown advantages in cell culture over traditional two-dimensional (2D) culture, and have great potential in various applications of tissue engineering. However, there are limitations in current organoid fabrication technologies, such as uncontrolled size, poor reproductively, and inadequate complexity of organoids. In this chapter, we present the existing techniques and discuss the major challenges for 3D organoid biofabrication. Future perspectives on organoid bioprinting are also discussed, where bioprinting technologies are expected to make a major contribution in organoid fabrication, such as realizing mass production and constructing complex heterotypic tissues, and thus further advance the translational application of organoids in tissue engineering and regenerative medicine as well drug testing and pharmaceutics.

Pluripotent Stem Cell-Derived Human Tissue: Platforms to Evaluate Drug Metabolism and Safety.

Despite the improvements in drug screening, high levels of drug attrition persist. Although high-throughput screening platforms permit the testing of compound libraries, poor compound efficacy or unexpected organ toxicity are major causes of attrition. Part of the reason for drug failure resides in the models employed, most of which are not representative of normal organ biology. This same problem affects all the major organs during drug development. Hepatotoxicity and cardiotoxicity are two interesting examples of organ disease and can present in the late stages of drug development, resulting in major cost and increased risk to the patient. Currently, cell-based systems used within industry rely on immortalized or primary cell lines from donated tissue. These models possess significant advantages and disadvantages, but in general display limited relevance to the organ of interest. Recently, stem cell technology has shown promise in drug development and has been proposed as an alternative to current industrial systems. These offerings will provide the field with exciting new models to study human organ biology at scale and in detail. We believe that the recent advances in production of stem cell-derived hepatocytes and cardiomyocytes combined with cutting-edge engineering technologies make them an attractive alternative to current screening models for drug discovery. This will lead to fast failing of poor drugs earlier in the process, delivering safer and more efficacious medicines for the patient.

Use of additives, scaffolds and extracellular matrix components for improvement of human pancreatic islet outcomes in vitro: A systematic review.

Pancreatic islet transplantation is an established treatment to restore insulin independence in type 1 diabetic patients. Its success rates have increased lately based on improvements in immunosuppressive therapies and on islet isolation and culture. It is known that the quality and quantity of viable transplanted islets are crucial for the achievement of insulin independence and some studies have shown that a significant number of islets are lost during culture time. Thus, in an effort to improve islet yield during culture period, researchers have tested a variety of additives in culture media as well as alternative culture devices, such as scaffolds. However, due to the use of different categories of additives or devices, it is difficult to draw a conclusion on the benefits of these strategies. Therefore, the aim of this systematic review was to summarize the results of studies that described the use of medium additives, scaffolds or extracellular matrix (ECM) components during human pancreatic islets culture. PubMed and Embase repositories were searched. Of 5083 articles retrieved, a total of 37 articles fulfilled the eligibility criteria and were included in the review. After data extraction, articles were grouped as follows: 1) "antiapoptotic/anti-inflammatory/antioxidant," 2) "hormone," 3) "sulphonylureas," 4) "serum supplements," and 5) "scaffolds or ECM components." The effects of the reviewed additives, ECM or scaffolds on islet viability, apoptosis and function (glucose-stimulated insulin secretion - GSIS) were heterogeneous, making any major conclusion hard to sustain. Overall, some "antiapoptotic/anti-inflammatory/antioxidant" additives decreased apoptosis and improved GSIS. Moreover, islet culture with ECM components or scaffolds increased GSIS. More studies are needed to define the real impact of these strategies in improving islet transplantation outcomes.

Is the future of meat palatable? Perceptions of in vitro meat as evidenced by online news comments.

OBJECTIVE: To understand current public perceptions of in vitro meat (IVM) in light of its potential to be a more environmentally sustainable alternative to conventional meat. DESIGN: A qualitative content analysis of the comments made on online news articles highlighting the development of IVM and the world's first IVM hamburger in August 2013. SETTING: News article comment sections across seven US-based online news sources (The New York Times, The Los Angeles Times, The Washington Post, The Wall Street Journal, USA Today, Cable News Network and National Public Radio). SUBJECTS: Four hundred and sixty-two commenters who made eight hundred and fourteen publicly available online comments addressing IVM. RESULTS: Key themes in commenter perceptions of IVM included environmental and public health benefits, but also negative themes such as IVM's status as an unnatural and unappealing food. Overall, the tone of comments was more negative than positive. CONCLUSIONS: Findings suggest that while the environmental and public health motivations for developing and in turn consuming IVM resonate with some segments of the population, others find that reasoning both uncompelling and problematic. Concerns about IVM as an unnatural and risky product also appear to be a significant barrier to public acceptance of IVM. Supporters of IVM may wish to begin to develop a regulatory strategy for IVM to build public trust and explore messaging strategies that cast IVM as a new technology with benefits to individuals rather than primarily a solution to global challenges. Those in the public health nutrition field can make an important contribution to the emerging public discussion about IVM.

Ovarian follicle culture: advances and challenges for human and nonhuman primates.

The removal and cryostorage of ovarian cortical biopsies is now offered as a fertility preservation option for young women. The only available option to restore fertility using this tissue is by transplantation, which may not be possible for all patients. The full potential of this tissue to restore fertility could be achieved by the development of in vitro systems that support oocyte development from the most immature stages to maturation. The techniques of in vitro growth (IVG) combined with in vitro maturation (IVM) are being developed with human tissue, but comparing different systems has been difficult because of the scarcity of tissue so nonhuman primates are being used as model systems. There are many challenges to developing a complete culture system that would support human oocyte development, and this review outlines the approaches being taken by several groups using tissue from women and nonhuman primate models to support each of the stages of oocyte development.