This detailed book collects original protocols aimed at encouraging and stimulating the scientific community to design and produce models for the laboratory that mimic cell guidance conditions as they occur in vivo. The protocols collected describe powerful strategies to exploit chemical cues involved in cell differentiation processes. Special emphasis is given to the use of methods for purification and characterization of exosomes and other secreted vesicles, as well as micro and non-coding RNAs, that have been demonstrated to control the tuning of the in vivo micro and macro environment in order to ensure the optimal soluble environment in vitro. Written for the highly successful Methods in Molecular Biology series, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and practical, Next Generation Culture Platforms for Reliable In Vitro Models: Methods and Protocols serves as an ideal guide for researchers working toward developing these vital testing models for preclinical studies.

In recent years, many limits to stem cell research s reliance on murine models have become evident.Regenerative medicine however, requires solid intermediate models where the results obtained in the mouse can be translated and assessed carefully in order to safely apply them to the human. Divided into three parts, Stem Cells in Animals: Pre-clinic to Biodiversity focuses on stem cells in non-murine species. The first part presents an overview of the different pre-clinical models recently created in other, non-murine animal species including the porcine model for heart failure, iPSC in large animal species, Duchenne muscular dystrophy and canine embryo-derived stem cells and modeling for human diseases. The second part of the book describes the recent efforts to use stem cells for preserving endangered species including the snow leopard, the rhino and coral reefs. From this perspective, stem cells are an invaluable tool in the preservation of biodiversities. Frozen cells and gametes can be obtained from animals at risk of extinction as well as from microorganisms and corals suffering from pollution and heavy changes in the eco-system. This may allow the generation of stem cell lines and represents an exciting opportunity to support and ensure the conservation of precious varieties of living creatures. This discussion leads easily into the third section which discusses stem cell banking as a way of safeguarding these endangered species."

This volume focuses on stem cell research and disease modeling in non-murine species. The book is divided into three parts: Stem Cells for Pre-Clinical Models, Stem Cells in Non-Conventional Species, and Stem Cell Banking for the Future. The first section presents an overview of the different pre-clinical stem cell models recently created in animal species, including the porcine model for heart failure, iPSC in large animal species, Duchenne muscular dystrophy and canine embryo-derived stem cells and modeling for human diseases. This section also discusses the potential advantages and applications of these models. The second part of this book describes recent efforts to use stem cells for preserving endangered species, including the snow leopard and coral reefs. From this perspective, stem cells are an invaluable tool to preserve bio-diversities. Frozen cells and gametes can be obtained from animals at risk of extinction and even from microorganisms and corals suffering from heavy changes in the eco-system; this may allow the cultivation of a generation of stem cell lines and represents an exciting opportunity to support and ensure the conservation of precious varieties of living creatures. This discussion leads easily into the third section, which discusses stem cell banking as a way of safeguarding these endangered species.

This addition to the Springer Brief in Stem Cells series focuses on aspects related to the specific mechanisms that ensure and control pluripotency and cell commitment in domestic animal species. This topic is generating rapidly-increasing interest due to the great potential for domestic animal species to be used as intermediate biomedical models, between the mouse and the human. The Brief addresses why we need large animal models for regenerative medicine. It also describes early embryo development with a careful and specific analysis of the regulatory mechanisms driving cleavage, polarization and genome activation in domestic species. How pluripotency is compartmentalized in domestic species as well as the different aspects that make the derivation of stem cells in domestic species very difficult are also addressed.

This Brief offers a concise, handy overview of the main concepts related to Embryology, revisited through the novel concepts that are applied daily in stem cell research and cell therapy oriented investigations.It isbased on three main areas:

-The process involved in female gamete differentiation and maturation. The main aspects related to cell biology will be covered and an overview of the epigenetic regulation of gametogenesis will be presented.

-Early stages of embryo development with a careful analysis of the regulatory mechanisms driving cleavage, polarization and genome activation.

-Stem cell and gametogenesis.

The use of the oocyte as a possible source for the derivation of stem cell lines is discussed and depicted as a powerful tool to investigate oocyte potency and asymmetric imprinting. The potential biological implications are evaluated and use of stem cells to derive oocytesis presented."

This detailed book collects original protocols aimed at encouraging and stimulating the scientific community to design and produce models for the laboratory that mimic cell guidance conditions as they occur in vivo. The protocols collected describe powerful strategies to exploit chemical cues involved in cell differentiation processes. Special emphasis is given to the use of methods for purification and characterization of exosomes and other secreted vesicles, as well as micro and non-coding RNAs, that have been demonstrated to control the tuning of the in vivo micro and macro environment in order to ensure the optimal soluble environment in vitro. Written for the highly successful Methods in Molecular Biology series, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and practical, Next Generation Culture Platforms for Reliable In Vitro Models: Methods and Protocols serves as an ideal guide for researchers working toward developing these vital testing models for preclinical studies.