Stem Cells: Latest Advances

Preface
Contents
1: Microelectrode Arrays: A Valuable Tool to Analyze Stem Cell-Derived Cardiomyocytes
1.1 Introduction
1.2 Methods for the Electrophysiological Characterization of hiPSC-CMs
1.2.1 Dye-Based Assessment of the Membrane Potential
1.2.2 Patch-Clamp Recordings
1.2.3 Whole Tissue Measurement with Extracellular Electrodes
1.3 MEA-Based Characterization of Physiological Parameters
1.3.1 The Field Potential Describes Cellular Electrophysiology
1.4 MEA-Based Evaluation of Drug-Induced Cardiotoxicity
1.4.1 CIPA—A New Paradigm in Cardiotoxicity Drug Screening
1.4.2 hiPSCs—An In Vitro System to Simulate Human Cardiac Physiology
1.5 Personalized Medicine
1.6 hiPSCs as In Vitro Cell Models for CVDs
1.6.1 Selective Overview of Current iPSC-Based Cell Models for CVDs
1.7 Conclusion and Future Perspective
References
2: CD34+ Stem Cells and Regenerative Medicine
2.1 Introduction
2.1.1 History
2.2 CD34+ Stem Cells and Peripheral Blood Stem Cell Transplantations
2.2.1 Evolution in CD34+ Stem Cell Knowledge
2.2.2 CD34+ Stem Cells and Ischemic Diseases
2.2.2.1 Heart Diseases
2.2.2.2 Stroke
2.2.2.3 Critical Limb Ischemia
2.2.3 CD34+ Cells and Non-Ischemic Diseases
2.2.3.1 Liver Insufficiency
2.2.3.2 Knee Arthrosis
2.3 Very Small Embryonic-Like Stem Cells
2.4 Conclusion
References
3: Mesenchymal–Hematopoietic Stem Cell Axis: Applications for Induction of Hematopoietic Chimerism and Therapies for Malignancies
3.1 Introduction
3.2 Hematopoietic Stem Cell and Bone Marrow Transplantation
3.2.1 Bone Marrow Transplantation
3.2.2 Bone Marrow Transplantation Challenges
3.2.3 Hematopoietic Stem Cell: History and Subtypes
3.3 Advancement of Conditioning Regimens for Bone Marrow Transplantation
3.3.1 Myeloablative Regimens for Malignant Cell Destruction and Allogeneic HSC Engraftment
3.3.2 Myeloablative vs Non-myeloablative vs Reduced Intensity Conditioning
3.3.3 Incorporating Monoclonal Antibody Therapy into RIC
3.4 Bone Marrow Dynamic Structure: HSC and MSCs Niches, Cells, Mechanisms, and Cross-Talk
3.4.1 Hematopoietic Stem Cell Niches
3.4.2 MSPCs and Their Role in HSC Niches
3.5 Endosteal/Osteoblastic HSC Niches
3.5.1 Osteoblasts
3.5.2 Osteoclasts
3.6 Nestin and Leptin
3.6.1 Perivascular HSC Niches
3.6.2 Leptin Receptor (LepR)
3.7 NG2
3.8 Sca-1 (Ly-6 A/E)
3.9 SCF/c-Kit
3.10 CXCL12
3.11 Challenging the Dogma of Necessity to Clear Space in HSC Niches for Engraftment of the Donor-Derived Hematopoiesis
3.11.1 Myeloablation and Its Impact on Multipotent HSCs
3.11.2 Myeloablation as a Means to Establish Niche Space for Allogeneic HSC Engraftment
3.11.3 Prevention of GVHD by Eliminating Donor-Derived Effector Cells and Supplementing Donor HSC Populations with Cell Subsets Aiding/Facilitating Their Engraftment
3.12 Potential Benefits of Clinical Adaptation of the MSPCs into Cytoreductive Therapies for Malignancies and Protocols for Induction of Allogeneic Hematopoietic Chimerism
3.12.1 MSPCs to Support Reconstitution of the Autologous Hematopoiesis Under Cytoreductive Therapies for Malignancies
3.12.2 MSPCs for Promoting Induction of Allogeneic Hematopoietic Chimerism
3.13 Summary and Conclusions
References
4: Mesenchymal Stem Cell-Derived Secretome: A New Remedy for the Treatment of Autoimmune and Inflammatory Diseases
4.1 Introduction
4.2 Therapeutic Potential of MSCs
4.3 Modulation of Immune Cell Phenotype and Function by MSC-Derived Secretome
4.4 MSC-Derived Secretome as a New Therapeutic Agent: Evidence Provided by Animal Studies
4.5 Clinical use of MSC-Derived Secretome
4.6 Conclusion and Future Directions
References
5: Cardiac Regenerative Therapy in Diabetes: Challenges and Potential Therapeutics
5.1 Introduction
5.2 Regenerative Therapy Approaches
5.2.1 Presence of Resident CSCs
5.2.2 Mechanical Scaffold and Cardiac Regeneration
5.2.3 Stem Cells and Cardiac Regeneration
5.2.4 Altering Resident Cells to Improve Cardiac Function
5.3 Differences in the Diabetic and nondiabetic Heart
5.3.1 The Heart Is a Highly Metabolically Active Organ
5.3.2 DM also Alters the Microenvironment of Myocardium
5.3.3 Diabetes and Heart Function Control
5.4 Challenges and Potential Therapeutic Strategies for Cardiac Regeneration in the Diabetic MI Heart
5.4.1 The Metabolic Status of the Transplanted Cells
5.4.2 The Toxic Microenvironment in the Diabetic Heart and Cell Survival
5.4.3 DM Reduces Contractility of Cardiomyocytes
5.5 Future Directions
5.5.1 Limitations of Current Approaches
5.5.2 Pitfalls and Alternatives of Current Regenerative Approaches
5.5.3 New Aspects to Consider Improving Regenerative Therapy
5.5.3.1 The Timing of Treatment
5.5.3.2 DM Causes Several Comorbidities
5.5.3.3 Key Aspects For Regenerating Diabetic Myocardium
References
6: Macrophage Response to Biomaterials in Cardiovascular Applications
6.1 Introduction
6.2 Role of Monocyte/Macrophages in Cardiac Repair
6.3 Biomaterials–Monocyte Interaction and Monocyte/Macrophage Differentiation
6.4 Biomaterials in Cardiac Repair and Regeneration
6.4.1 Synthetic Biomaterials
6.4.1.1 Degradable Polymer
Poly(Lactic Acid) (PLA) Nanofiber
Polyurethane Patches
6.4.1.2 Non-Degradable Polymer
Polyethylene Glycol (PEG)
Expanded Polytetrafluoroethylene
Polyethylene Terephthalate
6.4.2 Natural Biomaterials
6.4.2.1 Tissue-Derived (Natural) Biomaterials
Urinary Bladder Matrix-Derived Biomaterial
Small Intestinal Submucosa-Derived Biomaterial
Myocardium ECM-Derived Biomaterial
6.4.2.2 Nontissue-Derived (Natural) Biomaterials
Chitosan
Alginate
6.4.2.3 Purified Proteins
Collagen Hydrogels
Fibrin
6.4.2.4 Cell-Derived Matrices
6.5 Conclusions
References
7: Evolution of Stem Cells in Cardio-Regenerative Therapy
7.1 Introduction
7.2 First Generation
7.2.1 Bone Marrow Stem Cells
7.2.1.1 BM-Derived Stem Cells in Pre-Clinical Cardiovascular Research
Bone Marrow Mesenchymal Stem Cells
Bone Marrow Progenitor Cells
7.2.1.2 Bone Marrow Mononuclear Cells
7.2.1.3 Bone Marrow-Derived Stem Cells in Cardiovascular Clinical Research
Acute Myocardial Infarction
Chronic Ischemic Cardiomyopathy
Dilated Cardiomyopathy/Heart Failure
Mesenchymal Stem Cells
7.2.2 Adipose-Tissue Derived Stem Cells
7.3 Second Generation
7.3.1 Cardiac Stem Cells in Cardiovascular Regeneration
7.3.1.1 Brief History of Cardiac Stem Cells
7.3.1.2 Preclinical Evolution of CSCs in the Repair of Cardiovascular Diseases
7.3.1.3 Clinical Studies Involving CSCs in Cardiovascular Disease
7.3.1.4 Pros and Cons of CSCs
7.3.2 Embryonic Stem Cells
7.3.2.1 Embryonic Stem Cells by the Years
7.3.2.2 ESCs Transplantation and Integration into Host Tissue
7.3.2.3 Preclinical Studies on Cardiovascular Diseases with ESCs
7.3.2.4 Clinical Studies Involving hESCs in Heart Disease
7.3.2.5 Problems with ESCs
7.4 Third Generation
7.4.1 Induced Pluripotent Stem Cells
7.4.1.1 Pre-Clinical Studies on Cardiovascular Diseases with iPSCs
7.4.1.2 Limitations/Shortcomings with the Use of iPSCs
7.4.2 Skeletal Myoblasts
7.4.2.1 Limitations
7.4.3 Endometrial/Menstrual Blood-Derived Stem Cells
7.4.3.1 The Case for Endometrial-Derived Stem Cells
7.5 Exosomes
7.5.1 Pluripotent Stem Cell-Derived Exosomes
7.5.2 Multipotent MSC-Derived Exosomes
7.5.3 Multipotent Cardiac Stem and Progenitor Cell-Derived Exosomes
7.5.4 Advantages of Exosomes Over Traditional Stem Cell Therapies
7.6 Stem Cells as the Future of Cardiovascular Disease Therapy
References
8: Stem-Cell-Based Cardiac Regeneration: Is There a Place For Optimism in the Future?
8.1 Introduction
8.2 Stem-Cell-Based Therapy of Failing Heart
8.3 Primary Mechanisms of Action of Cellular Cell Therapy
8.4 Stem Cells in Adverse Cardiac Remodeling
8.4.1 Bone-Marrow-Derived Mononuclear Cells
8.4.2 Mesenchymal Stromal Cells
8.4.3 Cardiac-Derived Stem Cells
8.4.4 Pluripotent Stem Cells
8.5 Stem Cells in Clinical Trials for Patients with Ischemia-Induced Adverse Cardiac Remodeling
8.5.1 Human Allogeneic MSCs
8.5.2 Other Types of Cells
8.6 Ongoing Cell-Based Therapy Clinical Trials Among HF Patients
8.7 Conclusions
References
9: Dental Mesenchymal Stem/Progenitor Cells: A New Prospect in Regenerative Medicine
9.1 Introduction
9.2 Types of Dental Mesenchymal Stem/Progenitor Cells
9.2.1 Dental Pulp Stem/Progenitor Cells (DPSCs)
9.2.2 Properties and Differentiation Ability of DPSCs
9.2.3 Immunomodulatory Properties of DPSCs
9.2.4 Regulation of DPSCs’ Behaviors
9.2.5 DPSCs Versus Other MSCs
9.2.6 Preclinical and Clinical Applications of DPSCs
9.3 Stem/Progenitor Cells from Exfoliated Deciduous Teeth (SHEDs)
9.3.1 Properties and Differentiation Ability of SHEDs
9.3.2 Immunomodulatory Properties of SHEDs
9.3.3 Preclinical and Clinical Applications of SHEDs and their Secretome
9.4 Gingival Mesenchymal Stem/Progenitor Cells (GMSCs)
9.4.1 Properties and Differentiation Ability of GMSCs
9.4.2 Immunomodulatory Properties of GMSCs
9.4.3 Preclinical and Clinical Applications of GMSCs and their Secretome
9.5 Periodontal Ligament Stem/Progenitor Cells (PDLSCs)
9.5.1 Differentiation Ability of PDLSCs
9.5.2 Immunomodulatory Properties of PDLSCs
9.5.3 Factors that Regulate the Differentiation and Therapeutic Potential of PDLSCs
9.5.4 Clinical Applications of PDLSCs and their Secretome
9.6 Stem/Progenitor Cells from Apical Dental Papilla (SCAPs)
9.6.1 Immunomodulatory Properties of SCAPs
9.6.2 Differentiation Potential of SCAPs
9.6.3 Potential Application of SCAPs
9.7 Dental Follicle Stem/Progenitor Cells
9.7.1 Immunomodulatory Properties of DFSCs
9.7.2 DFSCs Differentiation Potential
9.7.3 Potential Application of DFSCs
9.8 Limitations Associated with Employing DMSCs in Tissue Regeneration
9.9 Conclusion
References
10: Stem Cell-Based Tissue Engineering for Functional Enamel and Dentin/Pulp Complex: A Potential Alternative to the Restorative Therapies
10.1 Introduction
10.2 Cells
10.2.1 Sources of Cells for Dental Tissue Engineering Strategies
10.2.2 Cells Used in Enamel Regeneration (Fig. 10.1 and Table 10.1)
10.2.2.1 Differentiated Cells
Differentiated Cells of Dental Origin
Differentiated Cells of Nondental Origin
10.2.2.2 Stem/Progenitor Cells
Stem/Progenitor Cells of Dental Origin
Stem/Progenitor Cells of Nondental Origin
10.2.3 Cells Used in Dentin–Pulp Complex Regeneration (Fig. 10.1 and Table 10.1)
10.2.3.1 Stem/Progenitor Cells
Stem/Progenitor Cells of Dental Origin
Stem/Progenitor Cells Derived from Human Adult Teeth
Stem/Progenitor Cells Derived from Developing Teeth
Induced Pluripotent Stem Cells
Stem/Progenitor Cells of Nondental Origin
10.3 Scaffolds
10.3.1 Definition
10.3.2 Natural Sources
10.3.3 Synthetic Sources
10.4 Requirements of an Ideal Scaffold
10.4.1 Porosity
10.4.2 Mechanical Properties
10.4.3 Biocompatibility
10.4.4 Immune Acceptance
10.5 Scaffolds Used in Enamel Regeneration (Fig. 10.2 and Table 10.1)
10.5.1 Synthetic Enamel Fabrication: Regenerating Enamel-Like Hydroxyapatite Microstructures
10.5.2 Enamel Regeneration via Cell-Based Strategies: Regenerative Treatment Requires Stem Cells, Scaffold, and Growth Factors
10.6 Scaffolds and Biodegradable Materials for Dentin and Pulp Regeneration (Fig. 10.2 and Table 10.1)
10.7 Signaling Molecules
10.7.1 Importance of Growth Factors and Signaling Molecules in Dental Regeneration
10.7.2 Signaling Molecules Used in Enamel Regeneration (Fig. 10.3 and Table 10.1)
10.7.3 Signaling Molecules Used in Dentin Regeneration (Fig. 10.3 and Table 10.1)
10.7.4 Signaling Molecules Used in Pulp Regeneration (Fig. 10.3 and Table 10.1)
10.8 Conclusion
References
11: Cell- and Stem Cell-Based Therapies for Liver Defects: Recent Advances and Future Strategies
11.1 Introduction
11.1.1 The Liver Is a Key Organ with an Astonishing Ability of Regeneration
11.1.2 Treatment of Liver Diseases Remains a Wide Unmet Medical Need for Both Medical and Patient Communities
11.2 Liver Cell Transplantation Is a New Therapeutic Modality Initially Designed to Substitute OLT
11.3 Lessons from Clinical Hepatocyte Transplantation Trial Cases
11.4 Stem Cells Are Developed as Second-Generation Cell Products for Liver
11.4.1 Regenerative Medicine
11.5 Extrahepatic Stem Cells
11.5.1 Hematopoietic Stem Cells
11.5.2 Pluripotent Stem Cells
11.5.3 Mesenchymal Stem Cells
11.6 Liver Stem Cells
11.6.1 Endogenous Stem Cells
11.6.2 Still Intrinsically Non-defined Stem/Progenitor Cells
11.7 Regulatory Framework
11.8 Concluding Remarks
References
12: Stem Cells: A Renewable Source of Pancreatic β-Cells and Future for Diabetes Treatment
12.1 Introduction
12.2 Diabetes and Stem Cell Function
12.2.1 Hyperglycemia Alters Stem/Progenitor Cell Morphology and Surface Marker Expression
12.2.2 Hyperglycemia Affects Stem/Progenitor Cell Mobilization
12.2.3 Hyperglycemia Modulates the Paracrine Activity of Stem/Progenitor Cells
12.3 Stem Cell Therapy and Diabetes
12.3.1 Cell-Based Therapy in Regenerative Medicine
12.3.2 Stem Cell-Based Therapy and Diabetes
12.3.3 Using Stem Cells as Magic Bullets to Cure Diabetes
12.4 Stem Cells Reprogramming to Insulin-Secreting β-Cells
12.5 Pluripotent Stem Cells for β-Cell Regeneration
12.5.1 ESCs as a Renewable Source of β-Cells
12.5.2 iPSCs as a Renewable Source of β-Cells
12.6 Development of Direct Reprogramming Protocol Using miRNA Approach
12.6.1 Advances in Insulin-Producing Cells for iPSCs and Future Perspective
References
13: Induced Pluripotent Stem Cells in Pediatric Research and Clinical Translation
13.1 Introductıon
13.2 Stem Cell Research and Clinical Use in Pediatrics
13.2.1 Stem Cell Experience in Pediatrics Toward iPSCs
13.3 Increased Incidence of Inherited Diseases in Childhood
13.3.1 Disease Modeling and Drug R&D with iPSCs
13.4 Limited Amount of Biological Samples in Pediatrics
13.5 Increased Regenerative Potential of Children and Future Use of iPSCs in Clinics
13.6 Congenital Anomalies, Birth Complications, and Availability of  Umbilical Cord Stem Cells
13.6.1 Future Use of Cord Blood for iPSC Generation
13.7 Gene Therapy Applications: iPSCs and CRISPR-Cas9 Gene Editing
13.8 Adverse Drug Reactions in Children: Personalized Therapy with iPSCs
13.9 Regulations in Pediatric Clinical Research
13.10 Technical Issues and Need for iPSCs Banking: For Research and Clinic
13.10.1 Generation and Characterization of iPSCs
13.10.2 Banking of iPSCs
13.11 Further Developments in the iPSCs Field
13.11.1 Disease Modeling and the Next-Generation Technologies with iPSCs
13.11.2 Organoid Research with iPSCs: A Step Toward Organoid Medicine
13.11.3 Drug Repurposing/Repositioning with iPSCs for Fast-Track Clinical Trials
13.11.4 Clinical Use of iPSCs in Regenerative Medicine
13.12 Future Perspective and Conclusions
References
14: Maturity of Pluripotent Stem Cell-Derived Cardiomyocytes and Future Perspectives for Regenerative Medicine
14.1 Introduction
14.2 Difference Between the Characteristics of Immature and Mature Cardiomyocytes
14.2.1 Morphology
14.2.2 Contractile Apparatus
14.2.3 Calcium Handling
14.2.4 Electrophysiology
14.2.5 Cell Cycle
14.2.6 Metabolism
14.3 Current Maturation Strategies
14.3.1 Prolonged Culture
14.3.2 Extracellular Matrices (ECMs)
14.3.3 Hormonal Treatments
14.3.4 Alternations of Energy Source
14.3.5 Substrate Stiffness
14.3.6 Electrical Stimulation
14.3.7 Co-culture with Non-cardiomyocytes
14.3.8 In Vivo Maturation
14.3.9 3D Culture System
14.4 Future Perspectives of PSC-CMs
14.4.1 Cardiac Disease Modeling
14.4.2 Pharmacological Studies
14.4.3 Cell Transplantations
14.5 Conclusion
References
15: Availability of Pluripotent Stem Cells from Normal Cells in Cancer Science
15.1 Introduction and a Short History of Cancer Research
15.2 Cancer Stem Cells in Cancer Science
15.3 Utilizing iPSC in Cancer Science
15.4 Investigation of Tumor Initiation Mechanisms with iPSCs
15.5 Using iPSCs-Derived CSCs to Study Cancer Microenvironment and Heterogeneity
15.6 Drug Screening, Precision Medicine, and New Treatment Strategies
15.7 Current Challenges and Future Perspectives
References
Index