Organoid Technology: A Reliable Developmental Biology Tool for Organ-Specific Nanotoxicity Evaluation

Prasad, Minakshi; Kumar, Rajesh; Buragohain, Lukumoni; Kumari, Ankur; Ghosh, Mayukh

doi:10.3389/fcell.2021.696668

Cited by 32 publications

(34 citation statements)

References 314 publications

(442 reference statements)

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“…So, worldwide research groups are dedicating efforts to develop a new generation of advanced in vitro models capable of recapitulating organ functions becoming effective tools for toxicology, pharmacology (investigating drug metabolism, pharmacokinetics, and toxicity), and for the mechanistic understanding of organ physiology and pathophysiology [ 150 , 153 , 154 , 155 ]. Several promising advanced models have been already established with superior physiological relevance, correlation, and validation compared to in vivo models [ 149 , 150 , 151 , 153 , 154 , 156 , 157 , 158 ]. However, it is important to stress that the priority in model development was not for nanosafety purposes.…”

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

“…These seem to be suited to the assessment of skin-related nanomaterial risk [ 159 ]. Three-dimensional skin models exposed to nanomaterials provided more realistic analyses with lesser nanomaterial penetration due to an enhanced barrier function [ 158 , 159 ]. Oral epithelium and urogenital tract tissues are already commercially available; however, few companies provide relevant essential organs for nanomaterial safety such as the liver, kidney, respiratory epithelium, and intestinal epithelium [ 149 , 150 , 151 , 152 , 153 , 160 ].…”

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

“…Liver, kidney, brain, skin, lung, and intestinal organoids among others were already established, and they are also considered promising tools for predicting nanomaterial toxicity to organs [ 150 ]. They provide organotypic cytoarchitectures with a spatially organized structure and in vivo phenotypic and extracellular matrix (ECM) expression mimicking important cellular functions such as cell migration, differentiation, and apoptosis, among other advantages [ 158 ]. In nanotoxicological studies, organoids seem to offer a barrier to nanomaterial distribution and cytotoxicity [ 9 , 152 ].…”

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

“…Alternatively, 3D biomaterial-based models also present multiple benefits, since they are constituted by synthetic or naturally derived biomaterials, mimicking cell–ECM interactions [ 156 , 163 , 164 ]. With the latest improvements in materials science, microfabrication techniques, and bioreactor-based spheroid and organoid technology [ 153 ], new efforts are being made to combine self-organizing 3D biological structures into organs-on-chips (OoCs) to emulate both the structural and dynamic complexity of tissues and organs [ 153 , 158 , 165 , 166 , 167 ].…”

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

“…Integrated multiorganoid models have been proposed in an effort to mimic complex procedures of metabolism and responses at the multiorganoid level, where flow rates resemble blood circulation in the human body [ 176 ]. Therefore, MOoCs can be exploited to evaluate the systemic toxicity of nanomaterials from the dynamic process of distribution, absorption, metabolism, and excretion features; nonetheless, systemic predictions are still challenging [ 157 , 158 ]. Future studies should take advantage of the development of engineered perfusable vasculature in microphysiological platforms making it possible to mimic the delivery of nanomaterials in a more physiologically relevant way, allowing the accurate prediction of their performance in vivo [ 153 , 166 ].…”

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

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Nanosafety: An Evolving Concept to Bring the Safest Possible Nanomaterials to Society and Environment

et al. 2022

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The use of nanomaterials has been increasing in recent times, and they are widely used in industries such as cosmetics, drugs, food, water treatment, and agriculture. The rapid development of new nanomaterials demands a set of approaches to evaluate the potential toxicity and risks related to them. In this regard, nanosafety has been using and adapting already existing methods (toxicological approach), but the unique characteristics of nanomaterials demand new approaches (nanotoxicology) to fully understand the potential toxicity, immunotoxicity, and (epi)genotoxicity. In addition, new technologies, such as organs-on-chips and sophisticated sensors, are under development and/or adaptation. All the information generated is used to develop new in silico approaches trying to predict the potential effects of newly developed materials. The overall evaluation of nanomaterials from their production to their final disposal chain is completed using the life cycle assessment (LCA), which is becoming an important element of nanosafety considering sustainability and environmental impact. In this review, we give an overview of all these elements of nanosafety.

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Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

Section: Advanced Models For In Vitro Testingmentioning

confidence: 99%

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Nanosafety: An Evolving Concept to Bring the Safest Possible Nanomaterials to Society and Environment

et al. 2022

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Use of Real‐World Evidence to Drive Drug Development Strategy and Inform Clinical Trial Design

Dagenais

Russo

Madsen

et al. 2021

Clin Pharma and Therapeutics

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Interest in real-world data (RWD) and real-world evidence (RWE) to expedite and enrich the development of new biopharmaceutical products has proliferated in recent years, spurred by the 21st Century Cures Act in the United States and similar policy efforts in other countries, willingness by regulators to consider RWE in their decisions, demands from third-party payers, and growing concerns about the limitations of traditional clinical trials. Although much of the recent literature on RWE has focused on potential regulatory uses (e.g., product approvals in oncology or rare diseases based on single-arm trials with external control arms), this article reviews how biopharmaceutical companies can leverage RWE to inform internal decisions made throughout the product development process. Specifically, this article will review use of RWD to guide pipeline and portfolio strategy; use of novel sources of RWD to inform product development, use of RWD to inform clinical development, use of advanced analytics to harness "big" RWD, and considerations when using RWD to inform internal decisions. Topics discussed will include the use of molecular, clinicogenomic, medical imaging, radiomic, and patient-derived xenograft data to augment traditional sources of RWE, the use of RWD to inform clinical trial eligibility criteria, enrich trial population based on predicted response, select endpoints, estimate sample size, understand disease progression, and enhance diversity of participants, the growing use of data tokenization and advanced analytical techniques based on artificial intelligence in RWE, as well as the importance of data quality and methodological transparency in RWE.

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Immunomodulation in age‐related disorders and nanotechnology interventions

Chintapula

Chikate

Sahoo

et al. 2022

WIREs Nanomed Nanobiotechnol

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Recently, the aging population has increased exponentially around the globe bringing more challenges to improve quality of life in those populations while reducing the economic burden on healthcare systems. Aging is associated with changes in the immune system culminating in detrimental effects such as immune dysfunction, immunosenescence, and chronic inflammation. Age-related decline of immune functions is associated with various pathologies including cardiovascular, autoimmune, neurodegenerative, and infectious diseases to name a few. Conventional treatment addresses the onset of age-related diseases by early detection of risk factors, administration of vaccines as preventive care, immunomodulatory treatment, and other dietary supplements. However, these approaches often come with systemic side-effects, low bioavailability of therapeutic agents, and poor outcomes seen in the elderly. Recent innovations in nanotechnology have led to the development of novel biomaterials/nanomaterials, which explore targeted drug delivery and immunomodulatory interactions in vivo. Current nanotechnology-based immunomodulatory approaches that have the potential to be used as therapeutic interventions for some prominent age-related diseases are discussed here. Finally, we explore challenges and future aspects of nanotechnology in the treatments of age-related disorders to improve quality of life in the elderly.

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Organoid Technology: A Reliable Developmental Biology Tool for Organ-Specific Nanotoxicity Evaluation

Cited by 32 publications

References 314 publications

Nanosafety: An Evolving Concept to Bring the Safest Possible Nanomaterials to Society and Environment

Nanosafety: An Evolving Concept to Bring the Safest Possible Nanomaterials to Society and Environment

Use of Real‐World Evidence to Drive Drug Development Strategy and Inform Clinical Trial Design

Immunomodulation in age‐related disorders and nanotechnology interventions

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