Magnetic Nanocomposite Hydrogels for Directing Myofibroblast Activity in Adipose‐Derived Stem Cells

Islam, Shariful; Molley, Thomas G.; Ireland, Jake; Kruzic, Jamie J.; Kilian, Kristopher A.

doi:10.1002/anbr.202000072

Cited by 5 publications

(4 citation statements)

References 58 publications

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“…Adipose derived stem cell (ADSC), the largest source of easily isolatable adult stem cells, are widely used for regenerative medicine and tissue engineering as they can self-renew and differentiate into various cell types, such as osteoblasts, , adipocytes, , chondrocytes, , and smooth muscle cells. , A major challenge in this field is guiding their differentiation into specific cell types and maintaining their specialized characteristics in synthetic 3D environments, such as model tissue scaffolds. To address this issue, we have used fiber loaded gels to evaluate the differentiation potential of ADSC into osteogenic and adipogenic linage.…”

Section: Resultsmentioning

confidence: 99%

Magnetic Nanofibrous Hydrogels for Dynamic Control of Stem Cell Differentiation

Islam,

Molley,

Hung

et al. 2023

ACS Appl. Mater. Interfaces

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The extracellular matrix in tissue consists of complex heterogeneous soft materials with hierarchical structure and dynamic mechanical properties dictating cell and tissue level function. In many natural matrices, there are nanofibrous structures that serve to guide cell activity and dictate the form and function of tissue. Synthetic hydrogels with integrated nanofibers can mimic the structural properties of native tissue; however, model systems with dynamic mechanical properties remain elusive. Here we demonstrate modular nanofibrous hydrogels that can be reversibly stiffened in response to applied magnetic fields. Iron oxide nanoparticles were incorporated into gelatin nanofibers through electrospinning, followed by chemical stabilization and fragmentation. These magnetoactive nanofibers can be mixed with virtually any hydrogel material and reversibly stiffen the matrix at a low fiber content (≤3%). In contrast to previous work, where a large quantity of magnetic material disallowed cell encapsulation, the low nanofiber content allows matrix stiffening with cells in 3D. Using adipose derived stem cells, we show how nanofibrous matrices are beneficial for both osteogenesis and adipogenesis, where stiffening the hydrogel with applied magnetic fields enhances osteogenesis while discouraging adipogenesis. Skeletal myoblast progenitors were used as a model of tissue morphogenesis with matrix stiffening augmenting myogenesis and multinucleated myotube formation. The ability to reversibly stiffen fibrous hydrogels through magnetic stimulation provides a useful tool for studying nanotopography and dynamic mechanics in cell culture, with a scope for stimuli responsive materials for tissue engineering.

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Section: Resultsmentioning

confidence: 99%

Magnetic Nanofibrous Hydrogels for Dynamic Control of Stem Cell Differentiation

Islam,

Molley,

Hung

et al. 2023

ACS Appl. Mater. Interfaces

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“…Mathematical models are pivotal across multiple disciplines, including biomedical engineering, material science, chemistry, computer science, and pharmacology. In biomedical engineering, for instance, magnetic soft robotics models are instrumental in predicting interactions with complex biological tissues, offering precise simulations of cellular growth dynamics crucial for tissue engineering [ 214 , 215 ]. Within material science, these models aid in forecasting the performance of novel magnetic materials, particularly under extreme conditions [ 216 ].…”

Section: Interdisciplinary Analysismentioning

confidence: 99%

Continuum Robots and Magnetic Soft Robots: From Models to Interdisciplinary Challenges for Medical Applications

Wang,

Mao,

2024

Micromachines

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This article explores the challenges of continuum and magnetic soft robotics for medical applications, extending from model development to an interdisciplinary perspective. First, we established a unified model framework based on algebra and geometry. The research progress and challenges in principle models, data-driven, and hybrid modeling were then analyzed in depth. Simultaneously, a numerical analysis framework for the principle model was constructed. Furthermore, we expanded the model framework to encompass interdisciplinary research and conducted a comprehensive analysis, including an in-depth case study. Current challenges and the need to address meta-problems were identified through discussion. Overall, this review provides a novel perspective on understanding the challenges and complexities of continuum and magnetic soft robotics in medical applications, paving the way for interdisciplinary researchers to assimilate knowledge in this domain rapidly.

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“…Precise emulation and understanding of such phenomena grant the advancement of spatiotemporal on-demand therapy and provide unprecedented insight to the field of nanobiomedicine. In this section, up-todate studies of magnetic in situ stem cell regulation [87,88] and immunoregulation [89] are classified based on the controlled nanoscale system parameters. Typically, studies that dynamically change the "inherent features" of the magnetic system are sorted as "magnetic control of dynamic nanoscale features."…”

Section: Magnetic In Situ Stem Cell Regulation and Immunoregulationmentioning

confidence: 99%

“…Precise emulation and understanding of such phenomena grant the advancement of spatiotemporal on‐demand therapy and provide unprecedented insight to the field of nanobiomedicine. In this section, up‐to‐date studies of magnetic in situ stem cell regulation [ 87,88 ] and immunoregulation [ 89 ] are classified based on the controlled nanoscale system parameters. Typically, studies that dynamically change the “inherent features” of the magnetic system are sorted as “magnetic control of dynamic nanoscale features.” Moreover, those that dynamically regulate the “nanoscale accessibility” of the cells via change of physical cues are categorized under “magnetic control of nanoscale accessibility.” Researches also controlled the differentiation of embryonic stem cells [ 90,91 ] toward regenerative therapies.…”

Section: Magnetic In Situ Stem Cell Regulation and Immunoregulationmentioning

confidence: 99%

Multifunctional Magnetic Nanoparticles for Dynamic Imaging and Therapy

Hong

Choi

et al. 2022

Advanced NanoBiomed Research

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Dynamic therapy is a key research area for noninvasive clinical therapeutics. Up to now, light, electricity, ultrasound, and magnetic field have been investigated for the potential remote cellular regulation tools. Opening ion channels, activating cell death, and manipulating individual receptors that can control various cellular signal pathways have been suggested using external energy forms that can be dynamically applied in situ, which advance from the static control strategies. [1][2][3][4] For instance, optogenetics using light [5,6] have greatly advanced cellular modulation over the past decades, especially for neuromodulation. [7] Other energy sources have also been demonstrated with promising potential for regulating cellular metabolism and death. However, controlling the penetration and localization of energy sources (e.g., light and electricity) in tissues and cells have been challenging for in vivo applications. On the other hand, a magnetic field can safely penetrate deep tissues, which is particularly relevant for clinical applications. Consequently, utilizing the magnetic field to manipulate the MNPs is emerging as an effective approach to dynamically regulate cellular activity. [8] Recent advancements of multifunctional MNPs, spintronics, and magnetogenetics have enabled precise modulation of magnetic field gradients and pulses to remotely control the movement, heat generation, and reactive oxygen species (ROS) generation of the MNPs (Figure 1).Engineering multifunctional magnetic particles is the key requirement to achieve desired biomedical applications. [9][10][11] In the past 20 years, MNPs have received increasing attention

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Magnetic Nanocomposite Hydrogels for Directing Myofibroblast Activity in Adipose‐Derived Stem Cells

Cited by 5 publications

References 58 publications

Magnetic Nanofibrous Hydrogels for Dynamic Control of Stem Cell Differentiation

Magnetic Nanofibrous Hydrogels for Dynamic Control of Stem Cell Differentiation

Continuum Robots and Magnetic Soft Robots: From Models to Interdisciplinary Challenges for Medical Applications

Multifunctional Magnetic Nanoparticles for Dynamic Imaging and Therapy

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