Mimicking Loading-Induced Cartilage Self-Heating <i>in Vitro</i> Promotes Matrix Formation in Chondrocyte-Laden Constructs with Different Mechanical Properties

Stampoultzis, Theofanis; Guo, Yanheng; Nasrollahzadeh, Naser; Karami, Peyman; Pioletti, Dominique P.

doi:10.1021/acsbiomaterials.2c00723

Cited by 11 publications

(18 citation statements)

References 40 publications

(95 reference statements)

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“…While it could be argued that our channel analysis has only been performed in free-swelling constructs and not in stimulated hydrogels, we have previously shown that thermomechanical loading increases the expression of these channels at protein levels as well. 12,26 Hence, we contend the validity of our hypothesis, suggesting that the observed effects likely arise from the interplay between various stimuli and the multifaceted responses of chondrocytes.…”

Section: Discussionmentioning

confidence: 58%

“…Our previous studies have extensively elucidated the significance and relevance in replicating cartilage self-heating in vitro and demonstrated thoroughly how loading-induced evolved temperature can be harnessed in vitro to accelerate tissue maturation through expression of major structural proteins. 26 Building upon our prior findings where load, heat and hypoxia interactions were studied, herein we aimed to introduce the inherent dynamic nature of the culture environment as an additional parameter in this multifaceted equation. The relevance of including PEG/alpha cyclodextrin-based polyrotaxanes into the robust covalent network stems from their capacity to partially replicate the dynamic interactions found in natural cartilage.…”

Section: Discussionmentioning

confidence: 99%

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Impact of Molecular Dynamics of Polyrotaxanes on Chondrocytes in Double Network Supramolecular Hydrogels under Physiological Thermomechanical Stimulation

Stampoultzis,

Rana,

Guo

et al. 2023

Preprint

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Hyaline cartilage, a soft tissue enriched with a dynamic extracellular matrix, manifests as a supramolecular system within load-bearing joints. At the same time, the challenge of cartilage repair through tissue engineering lies in replicating intricate cellular-matrix interactions. This study attempts to investigate chondrocyte responses within double-network supramolecular hydrogels, tailored to mimic the dynamic molecular nature of hyaline cartilage. To this end, we infused non-covalent host-guest polyrotaxanes, by blending α-cyclodextrins as host molecules and polyethylene glycol as guests, into a gelatin-based covalent matrix, thereby enhancing its dynamic characteristics. Subsequently, chondrocytes were seeded into these hydrogels to systematically probe the effects of varied concentrations of introduced polyrotaxanes (instilling different levels of supramolecular dynamism in the hydrogel systems) on cellular responsiveness. Our findings unveiled an augmented level of cellular mechanosensitivity for supramolecular hydrogels compared to pure covalent-based systems. This is demonstrated by an increased mRNA expression of ion channels (TREK1, TRPV4, PIEZO1), signaling molecules (SOX9) and matrix remodeling enzymes (LOXL2). Such outcomes were further elevated upon external application of biomimetic thermomechanical loading that brought a stark increase in the accumulation of sulfated glycosaminoglycans and collagen. Overall, we found that matrix adaptability plays a pivotal role in modulating chondrocyte responses within double-network supramolecular hydrogels. These findings hold potential for advancing cartilage engineering within load-bearing joints.

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Section: Discussionmentioning

confidence: 58%

Section: Discussionmentioning

confidence: 99%

Impact of Molecular Dynamics of Polyrotaxanes on Chondrocytes in Double Network Supramolecular Hydrogels under Physiological Thermomechanical Stimulation

Stampoultzis,

Rana,

Guo

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…In our investigation, the hydrogel formulations were also subjected to bioreactor culture conditions that incorporated thermomechanical signals under a low oxygen tension. Our previous studies have extensively elucidated the significance and relevance in replicating cartilage self-heating in vitro and demonstrated thoroughly how loading-induced evolved temperature can be harnessed in vitro to accelerate tissue maturation through expression of major structural proteins. ,, Building upon our prior findings where load, heat, and hypoxia interactions were studied, herein we aimed to introduce the inherent noncovalent nature of the culture environment as an additional parameter in this multifaceted equation. The relevance of including PEG/alpha cyclodextrin-based polyrotaxanes into the robust covalent network stems from their capacity to partially replicate the dynamic interactions found in natural cartilage. , Through the incorporation of supramolecular polyrataxanes, we aim to mimic the innate noncovalent interactions inherent in cartilage tissue, playing a pivotal role in its mechanical composure and potential signals they transfer to chondrocytes.…”

Section: Discussionmentioning

confidence: 99%

“…We identified three ion channels, namely, TREK1, TRPV4, and PIEZO1, whose expression was significantly upregulated in the presence of host–guest reversible polyrotaxanes. While it could be argued that our channel analysis has only been performed in free-swelling constructs and not in stimulated hydrogels, we have previously shown that thermomechanical loading increases the expression of these channels at protein levels as well. , Hence, we contend with the validity of our hypothesis, suggesting that the observed effects likely arise from the interplay between various stimuli and the multifaceted responses of chondrocytes.…”

Section: Discussionmentioning

confidence: 99%

Impact of Molecular Dynamics of Polyrotaxanes on Chondrocytes in Double-Network Supramolecular Hydrogels under Physiological Thermomechanical Stimulation

Stampoultzis,

Rana,

Guo

et al. 2024

Biomacromolecules

Self Cite

View full text Add to dashboard Cite

Hyaline cartilage, a soft tissue enriched with a dynamic extracellular matrix, manifests as a supramolecular system within load-bearing joints. At the same time, the challenge of cartilage repair through tissue engineering lies in replicating intricate cellular–matrix interactions. This study attempts to investigate chondrocyte responses within double-network supramolecular hybrid hydrogels tailored to mimic the dynamic molecular nature of hyaline cartilage. To this end, we infused noncovalent host–guest polyrotaxanes, by blending α-cyclodextrins as host molecules and polyethylene glycol as guests, into a gelatin-based covalent matrix, thereby enhancing its dynamic characteristics. Subsequently, chondrocytes were seeded into these hydrogels to systematically probe the effects of two concentrations of the introduced polyrotaxanes (instilling different levels of supramolecular dynamism in the hydrogel systems) on the cellular responsiveness. Our findings unveiled an augmented level of cellular mechanosensitivity for supramolecular hydrogels compared to pure covalent-based systems. This is demonstrated by an increased mRNA expression of ion channels (TREK1, TRPV4, and PIEZO1), signaling molecules (SOX9) and matrix-remodeling enzymes (LOXL2). Such outcomes were further elevated upon external application of biomimetic thermomechanical loading, which brought a stark increase in the accumulation of sulfated glycosaminoglycans and collagen. Overall, we found that matrix adaptability plays a pivotal role in modulating chondrocyte responses within double-network supramolecular hydrogels. These findings hold the potential for advancing cartilage engineering within load-bearing joints.

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“…At the end of the manufacturing phase and following transport/storage, the constructs were evaluated via macroscopic assessment, cell viability assessment, total GAG quantification, and histology for three different transport media (Table 4). [69][70][71]. In order to meet increasing clinical needs, important translational efforts are being allocated toward the optimization of existing ACI protocols or the creation of novel approaches [11,12,[72][73][74][75][76].…”

Section: Allogeneic Finished Products Possess An Appropriate Pharmace...mentioning

confidence: 99%

Autologous and Allogeneic Cytotherapies for Large Knee (Osteo)Chondral Defects: Manufacturing Process Benchmarking and Parallel Functional Qualification

Philippe,

Jeannerat,

Peneveyre

et al. 2023

Pharmaceutics

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Cytotherapies are often necessary for the management of symptomatic large knee (osteo)-chondral defects. While autologous chondrocyte implantation (ACI) has been clinically used for 30 years, allogeneic cells (clinical-grade FE002 primary chondroprogenitors) have been investigated in translational settings (Swiss progenitor cell transplantation program). The aim of this study was to comparatively assess autologous and allogeneic approaches (quality, safety, functional attributes) to cell-based knee chondrotherapies developed for clinical use. Protocol benchmarking from a manufacturing process and control viewpoint enabled us to highlight the respective advantages and risks. Safety data (telomerase and soft agarose colony formation assays, high passage cell senescence) and risk analyses were reported for the allogeneic FE002 cellular active substance in preparation for an autologous to allogeneic clinical protocol transposition. Validation results on autologous bioengineered grafts (autologous chondrocyte-bearing Chondro-Gide scaffolds) confirmed significant chondrogenic induction (COL2 and ACAN upregulation, extracellular matrix synthesis) after 2 weeks of co-culture. Allogeneic grafts (bearing FE002 primary chondroprogenitors) displayed comparable endpoint quality and functionality attributes. Parameters of translational relevance (transport medium, finished product suturability) were validated for the allogeneic protocol. Notably, the process-based benchmarking of both approaches highlighted the key advantages of allogeneic FE002 cell-bearing grafts (reduced cellular variability, enhanced process standardization, rationalized logistical and clinical pathways). Overall, this study built on our robust knowledge and local experience with ACI (long-term safety and efficacy), setting an appropriate standard for further clinical investigations into allogeneic progenitor cell-based orthopedic protocols.

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Mimicking Loading-Induced Cartilage Self-Heating in Vitro Promotes Matrix Formation in Chondrocyte-Laden Constructs with Different Mechanical Properties

Cited by 11 publications

References 40 publications

Impact of Molecular Dynamics of Polyrotaxanes on Chondrocytes in Double Network Supramolecular Hydrogels under Physiological Thermomechanical Stimulation

Impact of Molecular Dynamics of Polyrotaxanes on Chondrocytes in Double Network Supramolecular Hydrogels under Physiological Thermomechanical Stimulation

Impact of Molecular Dynamics of Polyrotaxanes on Chondrocytes in Double-Network Supramolecular Hydrogels under Physiological Thermomechanical Stimulation

Autologous and Allogeneic Cytotherapies for Large Knee (Osteo)Chondral Defects: Manufacturing Process Benchmarking and Parallel Functional Qualification

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