: Advances in understanding the mechanisms behind genetic diseases like Duchenne muscular dystrophy (DMD) underscore the critical role of the extracellular matrix (ECM) composition in disease progression. Effective in vitro models must replicate the intercellular relationships and physicochemical properties of native ECM to fully capture disease-specific characteristics. Although recent biomaterials support the in vitro biofabrication of pathophysiological environments, they often lack disease-specific ECM features. In this study, DystroGel, a hydrogel derived from the cardiac ECM of a porcine DMD model, replicates the distinct molecular composition of dystrophic cardiac tissue for the first time. The findings indicate that the dystrophic ECM matrix exhibits a unique protein profile, impacting cellular processes critical to DMD pathology. This work demonstrates the importance of using a 3D substrate that recreates intercellular dynamics within a defined pathological environment, enhancing the ability to model genetic disorders and providing a valuable tool for advancing personalized therapeutic strategies.
Mimicking the dystrophic cardiac extracellular environment through DystroGel / Chirivì, Maila; Maiullari, Fabio; Milan, Marika; Ceraolo, Maria Grazia; Fratini, Nicole; Fasciani, Alessandra; Bousselmi, Salma; Stirm, Michael; Scalera, Francesca; Gervaso, Francesca; Villa, Michela; Viganò, Raffaello; Brambilla, Francesca; Mauri, Pierluigi; De Falco, Elena; Silvestre, Dario Di; Costantini, Marco; Wolf, Eckhard; Bearzi, Claudia; Rizzi, Roberto. - In: ADVANCED HEALTHCARE MATERIALS. - ISSN 2192-2659. - (2025). [10.1002/adhm.202404251]
Mimicking the dystrophic cardiac extracellular environment through DystroGel
Chirivì, Maila;Milan, Marika;Fratini, Nicole;De Falco, Elena;Rizzi, Roberto
2025
Abstract
: Advances in understanding the mechanisms behind genetic diseases like Duchenne muscular dystrophy (DMD) underscore the critical role of the extracellular matrix (ECM) composition in disease progression. Effective in vitro models must replicate the intercellular relationships and physicochemical properties of native ECM to fully capture disease-specific characteristics. Although recent biomaterials support the in vitro biofabrication of pathophysiological environments, they often lack disease-specific ECM features. In this study, DystroGel, a hydrogel derived from the cardiac ECM of a porcine DMD model, replicates the distinct molecular composition of dystrophic cardiac tissue for the first time. The findings indicate that the dystrophic ECM matrix exhibits a unique protein profile, impacting cellular processes critical to DMD pathology. This work demonstrates the importance of using a 3D substrate that recreates intercellular dynamics within a defined pathological environment, enhancing the ability to model genetic disorders and providing a valuable tool for advancing personalized therapeutic strategies.| File | Dimensione | Formato | |
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