Engineering a 3D-Bioprinted Model of Human Heart Valve Disease Using Nanoindentation-Based Biomechanics

Valk, Dewy C. van der; Ven, Casper F.T. van der; Blaser, Mark C.; Grolman, Joshua M.; Wu, Pin Jou; Fenton, Owen S.; Lee, Lang Ho; Tibbitt, Mark W.; Andresen, Jason L.; Wen, Jennifer; Ha, Anna H.; Buffolo, Fabrizio; Mil, Alain van; Bouten, Cvc Carlijn; Body, Simon C.; Mooney, David J.; Sluijter, Joost P.G.; Aikawa, Masanori; Hjortnaes, Jesper; Langer, Robert; Aikawa, Elena

doi:10.3390/nano8050296

Cited by 84 publications

(86 citation statements)

References 58 publications

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“…Although many therapeutic targets have been identified, the mechanosensitive nature of VIC is a key limiting factor in current in vitro platforms for high throughput disease modeling or drug discovery, which are based on 2D cell culture tissue culture polystyrene with high nonphysiological stiffness (van der Valk et al, 2018). In vivo, the majority of VICs are in a quiescent state (qVIC) and have a fibroblast-like phenotype, low proliferation capacity, and minimal activity and express high vimentin and low alpha smooth muscle actin (α-SMA; Hinton et al, 2006;Rabkin-Aikawa, Farber, Aikawa, & Schoen, 2004;Rabkin et al, 2001).…”

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confidence: 99%

“…In order to develop an in vitro platform that recapitulates key aspects of the valvular architecture and microenvironment and to reliably screen novel targets, microtissues need to be encapsulated in tunable hydrogels mimicking the layer-specific mechanical properties of heart valves (van der Valk et al, 2018) and allowing fusion of the microtissues into macrotissues.…”

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confidence: 99%

“…In the past 10 years, several research groups have been evaluating polyethylene glycol, hyaluronic acid (HA), gelatin, and hybrid hydrogels as encapsulation material for VIC (Benton, DeForest, Vivekanandan, & Anseth, 2009;Chen, Srigunapalan, Wheeler, & Simmons, 2013;Kang et al, 2017;Masters, Shah, Leinwand, & Anseth, 2005). Encapsulated VICs in hybrid hydrogels are often the starting point for developing an organ on a chip to study physiological cardiovascular cell interactions Hjortnaes et al, 2015;van der Valk et al, 2018).…”

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confidence: 99%

“…). These tunable hydrogel systems will be important for future 3D bioprinting of valvular tissues mimicking the layer-specific mechanical properties of heart valves(van der Valk et al, 2018). Above all, it is described in literature that soft hydrogels would lead to activation of qVIC into aVIC.…”

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confidence: 99%

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Impact of modified gelatin on valvular microtissues

Roosens

Handoyo

Dubruel

et al. 2019

J Tissue Eng Regen Med

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A significant challenge in the field of tissue engineering is the biofabrication of three‐dimensional (3D) functional tissues with direct applications in organ‐on‐a‐chip systems and future organ engineering. Multicellular valvular microtissues can be used as building blocks for the formation of larger scale valvular macrotissues. Yet, for the controlled biofabrication of 3D macrotissues with predefined complex shapes, directed assembly of microtissues through bioprinting is needed. This study aimed to investigate if modified gelatin is an instructive material for valvular microtissues. Valvular microtissues were encapsulated in modified gelatin hydrogels and cross‐linked in the presence of a photoinitiator (Irgacure 2959 or VA‐086). Hydrogel properties were determined, and valvular interstitial cell functions like phenotype, proliferation, migration, mRNA expression of extracellular matrix (ECM) molecules, ECM deposition, and tissue fusion were characterized by histochemical stainings and RT‐qPCR. Encapsulated microtissues remained viable, produced heart valve‐related ECM components, and remained in a quiescent state. However, encapsulation induced some changes in ECM formation and gene expression. Encapsulated microtissues showed lower remodeling capacity and increased expression levels of Col I/V, elastin, hyaluronan, biglycan, decorin, and Sox9 compared with nonencapsulated microtissues. Furthermore, this study demonstrated that proliferation, migration, and tissue fusion was more pronounced in softer gels. In general, we evidenced that modified gelatin is an instructive material for physiologically relevant valvular microtissues and provided a proof of concept for the formation of larger valvular tissue by assembling microtissues at random in soft gels.

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confidence: 99%

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confidence: 99%

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confidence: 99%

mentioning

confidence: 99%

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Impact of modified gelatin on valvular microtissues

Roosens

Handoyo

Dubruel

et al. 2019

J Tissue Eng Regen Med

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“…Ultimately, our approach represents an efficient, cost-effective, and widely accessible strategy for studying the proteome and miRNAome of purified EVs isolated directly from fibro-calcific human, animal, or even engineered tissues. (8, 45)…”

Section: Discussionmentioning

confidence: 99%

Conserved and Divergent Modulation of Calcification in Atherosclerosis and Aortic Valve Disease by Tissue Extracellular Vesicles

Buffolo

Halu

et al. 2020

Preprint

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53 54 Background: Fewer than 50% of patients develop calcification of both atherosclerotic plaques 55 and aortic valves, implying differential pathogenesis. While circulating extracellular vesicles 56 (EVs) act as biomarkers of cardiovascular diseases, tissue-entrapped EVs associate with early 57 mineralization, but their contents, function, and contributions to disease remain unknown. 58 59 Results: Global proteomics of human carotid artery endarterectomies and calcified aortic valves 60 from a total of 27 donors/patients revealed significant over-representation of proteins with 61 vesicle-associated pathways/ontologies common to both diseases. We exploited enzymatic 62 digestion, serial (ultra)centrifugation and OptiPrep density-gradient separation to isolate EV 63 populations from diseased arteries and valves. Mass spectrometry found 22 EV marker proteins 64 to be highly enriched in the four least-dense OptiPrep fractions while extracellular matrix 65 proteins predominated in denser fractions, as confirmed by CD63 immunogold electron 66 microscopy and nanoparticle tracking analysis. Proteomics and miRNA-sequencing of OptiPrep-67 enriched tissue EVs quantified 1,104 proteins and 123 miR cargoes linked to 5,182 target 68 genes. Pathway networks of proteins and miR targets common to artery and valve tissue EVs 69 revealed a shared regulation of Rho GTPase and MAPK intracellular signaling cascades. 179 70 proteins and 5 miRs were significantly altered between artery and valve EVs; multi-omics 71 integration determined that EVs differentially modulated cellular contraction and p53-mediated 72 transcriptional regulation in diseased vascular vs. valvular tissue. 73 74 Conclusions: Our findings delineate a strategy to isolate, purify, and study protein and RNA 75 cargoes from EVs entrapped in fibrocalcific tissues. Multi-omics and network approaches 76 implicated tissue-resident EVs in human cardiovascular disease. 77 78 4 Keywords 79 80 Extracellular vesicles, exosomes, atherosclerosis, vascular calcification, calcific aortic valve 81 disease, proteomics, transcriptomics, miRNA, multi-omics integration, network analysis 82 83 84 Background 85 86Cardiovascular calcification directly correlates with incidence of cardiovascular events such as 87 myocardial infarction, stroke, and heart failure, and strongly predicts morbidity and mortality.(1) 88While aberrant mineralization of arteries and heart valves share numerous risk factors, only 25-89 50% of patients develop both vascular and valvular calcification, implying that they involve 90 differential drivers.(2) Histopathological studies described these two conditions as being grossly 91 comparable (3) and there has been little subsequent study of this apparent epidemiological 92 paradox. Despite the histological similarities, pharmacological therapies such as statins have 93 been successful in mitigating inflammation and lowering cholesterol in patients with 94 atherosclerosis but they failed to improve outcomes for aortic valve stenosisleaving patients 95 without effec...

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Fiber Scaffold Patterning for Mending Hearts: 3D Organization Bringing the Next Step

Kristen

Ainsworth

Chirico

et al. 2019

Adv Healthcare Materials

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Heart failure (HF) is a leading cause of death worldwide. The most common conditions that lead to HF are coronary artery disease, myocardial infarction, valve disorders, high blood pressure, and cardiomyopathy. Due to the limited regenerative capacity of the heart, the only curative therapy currently available is heart transplantation. Therefore, there is a great need for the development of novel regenerative strategies to repair the injured myocardium, replace damaged valves, and treat occluded coronary arteries. Recent advances in manufacturing technologies have resulted in the precise fabrication of 3D fiber scaffolds with high architectural control that can support and guide new tissue growth, opening exciting new avenues for repair of the human heart. This review discusses the recent advancements in the novel research field of fiber patterning manufacturing technologies for cardiac tissue engineering (cTE) and to what extent these technologies could meet the requirements of the highly organized and structured cardiac tissues. Additionally, future directions of these novel fiber patterning technologies, designs, and applicability to advance cTE are presented.

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Engineering a 3D-Bioprinted Model of Human Heart Valve Disease Using Nanoindentation-Based Biomechanics

Cited by 84 publications

References 58 publications

Impact of modified gelatin on valvular microtissues

Impact of modified gelatin on valvular microtissues

Conserved and Divergent Modulation of Calcification in Atherosclerosis and Aortic Valve Disease by Tissue Extracellular Vesicles

Fiber Scaffold Patterning for Mending Hearts: 3D Organization Bringing the Next Step

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