On the adhesion-cohesion balance and oxygen consumption characteristics of liver organoids

Mattei, Giorgio; Magliaro, Chiara; Giusti, Serena; Ramachandran, Sarada Devi; Heinz, Stefan; Braspenning, Joris; Ahluwalia, Arti

doi:10.1371/journal.pone.0173206

Cited by 32 publications

(34 citation statements)

References 38 publications

(63 reference statements)

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“…As we hypothesized that cell encapsulation within microscale droplets could overcome this challenge, we initially modeled oxygen concentration by using COMSOL multiphysics modeling software. We have taken into consideration oxygen diffusion according to Fick's second law and consumption by the cells according to Michaelis–Menten kinetics . The external concentration of oxygen was considered as the concentration within arterial blood and oxygen diffusion coefficient was considered as the one in a muscle.…”

Section: Resultsmentioning

confidence: 99%

“…We have taken into consideration oxygen diffusion according to Fick's second law and consumption by the cells according to Michaelis-Menten kinetics. [18] The external concentration of oxygen was considered as the concentration within arterial blood and oxygen diffusion coefficient was considered as the one in a muscle. Two assumptions were made during our mathematical modelling: 1) Twenty minutes is considered the maximal period of time, in which cardiac cells can survive without oxygen.…”

Section: Oxygen Diffusion Modelingmentioning

confidence: 99%

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Injectable Cardiac Cell Microdroplets for Tissue Regeneration

Gal

Edri

Noor

et al. 2020

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One of the strategies for heart regeneration includes cell delivery to the defected heart. However, most of the injected cells do not form quick cell–cell or cell–matrix interactions, therefore, their ability to engraft at the desired site and improve heart function is poor. Here, the use of a microfluidic system is reported for generating personalized hydrogel‐based cellular microdroplets for cardiac cell delivery. To evaluate the system's limitations, a mathematical model of oxygen diffusion and consumption within the droplet is developed. Following, the microfluidic system's parameters are optimized and cardiac cells from neonatal rats or induced pluripotent stem cells are encapsulated. The morphology and cardiac specific markers are assessed and cell function within the droplets is analyzed. Finally, the cellular droplets are injected to mouse gastrocnemius muscle to validate cell retention, survival, and maturation within the host tissue. These results demonstrate the potential of this approach to generate personalized cellular microtissues, which can be injected to distinct regions in the body for treating damaged tissues.

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Section: Resultsmentioning

confidence: 99%

Section: Oxygen Diffusion Modelingmentioning

confidence: 99%

Injectable Cardiac Cell Microdroplets for Tissue Regeneration

Gal

Edri

Noor

et al. 2020

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“…Developing physiologically relevant in vitro models to mimic cell and tissue organ response is one of the main challenges in experimental cell biology and tissue engineering. Organoid technology has emerged as a novel method to generate structural and functional tissue models 15,[32][33][34][35] . Luminal organoids were first generated from intestinal stem cells by Clevers and coworkers 36 .…”

Section: Discussionmentioning

confidence: 99%

“…The results are confirmed by experimental studies on liver buds by Ramachandran et al 22 ; the authors found no evidence of cell death in liver buds cultured in well-mixed fluidic bioreactors while those in static conditions developed a necrotic core. Mattei et al 43 demonstrated that the minimum oxygen level in liver buds with an average mass of a few mg cultured in bioreactors is 0.04 mol/m 3 , compared with 0.01 mol/m 3 in static culture plates. As shown in Table 4, the gel-free structures resembling liver buds maintain the criteria of quarter power scaling (b ≈ -1/4) and viable oxygen concentrations only if their radii are maintained in a narrow range (between 654 and 712 µm in the models).…”

Section: Discussionmentioning

confidence: 99%

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Allometric Scaling of physiologically-relevant organoids

Magliaro

Rinaldo

Ahluwalia

2019

Preprint

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The functional and structural resemblance of organoids to mammalian organs suggests that they might follow the same allometric scaling rules. However, despite their remarkable likeness to downscaled organs, non-luminal organoids are often reported to possess necrotic cores due to oxygen diffusion limits. To assess their potential as physiologically relevant in vitro models, we determined the range of organoid masses in which quarter power scaling as well as a minimum threshold oxygen concentration is maintained. Using data on brain organoids as a reference, computational models were developed to estimate oxygen consumption and diffusion at different stages of growth. The results show that mature brain (or other non-luminal) organoids generated using current protocols must lie within a narrow range of masses to maintain both quarter power scaling and viable cores. However, micro-fluidic oxygen delivery methods could be designed to widen this range, ensuring a minimum viable oxygen threshold throughout the constructs and mass dependent metabolic scaling. The results provide new insights into the significance of the allometric exponent in systems without a resource-supplying network and may be used to guide the design of more predictive and physiologically relevant in vitro models, providing an effective alternative to animals in research. ________________________________________________________________________________ Recent advances in in vitro technology have led to the development of organoids, i.e. cell aggregates grown from a small number of stem cells able to self-assemble, recapitulating the threedimensional architecture of an organ at the micro-scale 1,2 . They are currently considered as one of the most promising ways to study cell behaviour and may have significant potential as a tool for investigating developmental biology, disease pathology, regenerative medicine and drug toxicity. Moreover, their downscaled functional and structural resemblance to mammalian organs suggests that they might also follow allometric scaling rules, such as Kleiber's law (KL) 3-5 . KL is one of the most well-known allometric relationships in biology. It states that the basal metabolic rate (BMR) of an organism scales with its body mass, M, according to a universal powerlaw BMR = aM α , (where α is a scaling exponent, a a constant). On the basis that the number of cells in an organism is proportional to its mass, an analogous expression relates the average resource consumption rate per cell (cellular metabolic rate, CMR) to mass as CMR M (α-1) =M b . The majority of experimental studies support the claim that KL applies across species with α=3/4, or b=−1/4 hence it is often referred to as the quarter power scaling law 6 . A number of theoretical explanations have been proposed to support quarter power scaling 5,7 . As KL applies across several orders of magnitude of mass, it has been described as a unifying equation of biology 8 . Indeed, metabolic requirements of organisms, as well as their constituent cells, influence many ...

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Effect of substrate stiffness on hepatocyte migration and cellular Young's modulus

Xia

Zhao

Liu

et al. 2018

Journal Cellular Physiology

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Hepatic fibrosis progress accompanied by an unbalanced extracellular matrix (ECM) degradation and deposition leads to an increased tissue stiffness. Hepatocytes interplay with all intrahepatic cell populations inside the liver. However, how hepatocytes migration and cellular Young's modulus influenced by the substrate stiffness are not well understood. Here, we established a stiffness-controllable in vitro cell culture model by using a polyvinyl alcohol (PVA) hydrogel that mimicked the same physical stiffness as a fibrotic liver. Three levels of stiffness were used in our experiment that corresponded to the stiffness levels found in normal liver tissue (4.5 kPa), the early (19 kPa) and late stages (37 kPa) of fibrotic liver tissues. Cytoskeleton of hepatocyte was influenced by substrate stiffness. Soft substrate promoted the cellular migration and directionality. The cellular Young's modulus firstly increased and then decreased with increasing substrate stiffness. Integrin-β1 and β-catenin expression on cytomembrane were up-regulated and down-regulated with the increase of substrate stiffness, respectively. Our data not only suggested that hepatocytes were sensitive to substrate stiffness, but also suggested that there may be a potential relationship among substrate stiffness, cellular Young's modulus and the dynamic balance of integrin-β1 and β-catenin pathways. These results may provide us a new insight in mechanism investigation of mechano-dependent diseases, especially like fibrosis related diseases.

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On the adhesion-cohesion balance and oxygen consumption characteristics of liver organoids

Cited by 32 publications

References 38 publications

Injectable Cardiac Cell Microdroplets for Tissue Regeneration

Injectable Cardiac Cell Microdroplets for Tissue Regeneration

Allometric Scaling of physiologically-relevant organoids

Effect of substrate stiffness on hepatocyte migration and cellular Young's modulus

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