Fickian-Based Empirical Approach for Diffusivity Determination in Hollow Alginate-Based Microfibers  Using 2D Fluorescence Microscopy and Comparison  with Theoretical Predictions

Mobed-Miremadi, Maryam; Djomehri, Sabra; Keralapura, Mallika; McNeil, Melanie

doi:10.3390/ma7127670

Cited by 11 publications

(10 citation statements)

References 60 publications

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“…Internal fluorescence was quantified as demonstrated by intensity histograms (Figure A) and change of intensity over time (Figure B). Finite element modeling of diffusivity via parametric sweeps and sum of the squares analysis against measured values (Figure S1) provided diffusivity values comparable to those determined by others and demonstrated comparable diffusivities between PEG and alginate hydrogels (Figure C).…”

Section: Resultssupporting

confidence: 77%

Synthetic poly(ethylene glycol)-based microfluidic islet encapsulation reduces graft volume for delivery to highly vascularized and retrievable transplant site

Weaver

Headen

Coronel

et al. 2019

American Journal of Transplantation

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Transplant of hydrogel‐encapsulated allogeneic islets has been explored to reduce or eliminate the need for chronic systemic immunosuppression by creating a physical barrier that prevents direct antigen presentation. Although successful in rodents, translation of alginate microencapsulation to large animals and humans has been hindered by large capsule sizes (≥500 μm diameter) that result in suboptimal nutrient diffusion in the intraperitoneal space. We developed a microfluidic encapsulation system that generates synthetic poly(ethylene glycol)‐based microgels with smaller diameters (310 ± 14 μm) that improve encapsulated islet insulin responsiveness over alginate capsules and allow transplant within vascularized tissue spaces, thereby reducing islet mass requirements and graft volumes. By delivering poly(ethylene glycol)‐encapsulated islets to an isolated, retrievable, and highly vascularized site via a vasculogenic delivery vehicle, we demonstrate that a single pancreatic donor syngeneic islet mass exhibits improved long‐term function over conventional alginate capsules and close integration with transplant site vasculature. In vivo tracking of bioluminescent allogeneic encapsulated islets in an autoimmune type 1 diabetes murine model showed enhanced cell survival over unencapsulated islets in the absence of chronic systemic immunosuppression. This method demonstrates a translatable alternative to intraperitoneal encapsulated islet transplant.

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Section: Resultssupporting

confidence: 77%

Synthetic poly(ethylene glycol)-based microfluidic islet encapsulation reduces graft volume for delivery to highly vascularized and retrievable transplant site

Weaver

Headen

Coronel

et al. 2019

American Journal of Transplantation

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“…These rates are a function of the diameter, composition and mechanical properties of the hydrogel, as well as, of the size of the diffusing particles and thus, smaller molecules could diffuse at the same rate as larger ones for hydrogels of different compositions (Gautier et al, 2011;Sun et al, 2018). Of note, the physical barrier imposed by the hydrogel did not impair mass transfer of 150 kDa dextran, reinforced by studies demonstrating alginate permeability to large molecules up to 500 kDa (Khalil et al, 2001;Mobed-Miremadi et al, 2014). Design parameters of fluidized bed bioreactors can also influence mass transfer: increasing the number of holes and pressure drop across the distributor increases the mass transfer coefficient (Kalaga et al, 2014).…”

Section: Discussionmentioning

confidence: 95%

Small-Scale Fluidized Bed Bioreactor for Long-Term Dynamic Culture of 3D Cell Constructs and in vitro Testing

Silva

Erro

Awan

et al. 2020

Front. Bioeng. Biotechnol.

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With the increasing interest in three-dimensional (3D) cell constructs that better represent native tissues, comes the need to also invest in devices, i.e., bioreactors, that provide a controlled dynamic environment similar to the perfusion mechanism observed in vivo. Here a laboratory-scale fluidized bed bioreactor (sFBB) was designed for hydrogel (i.e., alginate) encapsulated cells to generate a dynamic culture system that produced a homogenous milieu and host substantial biomass for long-term evolution of tissue-like structures and "per cell" performance analysis. The bioreactor design, conceptualized through scale-down empirical similarity rules, was initially validated through computational fluid dynamics analysis for the distributor capacity of homogenously dispersing the flow with an average fluid velocity of 4.596 × 10 −4 m/s. Experimental tests then demonstrated a consistent fluidization of hydrogel spheres, while maintaining shape and integrity (606.9 ± 99.3 µm diameter and 0.96 shape factor). It also induced mass transfer in and out of the hydrogel at a faster rate than static conditions. Finally, the sFBB sustained culture of alginate encapsulated hepatoblastoma cells for 12 days promoting proliferation into highly viable (>97%) cell spheroids at a high final density of 27.3 ± 0.78 million cells/mL beads. This was reproducible across multiple units set up in parallel and operating simultaneously. The sFBB prototype constitutes a simple and robust tool to generate 3D cell constructs, expandable into a multi-unit setup for simultaneous observations and for future development and biological evaluation of in vitro tissue models and their responses to different agents, increasing the complexity and speed of R&D processes.

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“…The 3 X increase in effectiveness factor (g MI /g MA) as a result of miniaturization could be further enhanced by switching from microspheres to microfibers. The ratio of experimentally measured membrane diffusivities for alginate-based MIs [35] and microfibers [57,58] for the 4 kDa fluorescent marker is 264 (2.03 Â 1 0 À11 m 2 /s/7.7 Â 10 À14 m 2 /s). The emergence of composite living microfiber technology in the fields of tissue engineering and regenerative medicine has simultaneously addressed the benefits of increasing the aspect ratio as well overcoming the susceptibility to swelling and degradation.…”

Section: Discussionmentioning

confidence: 99%

Effect of artificial cell miniaturization on urea degradation by immobilizedE. coliDH5α (pKAU17)

Duque

Shan

Joya

et al. 2018

Artificial Cells, Nanomedicine, and Biotechnology

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Second generation E. coli DH5α (pKAU17) was successfully encapsulated by means of atomization (MA), inkjet printing (MI) and double-encapsulation (DDMI) for the purpose of urea degradation in a simulated uremic medium at 37 °C. Experimentally determined values of the effectiveness factor are 0.83, 0.28 and 0.34 for the MI, MA and DDMI capsules, respectively, suggesting that the catalytic activity of the E. coli DH5α (pKAU17) immobilized in MI capsule (d = 52 μm ± 2.7 μm) is significantly less diffusion-limited than in the case of the MA (d = 1558 μm ± 125 μm) and DDMI (d = 1370 μm ± 60 μm) bio-encapsulation schemes at the 98.3% CI. The proposed novel double encapsulation biofabrication method for alginate-based microspheres, characterized by lower membrane degradation rates due to secondary containment is recommended compared to the standard atomization scheme currently adopted across immobilization-based therapeutic scenarios. A Fickian-based mechanism is proposed with simulations mimicking urea degradation for a single capsule for the atomization and the inkjet schemes.

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Fickian-Based Empirical Approach for Diffusivity Determination in Hollow Alginate-Based Microfibers Using 2D Fluorescence Microscopy and Comparison with Theoretical Predictions

Cited by 11 publications

References 60 publications

Synthetic poly(ethylene glycol)-based microfluidic islet encapsulation reduces graft volume for delivery to highly vascularized and retrievable transplant site

Synthetic poly(ethylene glycol)-based microfluidic islet encapsulation reduces graft volume for delivery to highly vascularized and retrievable transplant site

Small-Scale Fluidized Bed Bioreactor for Long-Term Dynamic Culture of 3D Cell Constructs and in vitro Testing

Effect of artificial cell miniaturization on urea degradation by immobilizedE. coliDH5α (pKAU17)

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