Guidelines for standardization of bioprinting: a systematic study of process parameters and their effect on bioprinted structures

Kesti, Matti; Fisch, Philipp; Pensalfini, Marco; Mazza, Edoardo; Zenobi‐Wong, Marcy

doi:10.1515/bnm-2016-0004

Cited by 37 publications

(34 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To do so, an established bioink made from alginate and gellan gum was used. [21,22] We further tested the sensitivity of the extrusion process to increased polymer content, addition of hydroxyapatite particles, and commercial source of alginate (Figure 1 C, Bioink 1-4). Accuracy and precision of the two methods were determined by comparing the actual weight of the printed constructs compared to the targeted weight, after both printing processes were optimized.…”

Section: Introductionmentioning

confidence: 99%

Improved accuracy and precision of bioprinting through progressive cavity pump-controlled extrusion

Fisch

Holub

Zenobi‐Wong

2020

Preprint

Self Cite

View full text Add to dashboard Cite

3D bioprinting has seen a tremendous growth in recent years in a variety of fields such as tissue and organ models, drug testing and regenerative medicine. This growth has led researchers and manufacturers to continuously advance and develop novel bioprinting techniques and materials. Although new bioprinting methods are emerging (e.g. contactless and volumetric bioprinting), micro-extrusion bioprinting remains the most widely used method. Micro-extrusion bioprinting, however, is still largely dependent on the conventional pneumatic extrusion process, which relies heavily on homogenous biomaterial inks and bioinks to maintain a constant material flowrate. Augmenting the functionality of the bioink with the addition of nanoparticles, cells or biopolymers can induce inhomogeneities resulting in uneven material flow during printing and/or clogging of the nozzle, leading to defects in the printed construct. In this work, we evaluated a novel extrusion technique based on a miniaturized progressive cavity pump. We compared the accuracy and precision of this system to the pneumatic extrusion system and tested both for their effect on cell viability after extrusion. The progressive cavity pump achieved a significantly higher accuracy and precision compared to the pneumatic system while maintaining good viability and was able to maintain its reliability independently of the bioink composition, printing speed or nozzle size. Progressive cavity pumps are a promising tool for bioprinting and could help provide standardized and validated bioprinted constructs while leaving the researcher more freedom in the design of the bioinks with increased functionality.

show abstract

Section: Introductionmentioning

confidence: 99%

Improved accuracy and precision of bioprinting through progressive cavity pump-controlled extrusion

Fisch

Holub

Zenobi‐Wong

2020

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Furthermore, the shear recovery of the support inks was tested, following the proposed protocols of Paxton and co-workers and Kesti and co-workers [13,28]. Therefore, firstly a low shear rate of 5 s −1 was applied for 200 s, followed by a hundred-fold higher shear rate of 500 s −1 for 100 s. This procedure was repeated two times.…”

Section: Resultsmentioning

confidence: 99%

“…Shear thinning was characterized by increasing the shear rate from 0–100 s −1 over 1200 s (increment 0.08 s −1 ) and viscosity was measured ( n = 3). Shear recovery of the mc pastes ( n = 3) was characterized orientating at the protocols proposed by Paxton and co-workers and Kesti and co-workers [13,28]. Firstly, a constant shear rate of 5 s −1 was applied for 200 s, followed by a hundred-fold higher shear rate of 500 s −1 for 100 s. This procedure was repeated two times.…”

Section: Methodsmentioning

confidence: 99%

A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds

Ahlfeld

Köhler

Czichy

et al. 2018

Gels

View full text Add to dashboard Cite

3D plotting is an additive manufacturing technology enabling biofabrication, thus the integration of cells or biologically sensitive proteins or growth factors into the manufacturing process. However, most (bio-)inks developed for 3D plotting were not shown to be processed into clinically relevant geometries comprising critical overhangs and cavities, which would collapse without a sufficient support material. Herein, we have developed a support hydrogel ink based on methylcellulose (mc), which is able to act as support as long as the co-plotted main structure is not stable. Therefore, 6 w/v %, 8 w/v % and 10 w/v % mc were allowed to swell in water, resulting in viscous inks, which were characterized for their rheological and extrusion properties. The successful usage of 10 w/v % mc as support ink was proven by multichannel plotting of the support together with a plottable calcium phosphate cement (CPC) acting as main structure. CPC scaffolds displaying critical overhangs or a large central cavity could be plotted accurately with the newly developed mc support ink. The dissolution properties of mc allowed complete removal of the gel without residuals, once CPC setting was finished. Finally, we fabricated a scaphoid bone model by computed tomography data acquisition and co-extrusion of CPC and the mc support hydrogel.

show abstract

“…Exemplarily, the viscosity of the biomaterial inks at a shear rate of 10 s -1 was evaluated ( Furthermore, the shear recovery of the support inks was tested, following the proposed protocols of Paxton and co-workers and Kesti and co-workers. [17,18] Therefore, firstly a low shear rate of 5 s -1 was applied for 200 s, followed by a hundred-fold higher shear rate of 500 s -1 for 100 s. This procedure was repeated two times. Representative curves are shown in Figure 2.…”

Section: Development and Rheological Characterisation Of Methylcellulmentioning

confidence: 99%

“…Shear thinning was characterized by increasing the shear rate from 0-100 s -1 over 1200 s (increment 0.08 s -1 ) and viscosity was measured (n=3). Shear recovery of the mc pastes was characterized orientating at the protocols proposed by Paxton and co-workers and Kesti and co-workers [17,18]. Firstly, a constant shear rate of 5 s -1 was applied for 200 s, followed by a hundred-fold higher shear rate of 500 s -1 for 100 s. This procedure was repeated two times.…”

Section: Rheologymentioning

confidence: 99%

A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds

Ahlfeld¹,

Köhler²,

Czichy³

et al. 2018

Preprint

View full text Add to dashboard Cite

Guidelines for standardization of bioprinting: a systematic study of process parameters and their effect on bioprinted structures

Cited by 37 publications

References 26 publications

Improved accuracy and precision of bioprinting through progressive cavity pump-controlled extrusion

Improved accuracy and precision of bioprinting through progressive cavity pump-controlled extrusion

A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds

A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds

Contact Info

Product

Resources

About