Demonstration of protein capture and separation using three‐dimensional printed anion exchange monoliths fabricated in one‐step

Galindo-Rodriguez

et al. 2022

Bioresour. Bioprocess.

Self Cite

Background 3D printing is revolutioning many industrial sectors and has the potential to enhance also the biotechnology and bioprocessing fields. Here, we propose a new flexible material formulation to 3D print support matrices with complex, perfectly ordered morphology and with tuneable properties to suit a range of applications in bioprocess engineering. Findings Supports were fabricated using functional monomers as the key ingredients, enabling matrices with bespoke chemistry, such as charged groups, chemical moieties for further functionalization, and hydrophobic/hydrophilic groups. Other ingredients, e.g. crosslinkers and porogens, can be employed to fabricate supports with diverse characteristics of their porous network, providing an opportunity to further regulate the mechanical and mass transfer properties of the supports. Through this approach, we fabricated and demonstrated the operation of Schoen gyroid columns with (I) positive and negative charges for ion exchange chromatography, (II) enzyme bioreactors with immobilized trypsin to catalyse hydrolysis, and (III) bacterial biofilm bioreactors for fuel desulphurization. Conclusions This study demonstrates a simple, cost-effective, and flexible fabrication of customized 3D printed supports for different biotechnology and bioengineering applications.

Section: Application As Stationary Phase For Ion Exchange Chromatographymentioning

confidence: 81%

Flexible material formulations for 3D printing of ordered porous beds with applications in bioprocess engineering

Galindo-Rodriguez

et al. 2022

Bioresour. Bioprocess.

Self Cite

“…Maximum binding capacities of 104.2 ± 10.6 mg of BSA per mL of AETAC-based support, and 108.1 ± 25.9 mg of LYS per mL of CEA-based material were recorded (Figure 2a and 2b), about 5 fold higher than for commercial monoliths (Hahn et al, 2002) and chromatographic membranes (Boi et al, 2020) and in line or above standard chromatographic resins (Staby et al, 2005). Testing in dynamic conditions was carried out using Schoen gyroid columns (Figure 1f-h) by loading BSA and myoglobin (MYO) onto the AETAC material (Figure 2c, Simon et al, 2020) and BSA and LYS on the CEA material (Figure 2d). The chromatograms reveal elution patterns in line with the electrostatic interactions established at the buffer's pH, thus con rming the availability of the surface quaternary amine and carboxyl groups to establish appropriate electrostatic interactions with the protein models.…”

Section: Application As Stationary Phase For Ion Exchange Chromatographymentioning

confidence: 99%

Flexible Material Formulations for 3D Printing of Porous Beds with Applications in Bioprocess Engineering

Galindo-Rodriguez

et al. 2022

Preprint

Self Cite

Background: 3D printing is revolutionizing many industrial sectors and has the potential to enhance also the biotechnology and bioprocessing fields. Here, we propose a new flexible material formulation to 3D print support matrices with complex, perfectly ordered morphology and with tuneable properties to suit a range of applications in bioprocess engineering. Findings: Supports for packed-bed operations were fabricated using functional monomers as the key ingredients, enabling matrices with bespoke chemistry such as charged groups, chemical moieties for further functionalization, and hydrophobic/hydrophilic groups. Other ingredients, e.g. crosslinkers and porogens, provide the opportunity to further tune the mechanical properties of the supports and the morphology of their porous network. Through this approach, we fabricated and demonstrated the operation of Schoen gyroid columns with I) positive and negative charges for ion-exchange chromatography, II) enzyme bioreactors with immobilized trypsin to catalyse hydrolysis, and III) bacterial biofilms bioreactors for fuel desulfurization. Conclusions: This study demonstrates a simple, cost-effective and flexible fabrication of customized 3D printed supports for different biotechnology and bioengineering applications.

“…Figure 2. Adsorption isotherms of (a) bovine serum albumin (BSA) on anion exchangers (based on AETAC monomer, adapted from Simon et al, 2020), and (b) lysozyme (LYS) on cation exchangers (based on CEA monomer). Ligand densities of 0 (control), 0.57, 1.14, 1.73, 2.33 mmol/mL and of 0 (control), 0.77, 1.56, 2.36, 3.23 mmol/mL were tested for the anion and cation exchanger, respectively.…”

Section: Acknowledgementsmentioning

confidence: 99%

“…Maximum binding capacities of 104.2 ± 10.6 mg of BSA per mL of AETAC-based support, and 108.1 ± 25.9 mg of LYS per mL of CEA-based material were recorded (Figure 2a and 2b), about 5 fold higher than for commercial monoliths (Hahn et al, 2002) and chromatographic membranes (Boi et al, 2020) and in line or above standard chromatographic resins (Staby et al, 2005). Testing in dynamic conditions was carried out using Schoen gyroid columns ( Figure 1f-h) by loading BSA and myoglobin (MYO) onto the AETAC material ( Figure 2c, Simon et al, 2020) and BSA and LYS on the CEA material ( Figure 2d). The chromatograms reveal elution pattern in line with the electrostatic interactions established at the buffer's pH, thus confirming the availability of the surface quaternary amine and carboxyl groups to establish appropriate electrostatic interactions with the protein models.…”

Section: Introductionmentioning

confidence: 99%

Flexible material formulations for 3D printing of porous beds with applications in bioprocess engineering

Rodriguez

et al. 2021

Preprint

Self Cite

3D printing is revolutionizing many industrial sectors and has the potential to enhance also the biotechnology and bioprocessing fields. Here, we propose a new flexible material formulation to 3D print support matrices with complex, perfectly ordered morphology and with tuneable properties to suit a range of applications in bioprocess engineering. Supports for packed-bed operations were fabricated using functional monomers as the key ingredients, enabling matrices with bespoke chemistry such as charged groups, chemical moieties for further functionalization, and hydrophobic/hydrophilic groups. Other ingredients, e.g. crosslinkers and porogens, provide the opportunity to further tune the mechanical properties of the supports and the morphology of their porous network. Through this approach, we fabricated and demonstrated the operation of Schoen gyroid columns with I) positive and negative charges for ion-exchange chromatography, II) enzyme bioreactors with immobilized trypsin to catalyse hydrolysis, and III) bacterial biofilms bioreactors for fuel desulfurization. We expect this approach will enable simple, cost-effective and flexible fabrication of customized supports in biotechnology and bioengineering.