Enhancing long‐term storage and stability of engineered living materials through desiccant storage and trehalose treatment

Brooks, Sierra M.; Reed, Kevin B; Yuan, Shuo‐Fu; Altin-Yavuzarslan, Gokce; Shafranek, Ryan T.; Nelson, Alshakim; Alper, Hal S.

doi:10.1002/bit.28271

Cited by 4 publications

(5 citation statements)

References 44 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…When the samples cultured over 21 d, high cell density were observed in µ CT (Figure 3b), which showed the S. cerevisiae cells were able to grow in the BSA‐PEGDA network, similar in time but different in spatial organization from another ELM formulation we previously studied. [ 22 ]…”

Section: Resultsmentioning

confidence: 99%

“…When the samples cultured over 21 d, high cell density were observed in µCT (Figure 3b), which showed the S. cerevisiae cells were able to grow in the BSA-PEGDA network, similar in time but different in spatial organization from another ELM formulation we previously studied. [22] Scanning electron microscopy (SEM) analysis of the dehydrated cylindrical samples were additionally used to assess the cell distribution and proliferation throughout the printed structure. Cross-sectional images were taken from different regions of a printed cylinder (Figure 3c) of ELM-SC-BXN and ELM-EC-LDOPA after 3 days of culturing, which showed the presence of spherical-shaped yeast cells [23] and rod-shaped bacterial cells, [24] respectively (Figure 3).…”

Section: Cell Distribution and Morphology Of Cells In 3d-printed Elmsmentioning

confidence: 99%

See 1 more Smart Citation

Additive Manufacturing of Engineered Living Materials with Bio‐Augmented Mechanical Properties and Resistance to Degradation

Altin-Yavuzarslan

Brooks

Yuan

et al. 2023

Adv Funct Materials

Self Cite

View full text Add to dashboard Cite

Engineered living materials (ELMs) combine living cells with polymeric matrices to yield unique materials with programmable functions. While the cellular platform and the polymer network determine the material properties and applications, there are still gaps in the ability to seamlessly integrate the biotic (cellular) and abiotic (polymer) components into singular materials, then assemble them into devices and machines. Herein, the additive-manufacturing of ELMs wherein bioproduction of metabolites from the encapsulated cells enhanced the properties of the surrounding matrix is demonstrated. First, aqueous resins are developed comprising bovine serum albumin (BSA) and poly(ethylene glycol diacrylate) (PEGDA) with engineered microbes for vat photopolymerization to create objects with a wide array of 3D form factors. The BSA-PEGDA matrix afforded hydrogels that are mechanically stiff and tough for use in load-bearing applications. Second, the continuous in situ production of l-DOPA, naringenin, and betaxanthins from the engineered cells encapsulated within the BSA-PEGDA matrix is demonstrated. These microbial metabolites bioaugmented the properties of the BSA-PEGDA matrix by enhancing the stiffness (l-DOPA) or resistance to enzymatic degradation (betaxanthin). Finally, the assembly of the 3D printed ELM components into mechanically functional bolts and gears to showcase the potential to create functional ELMs for synthetic living machines is demonstrated.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Cell Distribution and Morphology Of Cells In 3d-printed Elmsmentioning

confidence: 99%

Additive Manufacturing of Engineered Living Materials with Bio‐Augmented Mechanical Properties and Resistance to Degradation

Altin-Yavuzarslan

Brooks

Yuan

et al. 2023

Adv Funct Materials

Self Cite

View full text Add to dashboard Cite

show abstract

“…To bypass the challenges of liquid culture-based production flexibility and co-culture stability, the use of ELMs has been proposed 31 , 33 , 34 . Here, we sought to apply the principles of encapsulation-based production to 2- and 3- part consortia for ferulic acid and eugenol production, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…These ELM-based approaches can uniquely support stable co-cultures by spatially encapsulating individual microbes to avoid growth-based competitions that can occur during outgrowth and repeated culturing. Additionally, ELM bioproduction can enable on-demand production without cold-chain requirements, with over one year of shelf stability for encapsulated fungal bioproduction systems 34 , thus enabling resource-limited biomanufacturing 35 . On-demand phenylpropene production would be advantageous as these compounds have limited stability at elevated temperatures 36 , 37 .…”

Section: Introductionmentioning

confidence: 99%

A tripartite microbial co-culture system for de novo biosynthesis of diverse plant phenylpropanoids

Brooks¹,

Marsan²,

Reed³

et al. 2023

Nat Commun

Self Cite

View full text Add to dashboard Cite

Plant-derived phenylpropanoids, in particular phenylpropenes, have diverse industrial applications ranging from flavors and fragrances to polymers and pharmaceuticals. Heterologous biosynthesis of these products has the potential to address low, seasonally dependent yields hindering ease of widespread manufacturing. However, previous efforts have been hindered by the inherent pathway promiscuity and the microbial toxicity of key pathway intermediates. Here, in this study, we establish the propensity of a tripartite microbial co-culture to overcome these limitations and demonstrate to our knowledge the first reported de novo phenylpropene production from simple sugar starting materials. After initially designing the system to accumulate eugenol, the platform modularity and downstream enzyme promiscuity was leveraged to quickly create avenues for hydroxychavicol and chavicol production. The consortia was found to be compatible with Engineered Living Material production platforms that allow for reusable, cold-chain-independent distributed manufacturing. This work lays the foundation for further deployment of modular microbial approaches to produce plant secondary metabolites.

show abstract

“…This exotherm arises from the thermal polymerization of unreacted acrylates in the samples. [26,27] However, when these samples are treated with a post-print cure, wherein the constructs are irradiated with 400 nm in a custom photocuring chamber (Quans, 400 nm, 1 mW cm −2 ) for 60 min, the exothermic peak was not present for any of the samples (Figure 2d-e). When glycerol was present in the resin formulation this peak was absent, which suggests that glycerol may promote efficient network formation by aggregating the PEGDA chains to facilitate the reaction of the chain ends.…”

Section: Glycerol Improves the 3d Printing Resolution And Mechanical ...mentioning

confidence: 99%

Engineered Living Material Bioreactors with Tunable Mechanical Properties using Vat Photopolymerization

Altin‐Yavuzarslan,

Sadaba,

Brooks

et al. 2023

Small

Self Cite

View full text Add to dashboard Cite

Abstract3D‐printed engineered living materials (ELM) are promising bioproduction platforms for agriculture, biotechnology, sustainable energy, and green technology applications. However, the design of these platforms faces several challenges, such as the processability of these materials into complex form factors and control over their mechanical properties. Herein, ELM are presented as 3D‐printed bioreactors with arbitrary shape geometries and tunable mechanical properties (moduli and toughness). Poly(ethylene glycol) diacrylate (PEGDA) is used as the precursor to create polymer networks that encapsulate the microorganisms during the vat photopolymerization process. A major limitation of PEGDA networks is their propensity to swell and fracture when submerged in water. The authors overcame this issue by adding glycerol to the resin formulation to 3D print mechanically tough ELM hydrogels. While polymer concentration affects the modulus and reduces bioproduction, ELM bioreactors still maintain their metabolic activity regardless of polymer concentration. These ELM bioreactors have the potential to be used in different applications for sustainable architecture, food production, and biomedical devices that require different mechanical properties from soft to stiff.

show abstract

Enhancing long‐term storage and stability of engineered living materials through desiccant storage and trehalose treatment

Cited by 4 publications

References 44 publications

Additive Manufacturing of Engineered Living Materials with Bio‐Augmented Mechanical Properties and Resistance to Degradation

Additive Manufacturing of Engineered Living Materials with Bio‐Augmented Mechanical Properties and Resistance to Degradation

A tripartite microbial co-culture system for de novo biosynthesis of diverse plant phenylpropanoids

Engineered Living Material Bioreactors with Tunable Mechanical Properties using Vat Photopolymerization

Contact Info

Product

Resources

About