International Journal of Bioprinting      Programmable formaldehyde dehydrogenase for biodegradation formaldehyde































                                       Figure 9. Different shapes are printed using 3D printing technology.


            Foundation of Fujian Province (2021J05058), State Key   References
            Laboratory of Microbial Technology Open Projects Fund
            (Project NO. M2022-02), the Fundamental Research   1.   Jiang W, Pei R, Zhou SF, 2020, 3D-printed xylanase
            Funds  for  the  Central  Universities  (No.  ZQN-814),  the   within biocompatible polymers as excellent catalyst for
            high-level personnel activation fee of Huaqiao University   lignocellulose degradation.  Chem Eng J, 400:125920–
            (No. 600005-Z17Y0072), and Quanzhou City Science &    125928.
            Technology Program of China (No. 2018C008).        2.   Cogliano VJ, Baan R, Ghissassi FE, et al., 2006, Formaldehyde,
                                                                  2-butoxyethanol and 1-tert-butoxypropan-2-ol. Iarc Monogr
            Conflict of interest                                  Eval Carcinog Risks Hum, 88:1–478.
            The authors declare that they have no known competing   3.   Yuan Z, Yang C, Meng F, 2021, Strategies for improving
            financial interests or personal relationships that could have   the  sensing  performance of semiconductor  gas  sensors
                                                                  for high-performance formaldehyde detection: A review.
            appeared to influence the work reported in this paper.
                                                                  Chemosensors, 9(7):179–204.
            Author contributions                               4.   Ws A, Lc B, Lei WA, et al., 2021, The influence of doping
                                                                  amount on the catalytic oxidation of formaldehyde by Mn-
            Conceptualization: Shuyan Zhao, Wei Jiang             CeO  mixed oxide catalyst: A combination of DFT and
                                                                      2
            Data curation: Shuyan Zhao, Bo Zeng                   microkinetic study. J Hazard Mater, 425:127985.
            Funding acquisition: Wei Jiang                     5.   Ma L, Seo CY, Chen X,  et al., 2018, Schwank, sodium-
            Investigation: Shuyan Zhao, Bo Zeng                   promoted Ag/CeO2 nanospheres for catalytic oxidation of
                                                                  formaldehyde. Chem Eng J, 350:419–428.
            Ethics approval and consent to participate
                                                               6.   Xu Z, Qin N, Wang J, et al., 2010, Formaldehyde biofiltration
            Not applicable.                                       as affected by spider plant. Biores Technol, 101(18):6930–6934.
                                                               7.   Rong S, Zhang P, Wang J, et al., 2016, Ultrathin manganese
            Consent for publication                               dioxide nanosheets for formaldehyde removal and
            Not applicable.                                       regeneration performance. Chem Eng J, 306:1172–1179.
                                                               8.   Huang H, Hu P, Huang H, et al., 2014, Highly dispersed and
            Availability of data                                  active supported Pt nanoparticles for gaseous formaldehyde
                                                                  oxidation: Influence of particle size. Chem Eng J, 252:320–326.
            Not applicable.




            Volume 9 Issue 3 (2023)                        129                          https://doi.org/10.18063/ijb.695