Materials Science in Additive Manufacturing                         Water repellence via pinecone structures



            of microfluidic chips with various customized micro/nano   2.   Elvira K, Solvas XC, Wootton RC, et al., 2013, The past,
            hierarchical features and tuned functions. There is a broad   present and potential for microfluidic reactor technology in
            potential application prospect for this technology. However,   chemical synthesis. Nat Chem, 5: 905–915.
            insufficient processing efficiency remains a significant      https://doi.org/10.1038/nchem.1753
            challenge. Incorporating TPP and other approaches will   3.   Vitorino R, Guedes S, da Costa JP, et al., 2021, Microfluidics
            offer a solution and allows cross-scale processing.   for peptidomics, proteomics, and cell analysis. Nanomaterials

            Acknowledgments                                       (Basel), 11: 1118.
                                                                  https://doi.org/10.3390/nano11051118
            The authors express their gratitude to Dr.  Liu Feng from
            Analytical Testing Center, Shandong University of Technology,   4.   Liu Y, Chen X, Zhang Y,  et al., 2019, Advancing single-
                                                                  cell  proteomics  and  metabolomics  with  microfluidic
            for her assistance in the characterization of the samples.
                                                                  technologies. Analyst, 144: 846–858.
            Funding                                               https://doi.org/10.1039/c8an01503a
            This work was financially supported by the National Key   5.   Maurya  R,  Gohil  N,  Bhattacharjee  G,  et al., 2022,
            R&D Program of China (grant number: 2022YFE0199100),   Microfluidics for single cell analysis. Prog Mol Biol Transl
            and Shandong Natural Science Foundation (grant numbers:   Sci, 186: 203–215.
            ZR2020QE030 and ZR2022ZD07).                          https://doi.org/10.1016/bs.pmbts.2021.07.013

            Conflict of interest                               6.   Luo X, Chen JY, Ataei M,  et al., 2022, Microfluidic
                                                                  compartmentalization platforms for single cell analysis.
            No potential conflicts of interest were reported by the authors.  Biosensors (Basel), 12: 58.
            Author contributions                                  https://doi.org/10.3390/bios12020058
                                                               7.   Filippi M, Buchner T, Yasa O, et al., 2022, Microfluidic tissue
            Conceptualization: Wenhui Yu, Weilong Cao, Zhen Xiao  engineering and bio-actuation. Adv Mater, 34: e2108427.
            Formal analysis: Wenhui Yu, Weilong Cao, Zhen Xiao,
               Yongling Wu                                        https://doi.org/10.1002/adma.202108427
            Funding acquisition: Wenhui Yu, Hongyu Zheng       8.   Takehara H, Sakaguchi K, Sekine H, et al., 2019, Microfluidic
            Investigation: Wenhui Yu, Weilong Cao, Wuhong Xin     vascular-bed devices for vascularized 3D tissue engineering:
            Methodology: Wenhui Yu, Weilong Cao, Zhen Xiao        Tissue engineering on a chip. Biomed Microdevices, 22: 9.
            Project administration: Wenhui Yu, Hongyu Zheng       https://doi.org/10.1007/s10544-019-0461-2
            Supervision: Wenhui Yu, Hongyu Zheng               9.   Zhang Z, Guo Q, Wang Y,  et al., 2023, High-throughput
            Writing – original draft: Weilong Cao                 screening of microbial strains in large-scale microfluidic
            Writing –  review &  editing: Wenhui Yu, Zhen Xiao,   droplets. Front Bioeng Biotechnol, 11: 1105277.
               Yongling Wu, Hongyu Zheng
                                                                  https://doi.org/10.3389/fbioe.2023.1105277
            Ethics approval and consent to participate         10.  Carvalho RM, Ferreira VS, Lucca BG, et al., 2021, A novel
                                                                  all-3D-printed thread-based microfluidic device with
            Not applicable.
                                                                  an embedded electrochemical detector: First application
            Consent for publication                               in  environmental  analysis  of  nitrite.  Anal Methods,
                                                                  13: 1349–1357.
            Not applicable.                                       https://doi.org/10.1039/d1ay00070e
            Availability of data                               11.  Yamada K,  Shibata  H, Suzuki  K,  et al., 2017,  Toward
                                                                  practical application of paper-based microfluidics for
            Data related to this work can be acquired by contacting the   medical diagnostics: State-of-the-art and challenges.  Lab
            corresponding author with a reasonable justification.  Chip, 17: 1206–1249.

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            Volume 2 Issue 2 (2023)                         8                       https://doi.org/10.36922/msam.0879