運用改良式膨壓探針探討捕蠅草膨壓動態與多尺度形變之關聯性

王啓恩; Chi-En Wang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101842

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	王俊能	zh_TW
dc.contributor.advisor	Chun-Neng Wang	en
dc.contributor.author	王啓恩	zh_TW
dc.contributor.author	Chi-En Wang	en
dc.date.accessioned	2026-03-04T17:01:22Z	-
dc.date.available	2026-03-05	-
dc.date.copyright	2026-03-04	-
dc.date.issued	2026	-
dc.date.submitted	2026-01-31	-
dc.identifier.citation	Ali, O., Cheddadi, I., Landrein, B., & Long, Y. (2023). Revisiting the relationship between turgor pressure and plant cell growth. New Phytologist, 238(1), 62-69. Baskin, T. I. (2005). Anisotropic expansion of the plant cell wall. Annu. Rev. Cell Dev. Biol., 21(1), 203-222. Beauzamy, L., Nakayama, N., & Boudaoud, A. (2014). Flowers under pressure: ins and outs of turgor regulation in development. Annals of botany, 114(7), 1517-1533. Buckley, T. N. (2019). How do stomata respond to water status?. New Phytologist, 224(1), 21-36. Colombani, M., & Forterre, Y. (2011). Biomechanics of rapid movements in plants: poroelastic measurements at the cell scale. Computer Methods in Biomechanics and Biomedical Engineering, 14(sup1), 115-117. Cosgrove, D. J. (1987). Wall relaxation and the driving forces for cell expansive growth. Plant physiology, 84(3), 561-564. Cosgrove, D. J., & Durachko, D. M. (1986). Automated pressure probe for measurement of water transport properties of higher plant cells. Review of scientific instruments, 57(10), 2614-2619. Forterre, Y., Skotheim, J. M., Dumais, J., & Mahadevan, L. (2005). How the Venus flytrap snaps. Nature, 433(7024), 421-425. Hansen, S. L., Ray, P. M., Karlsson, A. O., Jørgensen, B., Borkhardt, B., Petersen, B. L., & Ulvskov, P. (2011). Mechanical properties of plant cell walls probed by relaxation spectra. Plant Physiology, 155(1), 246-258. Harold, F. M. (2002). Force and compliance: rethinking morphogenesis in walled cells. Fungal Genetics and Biology, 37(3), 271-282. Hill, B. S., & Findlay, G. P. (1981). The power of movement in plants: the role of osmotic machines. Quarterly reviews of biophysics, 14(2), 173-222. Hodick, D., & Sievers, A. (1989). On the mechanism of trap closure of Venus flytrap (Dionaea muscipula Ellis). Planta, 179(1), 32-42. Mano, H., & Hasebe, M. (2021). Rapid movements in plants. Journal of plant research, 134(1), 3-17. Markin, V. S., & Volkov, A. G. (2012). Morphing structures in the Venus flytrap. In Plant Electrophysiology: Signaling and Responses (pp. 1-31). Berlin, Heidelberg: Springer Berlin Heidelberg. Markin, V. S., Volkov, A. G., & Jovanov, E. (2008). Active movements in plants: mechanism of trap closure by Dionaea muscipula Ellis. Plant signaling & behavior, 3(10), 778-783. Poppinga, S., Kampowski, T., Metzger, A., Speck, O., & Speck, T. (2016). Comparative kinematical analyses of Venus flytrap (Dionaea muscipula) snap traps. Beilstein Journal of Nanotechnology, 7(1), 664-674. Sachse, R., Westermeier, A., Mylo, M., Nadasdi, J., Bischoff, M., Speck, T., & Poppinga, S. (2020). Snapping mechanics of the Venus flytrap (Dionaea muscipula). Proceedings of the National Academy of Sciences, 117(27), 16035-16042. Sleboda, D. A. (2023). Exploring the dual functionality of plant pulvini using a physical modeling approach. Integrative and Comparative Biology, 63(6), 1331-1339. Sleboda, D. A., Geitmann, A., & Sharif-Naeini, R. (2023). Multiscale structural anisotropy steers plant organ actuation. Current Biology, 33(4), 639-646. Tomos, A. D., & Leigh, R. A. (1999). The pressure probe: a versatile tool in plant cell physiology. Annual review of plant biology, 50(1), 447-472. Volkov, A. G., Harris II, S. L., Vilfranc, C. L., Murphy, V. A., Wooten, J. D., Paulicin, H., ... & Markin, V. S. (2013). Venus flytrap biomechanics: forces in the Dionaea muscipula trap. Journal of plant physiology, 170(1), 25-32. Wang, X., Khara, A., & Chen, C. (2020). A soft pneumatic bistable reinforced actuator bioinspired by Venus Flytrap with enhanced grasping capability. Bioinspiration & Biomimetics, 15(5), 056017. Wermelink, M. H., Sachse, R., Kruppert, S., Speck, T., & Tauber, F. J. (2026). Model to Model: Understanding the Venus Flytrap Snapping Mechanism and Transferring it to a 3D-printed Bistable Soft Robotic Demonstrator. In Conference on Biomimetic and Biohybrid Systems (pp. 179-192). Springer, Cham. Yi, H., Chen, Y., & Anderson, C. T. (2022). Turgor pressure change in stomatal guard cells arises from interactions between water influx and mechanical responses of their cell walls. Quantitative Plant Biology, 3, e12. Yi, H., Chen, Y., & Anderson, C. T. (2022). Turgor pressure change in stomatal guard cells arises from interactions between water influx and mechanical responses of their cell walls. Quantitative Plant Biology, 3, e12. Yoshida, S., Song, Q., Rapp, B. E., Speck, T., & Tauber, F. J. (2026). Thermo-responsive closing and reopening artificial Venus Flytrap utilizing shape memory elastomers. In Conference on Biomimetic and Biohybrid Systems (pp. 3-15). Springer, Cham. Zeng, X., Wang, Y., & Morishima, K. (2025). Asymmetric-bifurcation snapping, all-or-none motion of Venus flytrap. Scientific Reports, 15(1), 4805.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101842	-
dc.description.abstract	研究快速植物運動的生物力學機制長期以來是一項挑戰，主要原因在於其運動時間尺度遠快於單純水力傳輸所能解釋的範圍。以捕蠅草為例，膨壓被認為與捕蟲葉片的閉合密切相關，但由於缺乏在活體組織中的直接量測證據，無法確認膨壓是閉合的直接驅動力，或僅負責建立預應力 (prestress) 的準備狀態。我們利用改良式膨壓探針，直接量測補蠅草葉片中肋腹側與背側的膨壓動態，並比較完全水合、脫水與復水條件下的壓力特徵。此外，結合掃描式電子顯微鏡分析組織的結構方向性，進一步探討絕對膨壓與腹背壓力比值在運動過程中的關聯性。結果顯示，陷阱閉合並非由局部膨壓上升所驅動，而是腹背兩側膨壓同時下降，且腹背壓力比值在開放與閉合狀態間呈現反轉，此現象僅出現在具閉合能力的陷阱中。結構分析進一步顯示，腹背表皮層在細胞排列上的差異，為等向性膨壓轉換為方向性形變提供了結構基礎。綜上所述，膨壓並非捕蠅草閉合的直接驅動力，而是建立可供細胞壁快速釋放彈性的預應力力學狀態；組織層級的結構各向異性則決定了能量轉換的方向性。水合狀態透過調控預應力的可用性與分配，形成決定捕蠅草快速閉合的臨界條件。	zh_TW
dc.description.abstract	The biomechanics of rapid plant movements often exceed the speeds achievable through simple hydraulics. In the Venus flytrap, the exact mechanical role of turgor pressure has remained debated due to a lack of direct in vivo measurements. This study clarifies these dynamics using a modified injection-type pressure probe to monitor adaxial and abaxial midrib turgor under varying hydration conditions. Our results demonstrate that trap closure is not driven by increasing localized pressure; instead, snapping is consistently accompanied by a marked turgor decrease on both sides. While pressure remains constant across tissue layers, a stable inversion of the adaxial-to-abaxial pressure ratio is essential for functional closure. Scanning electron microscopy reveals pronounced structural anisotropy, with perpendicular to each other cellular alignments between the upper and lower epidermis. This architecture provides the template for converting isotropic turgor into directional deformation. We conclude that turgor pressure functions primarily as a physiological source of prestress, enabling elastic energy storage. Hydration status directly determines the functional capacity of the snapping mechanism.	en
dc.description.provenance	Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2026-03-04T17:01:22Z No. of bitstreams: 0	en
dc.description.provenance	Made available in DSpace on 2026-03-04T17:01:22Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	致謝 i 中文摘要 ii Abstract iii Contents iv Index of Figures vii Introduction 1 Aim of this study 7 Materials and Methods 8 2.1 Plant material and growth conditions 8 2.2 Experimental states and definition of trap configurations 8 2.2.1 Physiological hydration conditions 8 2.2.2 Definition of trap configurations 9 2.2.3 Mechanical stimulation protocol 9 2.3 Modified pressure probe setup 10 2.3.1 Glass microcapillary preparation 11 2.3.2 Oil filling 11 2.3.3 Pressure calibration 11 2.3.4 Sample targeting and pressure measurement protocol 12 2.4 Effects of hydration conditions 14 2.5 Scanning electron microscopy and structural characterization 15 Results 17 3.1 Functional performance of the modified pressure probe 17 3.2 Spatial distribution of turgor pressure along the midrib 19 3.3 Effect of hydration condition on turgor pressure 23 3.4 Structural anisotropy of trap tissues revealed by SEM 28 Discussion 31 4.1 Direct measurement of turgor pressure in living Venus flytrap 31 4.2 Turgor pressure as a prestressed state rather than a driving force 33 4.3 Structural anisotropy converts isotropic turgor pressure into directional deformation 36 Conclusion and Future Prospects 38 Reference 41	-
dc.language.iso	en	-
dc.subject	捕蠅草	-
dc.subject	膨壓	-
dc.subject	預應力	-
dc.subject	快速植物運動	-
dc.subject	彈性失穩	-
dc.subject	結構各向異性	-
dc.subject	植物生物力學	-
dc.subject	膨壓探針	-
dc.subject	Venus flytrap	-
dc.subject	turgor pressure	-
dc.subject	prestress	-
dc.subject	rapid plant movement	-
dc.subject	snap-through instability	-
dc.subject	structural anisotropy	-
dc.subject	plant biomechanics	-
dc.subject	pressure probe	-
dc.title	運用改良式膨壓探針探討捕蠅草膨壓動態與多尺度形變之關聯性	zh_TW
dc.title	Linking Turgor Pressure Dynamics to Multiscale Deformation in the Venus Flytrap Using a Modified Pressure Probe	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	紀凱容;許聿翔;陳香君	zh_TW
dc.contributor.oralexamcommittee	Kai-Jung Chi;Yu-Hsiang Hsu;Shiang-Jiuun Chen	en
dc.subject.keyword	捕蠅草,膨壓預應力快速植物運動彈性失穩結構各向異性植物生物力學膨壓探針	zh_TW
dc.subject.keyword	Venus flytrap,turgor pressureprestressrapid plant movementsnap-through instabilitystructural anisotropyplant biomechanicspressure probe	en
dc.relation.page	44	-
dc.identifier.doi	10.6342/NTU202600233	-
dc.rights.note	同意授權(限校園內公開)	-
dc.date.accepted	2026-02-03	-
dc.contributor.author-college	生命科學院	-
dc.contributor.author-dept	生命科學系	-
dc.date.embargo-lift	2029-01-31	-
顯示於系所單位：	生命科學系

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