All 3D-printed high-sensitivity adaptive hydrogel strain sensor for accurate plant growth monitoring

Lina Wang; Wen Wang; Rongtai Wan; Mutian Yao; Wenna Chen; Liuyu Zhang; Jingkun Xu; Ximei Liu; Baoyang Lu

doi:10.20517/ss.2024.38

Soft Science ›› 2025, Vol. 5 ›› Issue (1) :2 DOI: 10.20517/ss.2024.38

Research Article

All 3D-printed high-sensitivity adaptive hydrogel strain sensor for accurate plant growth monitoring

Lina Wang ¹^,²^,^#
, Wen Wang ¹^,^#
, Rongtai Wan ¹^,²^,^#
, Mutian Yao ¹^,²
, Wenna Chen ²
, Liuyu Zhang ³
, Jingkun Xu ¹
, Ximei Liu ¹^,²^,^*
, Baoyang Lu ¹^,²^,^*

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Abstract

Highly sensitive strain sensors are crucial for monitoring subtle plant growth changes and show diverse applications in plant sensing. However, the prevailing integrated fabrication methods for such sensors tend to be costly and complex, impeding their fundamental design and practical usage. Herein, we develop a simple and effective multimaterial all-3D printing technique to manufacture integrated strain sensors with a multilayered structure. Such an all-3D-printed strain sensor exhibits excellent sensing performance enabling precise detection of minor strains in plant growth, including high stretchability (> 300%), high sensitivity (~12.78) with good linearity (0.98), and good long-term stability over 3,000 loading/unloading cycles. We further validate the potential applications of our 3D-printed integrated strain sensor for accurate and continuous monitoring of bamboo growth in both horizontal and vertical directions over 14 days. Our all-3D-printed strain sensor offers a promising avenue for integrated strain sensing systems toward plant growth monitoring.

Keywords

Hydrogel strain sensor / 3D printing / high sensitivity / plant growth monitoring

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Lina Wang, Wen Wang, Rongtai Wan, Mutian Yao, Wenna Chen, Liuyu Zhang, Jingkun Xu, Ximei Liu, Baoyang Lu. All 3D-printed high-sensitivity adaptive hydrogel strain sensor for accurate plant growth monitoring. Soft Science, 2025, 5(1): 2 DOI:10.20517/ss.2024.38

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Lee HJ,Lee J.Liquid polymer/metallic salt-based stretchable strain sensor to evaluate fruit growth.ACS Appl Mater Interfaces2022;14:5983-94

[2]	Nagelmüller S,Yates S,Walter A.Leaf length tracker: a novel approach to analyse leaf elongation close to the thermal limit of growth in the field.J Exp Bot2016;67:1897-906 PMCID:PMC4783369

[3]	Li S,Ma W.Monitoring blood pressure and cardiac function without positioning via a deep learning-assisted strain sensor array.Sci Adv2023;9:eadh0615 PMCID:PMC10421034

[4]	Gong T,Huang W.Highly responsive flexible strain sensor using polystyrene nanoparticle doped reduced graphene oxide for human health monitoring.Carbon2018;140:286-95

[5]	Li J,Wang H.Engineering smart composite hydrogels for wearable disease monitoring.Nanomicro Lett2023;15:105 PMCID:PMC10105367

[6]	Zhang Z,Xue Y.Fatigue-resistant conducting polymer hydrogels as strain sensor for underwater robotics.Adv Funct Mater2023;33:2305705

[7]	Yang D,Gu G.High-stroke, high-output-force, fabric-lattice artificial muscles for soft robots.Adv Mater2024;36:e2306928

[8]	Li J,Lu B.3D-printed PEDOT:PSS for soft robotics.Nat Rev Mater2023;8:604-22

[9]	Yoon H,Choi C,Hwang B.Mini review on PEDOT:PSS as a conducting material in energy harvesting and storage devices applications.J Polym Mater2023;40:1-17

[10]	Sudhahar S,Alla JP,Lakshmi S.Acrylic finished leather upgraded with thermoplastic polyurethane filament using 3D printing - a new generation hybrid leather of synthetic and natural polymer.J Polym Mater2023;40:33-45

[11]	Shen Z,Huang S.Progress of flexible strain sensors for physiological signal monitoring.Biosens Bioelectron2022;211:114298

[12]	Lin J,Zhang P.Wireless bioelectronics for in vivo pressure monitoring with mechanically-compliant hydrogel biointerfaces.Adv Mater2024;36:2400181

[13]	Wan R,Quan Z.A reusable, healable, and biocompatible PEDOT:PSS hydrogel-based electrical bioadhesive interface for high-resolution electromyography monitoring and time–frequency analysis.Chem Eng J2024;490:151454

[14]	Ke X,Chen S.Reduced graphene oxide reinforced PDA-Gly-PVA composite hydrogel as strain sensors for monitoring human motion.Soft Sci2023;3:21

[15]	Yao X,Qian L.Super stretchable, self-healing, adhesive ionic conductive hydrogels based on tailor-made ionic liquid for high-performance strain sensors.Adv Funct Mater2022;32:2204565

[16]	Zhu H,Liu B,Qu S.3D printing of conductive hydrogel-elastomer hybrids for stretchable electronics.ACS Appl Mater Interfaces2021;13:59243-51

[17]	Yang J,Qi G.Ultrastretchable, multihealable, and highly sensitive strain sensor based on a double cross-linked MXene hydrogel.ACS Appl Mater Interfaces2023;15:17163-74

[18]	Wang F,Chen X.3D printed implantable hydrogel bioelectronics for electrophysiological monitoring and electrical modulation.Adv Funct Mater2024;34:2314471

[19]	Su X,Chen S.A highly conducting polymer for self-healable, printable, and stretchable organic electrochemical transistor arrays and near hysteresis-free soft tactile sensors.Adv Mater2022;34:e2200682

[20]	Wei J,Chen T.A fully hydrophobic ionogel enables highly efficient wearable underwater sensors and communicators.Mater Horiz2021;8:2761-70

[21]	Xiong Y,Zhao Z.A template-stripped carbon nanofiber/poly(styrene-butadiene-styrene) compound for high-sensitivity pressure and strain sensing.Soft Sci2022;2:14

[22]	Zhang J,Yang Z.Highly flexible and stretchable strain sensors based on conductive whisker carbon nanotube films.Carbon2021;176:139-47

[23]	Park H,Hong SY.A skin-integrated transparent and stretchable strain sensor with interactive color-changing electrochromic displays.Nanoscale2017;9:7631-40

[24]	Abed A,Cochrane C.Piezo-resistive properties of bio-based sensor yarn made with sisal fibre.Sensors2021;21:4083 PMCID:PMC8232028

[25]	Wu Z,Luo X.Low-cost fabrication of high-performance fluorinated polythiophene-based vis–NIR electrochromic devices toward deformable display and camouflage.Chem Mater2022;34:9923-33

[26]	Xie H,Wan J.Dual-band laser selective etching for stretchable and strain interference-free pressure sensor arrays.Adv Funct Mater2024;34:2401532

[27]	Yue Y,Zhao Z,Guo X.Stretchable flexible sensors for smart tires based on laser-induced graphene technology.Soft Sci2023;3:13

[28]	Agarwala S,Dinh Le TS.Wearable bandage-based strain sensor for home healthcare: combining 3D aerosol jet printing and laser sintering.ACS Sens2019;4:218-26

[29]	Shi W,Song H.High-sensitivity and extreme environment-resistant sensors based on PEDOT:PSS@PVA hydrogel fibers for physiological monitoring.ACS Appl Mater Interfaces2022;14:35114-25

[30]	Li C,He Y.Polyelectrolyte elastomer-based ionotronic sensors with multi-mode sensing capabilities via multi-material 3D printing.Nat Commun2023;14:4853 PMCID:PMC10415297

[31]	Cheng J,Sun Z.Centrifugal multimaterial 3D printing of multifunctional heterogeneous objects.Nat Commun2022;13:7931 PMCID:PMC9789974

[32]	Zeng S,Zu G.Transparent, flexible, and multifunctional starch-based double-network hydrogels as high-performance wearable electronics.Carbohydr Polym2021;267:118198

[33]	Xia S,Song S,Gao G.Bioinspired dynamic cross-linking hydrogel sensors with skin-like strain and pressure sensing behaviors.Chem Mater2019;31:9522-31

[34]	Wang Q,Ran X,Shen G.High-performance flexible self-powered strain sensor based on carbon nanotube/ZnSe/CoSe₂ nanocomposite film electrodes.Nano Res2022;15:170-8

[35]	Zhao W,Yang Y,Zhang B.A fast self-healing multifunctional polyvinyl alcohol nano-organic composite hydrogel as a building block for highly sensitive strain/pressure sensors.J Mater Chem A2021;9:22082-94

[36]	Xia X,Gao Z.Structural design and DLP 3D printing preparation of high strain stable flexible pressure sensors.Adv Sci2024;11:e2304409 PMCID:PMC11462308

[37]	Poompiew N,Aumnate C,Osswald TA.3D printable resin/carbon nanotube composites for wearable strain sensors: enhancing mechanical and electrical properties.J Sci Adv Mater Dev2023;8:100546

[38]	Han S,Xu Y.Multi-functional eutectic hydrogel for 3D printable flexible omnidirectional strain sensors.Adv Mater Technol2023;8:2301123

[39]	Guo B,Chen X,Bai J.3D printing of electrically conductive and degradable hydrogel for epidermal strain sensor.Compos Commun2023;37:101454

[40]	Zhang C,Sun J.3D printed, solid-state conductive ionoelastomer as a generic building block for tactile applications.Adv Mater2022;34:e2105996

[41]	Ertugrul I,Ersoy S.Additive manufactured strain sensor using stereolithography method with photopolymer material.Polymers2023;15:991 PMCID:PMC9965623

[42]	Sanandiya ND,Seyedin S,Thomas S.Chitosan-based electroconductive inks without chemical reaction for cost-effective and versatile 3D printing for electromagnetic interference (EMI) shielding and strain-sensing applications.Carbohydr Polym2024;337:122161

[43]	Christ JF,Ameli A.3D printed highly elastic strain sensors of multiwalled carbon nanotube/thermoplastic polyurethane nanocomposites.Mater Design2017;131:394-401

[44]	Liu Z,Hong S.Data-driven inverse design of flexible pressure sensors.Proc Natl Acad Sci U S A2024;121:e2320222121 PMCID:PMC11252744

[45]	Jiang Y,Matsuhisa N.Auxetic mechanical metamaterials to enhance sensitivity of stretchable strain sensors.Adv Mater2018;30:e1706589

[46]	Yuk H,Lin S.3D printing of conducting polymers.Nat Commun2020;11:1604 PMCID:PMC7105462

[47]	Shen Z,Zhang N.High-stretchability, ultralow-hysteresis conductingpolymer hydrogel strain sensors for soft machines.Adv Mater2022;34:e2203650

[48]	Cao J,Li K.Self-healable PEDOT:PSS-PVA nanocomposite hydrogel strain sensor for human motion monitoring.Nanomaterials2023;13:2465 PMCID:PMC10489763

[49]	Yang R,Chen X.Highly stretchable, robust, sensitive and wearable strain sensors based on mesh-structured conductive hydrogels.Chem Eng J2024;480:148228