Tunable Phase-Engineered Polyhydroxybutyrate Fibrous Mat: An Energy Autonomous, Temperature-Responsive Platform for Wearable Application

Kusum Sharma , Nagamalleswara Rao Alluri , Asokan Poorani Sathya Prasanna , Muthukumar Perumalsamy , Anandhan Ayyappan Saj , Yeonkyeong Ryu , Ju-Hyuck Lee , Kwi-Il Park , Sang-Jae Kim

Advanced Fiber Materials ›› 2025, Vol. 7 ›› Issue (5) : 1446 -1461.

PDF
Advanced Fiber Materials ›› 2025, Vol. 7 ›› Issue (5) : 1446 -1461. DOI: 10.1007/s42765-025-00555-4
Research Article
research-article

Tunable Phase-Engineered Polyhydroxybutyrate Fibrous Mat: An Energy Autonomous, Temperature-Responsive Platform for Wearable Application

Author information +
History +
PDF

Abstract

Biodegradable and biocompatible organic polymers play a pivotal role in designing the next generation of wearable smart electronics, reducing electronic waste and carbon emissions while promoting a toxin-free environment. Herein, an electrospun fibrous polyhydroxybutyrate (PHB) organic mat-based, energy-autonomous, skin-adaptable temperature sensor is developed, eliminating the need for additional storage or circuit components. The electrospun PHB mat exhibits an enhanced β-crystalline phase with a β/α phase ratio of 3.96 using 1,1,1,3,3,3-hexafluoro-2-propanol as a solvent. Solvent and film processing techniques were tailored to obtain high-quality PHB films with the desired thickness, flexibility, and phase conversion. The PHB mat-based temperature sensor (PHB–TS) exhibits a negative temperature coefficient of resistance, with a sensitivity of − 2.94%/°C and a thermistor constant of 4676 K, outperforming pure metals and carbon-based sensors. A triboelectric nanogenerator (TENG) based on the enhanced β-phase PHB mat was fabricated, delivering an output of 156 V, 0.43 µA, and a power density of 1.71 mW/m2. The energy-autonomous PHB–TS was attached to the index finger to monitor temperature changes upon contact with hot and cold surfaces, demonstrating good reliability and endurance.

Keywords

Polyhydroxybutyrate / Self-powered sensor / Triboelectric nanogenerator / Thermistor / Electrospinning

Cite this article

Download citation ▾
Kusum Sharma, Nagamalleswara Rao Alluri, Asokan Poorani Sathya Prasanna, Muthukumar Perumalsamy, Anandhan Ayyappan Saj, Yeonkyeong Ryu, Ju-Hyuck Lee, Kwi-Il Park, Sang-Jae Kim. Tunable Phase-Engineered Polyhydroxybutyrate Fibrous Mat: An Energy Autonomous, Temperature-Responsive Platform for Wearable Application. Advanced Fiber Materials, 2025, 7(5): 1446-1461 DOI:10.1007/s42765-025-00555-4

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

PengX, DongK, YeC, JiangY, ZhaiS, ChengR, LiuD, GaoX, WangJ, WangZL. A breathable, biodegradable, antibacterial, and self-powered electronic skin based on all-nanofiber triboelectric nanogenerators. Sci Adv, 2020, 6eaba9624.

[2]

QinS, YangP, LiuZ, HuJ, LiN, DingL, ChenX. Triboelectric sensor with ultra-wide linear range based on water-containing elastomer and ion-rich interface. Nat Commun, 2024, 1510640.

[3]

YangP, LiuZ, QinS, HuJ, YuanS, WangZL, ChenX. A wearable triboelectric impedance tomography system for noninvasive and dynamic imaging of biological tissues. Sci Adv, 2024, 10eadr9139.

[4]

WangR, MuL, BaoY, LinH, JiT, ShiY, ZhuJ, WuW. Holistically engineered polymer-polymer and polymer-ion interactions in biocompatible polyvinyl alcohol blends for high-performance triboelectric devices in self-powered wearable cardiovascular monitorings. Adv Mater, 2020, 32: 1-10
[5]

LuY, ZhangH, ZhaoY, LiuH, NieZ, XuF, ZhuJ, HuangW. Robust fiber-shaped flexible temperature sensors for safety monitoring with ultrahigh sensitivity. Adv Mater, 2024, 362310613.

[6]

LiuL, DouY, WangJ, ZhaoY, KongW, MaC, HeD, WangH, ZhangH, ChangA, ZhaoP. Recent advances in flexible temperature sensors: materials, mechanism, fabrication, and applications. Adv Sci, 2024, 112405003.

[7]

XiaoH, LiS, HeZ, WuY, GaoZ, HuC, HuS, WangS, LiuC, ShangJ, LiaoM, MakarovD, LiuY, LiRW. Dual mode strain-temperature sensor with high stimuli discriminability and resolution for smart wearables. Adv Funct Mater, 2023, 33: 1-13.

[8]

YaoP, BaoQ, YaoY, XiaoM, XuZ, YangJ, LiuW. Environmentally stable, robust, adhesive, and conductive supramolecular deep eutectic gels as ultrasensitive flexible temperature sensor. Adv Mater, 2023, 35: 1-12.

[9]

ZhuH, LuoH, CaiM, SongJ. A multifunctional flexible tactile sensor based on resistive effect for simultaneous sensing of pressure and temperature. Adv Sci, 2024, 11: 1-10
[10]

ChaiB, ShiK, WangY, LiuY, LiuF, ZhuL, HuangX. Integrated piezoelectric/pyroelectric sensing from organic-inorganic perovskite nanocomposites. ACS Nano, 2024, 18: 25216-25225.

[11]

DankocoMD, TesfayGY, BeneventE, BendahanM. Temperature sensor realized by inkjet printing process on flexible substrate. Mater Sci Eng B, 2016, 205: 1-5.

[12]

Moser Y, Gijs MAM. Miniaturised flexible temperature sensor, TRANSDUCERS and EUROSENSORS ’07—4th international conference on solid-state sensors, actuators and microsystems, vol 16. 2007. pp. 2279–82.
[13]

ZhangH, XuK, LuY, LiuH, HanW, ZhaoY, LiR, NieZ, XuF, ZhuJ, HuangW. Robust self-gated-carriers enabling highly sensitive wearable temperature sensors. Appl Phys Rev, 2021, 8. 031416
[14]

AppiagyeiAB, BanuaJ, HanJI. Flexible and patterned-free Ni/NiO-based temperature device on cylindrical PET fabricated by RF magnetron sputtering: bending and washing endurance tests. J Ind Eng Chem, 2021, 100: 372-382.

[15]

Maria-Joseph-RajNP, AlluriNR, ChandrasekharA, KhandelwalG, KimSJ. Self-powered ferroelectric NTC thermistor based on bismuth titanate. Nano Energy, 2019, 62: 329-337.

[16]

ChenZ, ZhaoD, MaR, ZhangX, RaoJ, YinY, WangX, YiF. Flexible temperature sensors based on carbon nanomaterials. J Mater Chem B, 2021, 9: 1941-1964.

[17]

HongSY, LeeYH, ParkH, JinSW, JeongYR, YunJ, YouI, ZiG, HaJS. Stretchable active matrix temperature sensor array of polyaniline nanofibers for electronic skin. Adv Mater, 2016, 28: 930-935.

[18]

LiF, XueH, LinX, ZhaoH, ZhangT. Wearable temperature sensor with high resolution for skin temperature monitoring. ACS Appl Mater Interfaces, 2022, 14: 43844-43852.

[19]

ZargarianSS, ZakrzewskaA, Kosik-KoziołA, BartolewskaM, ShahSA, LiX, SuQ, PetronellaF, MarinelliM, De SioL, LanziM, DingB, PieriniF. Advancing resource sustainability with green photothermal materials: insights from organic waste-derived and bioderived sources. Nanotechnol Rev, 2024, 1320240100.

[20]

BartolewskaM, Kosik-KoziołA, KorwekZ, KrysiakZ, MontroniD, MazurM, FaliniG, PieriniF. Eumelanin-enhanced photothermal disinfection of contact lenses using a sustainable marine nanoplatform engineered with electrospun nanofibers. Adv Healthc Mater, 2025, 142402431.

[21]

AnbukarasuP, SauvageauD, EliasA. Tuning the properties of polyhydroxybutyrate films using acetic acid via solvent casting. Sci Rep, 2015, 5: 1-14.

[22]

GongL, ChaseDB, NodaI, LiuJ, MartinDC, NiC, RaboltJF. Discovery of β-form crystal structure in electrospun poly[(R)-3-hydroxybutyrate-co-(R)-3-hydroxyhexanoate] (PHBHx) nanofibers: from fiber mats to single fibers. Macromolecules, 2015, 48: 6197-6205.

[23]

PhongtamrugS, TashiroK. X-ray crystal structure analysis of poly(3-hydroxybutyrate) β-form and the proposition of a mechanism of the stress-induced α-to-β phase transition. Macromolecules, 2019, 52: 2995-3009.

[24]

P. Conjugates, of poly(3-hydroxyalkanoate) (PHA) conjugates: PHA-carbohydrate and. 1991;5:6046–9.
[25]

BrunettiL, Degli EspostiM, MorselliD, BoccacciniAR, FabbriP, LiveraniL. Poly(hydroxyalkanoate)s meet benign solvents for electrospinning. Mater Lett, 2020, 278128389.

[26]

DaiX, LiH, RenZ, RussellTP, YanS, SunX. Confinement effects on the crystallization of poly(3-hydroxybutyrate). Macromolecules, 2018, 51: 5732-5741.

[27]

BudurovaD, UblekovF, PenchevH. The use of formic acid as a common solvent for electrospinning of hybrid PHB/Soy protein fibers. Mater Lett, 2021, 301. 130313
[28]

SharmaK, KimS-J. Wearable electret based metal oxide nanostructure for self-powered respiration monitoring. Sustain Mater Technol, 2023, 38e00734
[29]

KabeT, TanakaT, MarubayashiH, HikimaT, TakataM, IwataT. Investigating thermal properties of and melting-induced structural changes in cold-drawn P(3HB) films with α- and β-structures using real-time X-ray measurements and high-speed DSC. Polymer (Guildf), 2016, 93: 181-188.

[30]

DanL, EliasAL. Flexible and stretchable temperature sensors fabricated using solution-processable conductive polymer composites. Adv Healthc Mater, 2020, 92000380.

[31]

LeeCY, WuGW, HsiehWJ. Fabrication of micro sensors on a flexible substrate. Sens Actuators A Phys, 2008, 147: 173-176.

[32]

CuiZ, PobleteFR, ZhuY. Tailoring the temperature coefficient of resistance of silver nanowire nanocomposites and their application as stretchable temperature sensors. ACS Appl Mater Interfaces, 2019, 11: 17836-17842.

[33]

LeeJH, ChenH, KimE, ZhangH, WuK, ZhangH, ShenX, ZhengQ, YangJ, JeonS, KimJK. Flexible temperature sensors made of aligned electrospun carbon nanofiber films with outstanding sensitivity and selectivity towards temperature. Mater Horiz, 2021, 8: 1488-1498.

[34]

SehrawatP, AbidS, IslamSS, MishraP. Reduced graphene oxide based temperature sensor: extraordinary performance governed by lattice dynamics assisted carrier transport. Sens Actuators B Chem, 2018, 258: 424-435.

[35]

TrungTQ, LeHS, DangTML, JuS, ParkSY, LeeNE. Freestanding, fiber-based, wearable temperature sensor with tunable thermal index for healthcare monitoring. Adv Healthc Mater, 2018, 7: 1-9.

[36]

DanL, EliasAL. Flexible and stretchable temperature sensors fabricated using solution-processable conductive polymer composites. Adv Healthc Mater, 2020, 9: 1-13.

[37]

HondaW, HaradaS, ArieT, AkitaS, TakeiK. Wearable, human-interactive, health-monitoring, wireless devices fabricated by macroscale printing techniques. Adv Funct Mater, 2014, 24: 3299-3304.

[38]

SoniM, BhattacharjeeM, NtagiosM, DahiyaR. Printed temperature sensor based on PEDOT: PSS-graphene oxide composite. IEEE Sens J, 2020, 20: 7525-7531.

[39]

LuY, ZhangH, ZhaoY, LiuH, NieZ, XuF, ZhuJ, HuangW. Robust fiber-shaped flexible temperature sensors for safety monitoring with ultrahigh sensitivity. Adv Mater, 2024, 36: 1-12.

[40]

Zhang H, Xu K, Lu Y, Liu H, Han W, Zhao Y, Li R, Nie Z, Xu F, Zhu J, Huang W. Robust self-gated-carriers enabling highly sensitive wearable temperature sensors. Appl Phys Rev. 2021;8.
[41]

LebedevV, LaukhinaE, LaukhinV, SomovA, BaranovAM, RoviraC, VecianaJ. Investigation of sensing capabilities of organic bi-layer thermistor in wearable e-textile and wireless sensing devices. Org Electron, 2017, 42: 146-152.

[42]

HuangJ, XuZ, QiuW, ChenF, MengZ, HouC, GuoW, LiuXY. Stretchable and heat-resistant protein-based electronic skin for human thermoregulation. Adv Funct Mater, 2020, 30: 1-9

Funding

National Research Foundation of Korea (NRF)(2023R1A2C3004336)

RIGHTS & PERMISSIONS

Donghua University, Shanghai, China

AI Summary AI Mindmap
PDF

173

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/