<p>Optical tweezers offer precise, non-contact control, but operate in a limited force regime and impose strict requirements on the characteristics of the targets as well as the environmental conditions<sup><CitationRef AdditionalCitationIDS="CR2 CR3" CitationID="CR1">1</CitationRef>–<CitationRef CitationID="CR4">4</CitationRef></sup>. Millimetre-scale mechanical tweezers can offer higher gripping force but are not suitable for precise manipulations<sup><CitationRef AdditionalCitationIDS="CR6 CR7 CR8 CR9 CR10" CitationID="CR5">5</CitationRef>–<CitationRef CitationID="CR11">11</CitationRef></sup>. Integrating microgrippers directly at the optical fibres provides a new approach for precise micromanipulation. However, existing fibre-integrated tweezers still face challenges in achieving high-performance manipulation of micro-objects (for example, single cells) within narrow spaces, mainly due to simplified architectures, constrained designs and millimetre-scale footprints<sup><CitationRef AdditionalCitationIDS="CR13" CitationID="CR12">12</CitationRef>–<CitationRef CitationID="CR14">14</CitationRef></sup>. Here we report a three-dimensional (3D) optical fibre gripper (OFG), which is fabricated by two-step, two-photon polymerization. The OFG consists of rigid photoresist microclaws and soft thermoresponsive hydrogel muscle doped with silver nanoparticles, and its size is only 38 × 38 × 61 μm<sup>3</sup>. The OFG exhibits a force-to-mass ratio of about 340 μN mg<sup>−1</sup>, outperforming previously reported fibre-integrated tweezers by one to two orders of magnitude. The OFG can manipulate opaque particles, irregular micromechanical components and diverse single-cell types. We further demonstrated its potential in 3D microassembly of complex microdevices (bearings, shafts and gearboxes) and biomimetic sampling in the narrow environment (&lt;300 μm). These results position the OFG as a compact fibre-tip manipulator for 3D micromanipulation, offering reversible and tunable gripping in an intermediate force regime between optical field trapping and millimetre-scale mechanical tweezers.</p>

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Optical fibre gripper for high-performance 3D micromanipulation

  • Deng Pan,
  • Kaiwen Liang,
  • Chen Xin,
  • Lei Zhong,
  • Shaojun Jiang,
  • Chenchu Zhang,
  • Liang Yang,
  • Zhiqiang Wang,
  • Zhaoxin Lao,
  • Jincheng Ni,
  • Chaowei Wang,
  • Jiawen Li,
  • Shenglai Zhen,
  • Benli Yu,
  • Zhixiang Huang,
  • Fang-Wen Sun,
  • Jiaru Chu,
  • Yanlei Hu,
  • Li Zhang,
  • Dong Wu

摘要

Optical tweezers offer precise, non-contact control, but operate in a limited force regime and impose strict requirements on the characteristics of the targets as well as the environmental conditions14. Millimetre-scale mechanical tweezers can offer higher gripping force but are not suitable for precise manipulations511. Integrating microgrippers directly at the optical fibres provides a new approach for precise micromanipulation. However, existing fibre-integrated tweezers still face challenges in achieving high-performance manipulation of micro-objects (for example, single cells) within narrow spaces, mainly due to simplified architectures, constrained designs and millimetre-scale footprints1214. Here we report a three-dimensional (3D) optical fibre gripper (OFG), which is fabricated by two-step, two-photon polymerization. The OFG consists of rigid photoresist microclaws and soft thermoresponsive hydrogel muscle doped with silver nanoparticles, and its size is only 38 × 38 × 61 μm3. The OFG exhibits a force-to-mass ratio of about 340 μN mg−1, outperforming previously reported fibre-integrated tweezers by one to two orders of magnitude. The OFG can manipulate opaque particles, irregular micromechanical components and diverse single-cell types. We further demonstrated its potential in 3D microassembly of complex microdevices (bearings, shafts and gearboxes) and biomimetic sampling in the narrow environment (<300 μm). These results position the OFG as a compact fibre-tip manipulator for 3D micromanipulation, offering reversible and tunable gripping in an intermediate force regime between optical field trapping and millimetre-scale mechanical tweezers.