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Laser & Optoelectronics Progress, Volume. 62, Issue 2, 0200002(2025)

Advances in Optical Coherence Elastography and Its Applications

Yirui Zhu1、*, Jiulin Shi1, Lingkai Huang1, Lihua Fang1, Tomas E. Gomez Alvarez-Arenas2, and Xingdao He1
Author Affiliations
  • 1Key Laboratory for Optoelectronic Information Perception and Instrumentation of Jiangxi Province, Nanchang Hangkong University, Nanchang 330063, Jiangxi , China
  • 2Information and Physical Technologies Institute, Spanish National Research Council, Madrid 28006, Spain
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    AbstractGet PDF(in Chinese)
    Figures&Tables (23)
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    References (209)
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    Figures & Tables(23)
    Three main steps of the classical OCE technique[45]

    Fig. 1. Three main steps of the classical OCE technique[45]

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    Elastography of human breast cancer tissues obtained from elastography across different spatial scales[68-71]

    Fig. 2. Elastography of human breast cancer tissues obtained from elastography across different spatial scales[68-71]

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    Different excitation methods for OCE technology[72]

    Fig. 3. Different excitation methods for OCE technology[72]

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    OCT-based OCE system setup. (a) SD-OCE system; (b) SS-OCE system

    Fig. 4. OCT-based OCE system setup. (a) SD-OCE system; (b) SS-OCE system

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    M-scan mode with temporal repetitive scanning at a particular transverse position x0 to obtain vibration information at that position over time

    Fig. 5. M-scan mode with temporal repetitive scanning at a particular transverse position x0 to obtain vibration information at that position over time

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    M-B scanning mode. (a) M-B scanning optical path setup with the OCT probe beam completing the B-scan in the x-z plane; (b) M-B scanning timing control program; (c) 3D dataset acquired in the M-B scanning mode (x, z, t)

    Fig. 6. M-B scanning mode. (a) M-B scanning optical path setup with the OCT probe beam completing the B-scan in the x-z plane; (b) M-B scanning timing control program; (c) 3D dataset acquired in the M-B scanning mode (x, z, t)

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    Tissue model in the 3D Cartesian coordinate system (x,y,z)

    Fig. 7. Tissue model in the 3D Cartesian coordinate system (x,y,z)

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    Types of mechanical waves in biological tissues

    Fig. 8. Types of mechanical waves in biological tissues

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    Imaging results of LSW with AC-ARF non-contact excitation in the agar model[63]. (a) M-scan mode results of LSW, while white arrows indicate the different detection moments; (b) vibrational displacement curves of LSW along the depth direction at different detection moments

    Fig. 9. Imaging results of LSW with AC-ARF non-contact excitation in the agar model[63]. (a) M-scan mode results of LSW, while white arrows indicate the different detection moments; (b) vibrational displacement curves of LSW along the depth direction at different detection moments

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    OCE results for SAW and SRW in agar[127]. (a) 2D vibrational displacement propagation images of SAW and SRW within agar at different moments, with yellow arrows at the top of the image indicating excitation points; (b) 3D surfaces (x, z, t) reconstructed for SAW and SRW, with white arrows indicating SAW wavefronts and black arrows indicating SRW wavefronts; (c) 2D OCT images of the agar; (d) the displacement profiles of SRW and SAW at 2.7 ms at the depths shown by the blue line in Fig. 10 (a); (e) the spatiotemporal displacement of SRW and SAW at the depths shown by the blue line in Fig. 10(a)

    Fig. 10. OCE results for SAW and SRW in agar[127]. (a) 2D vibrational displacement propagation images of SAW and SRW within agar at different moments, with yellow arrows at the top of the image indicating excitation points; (b) 3D surfaces (x, z, t) reconstructed for SAW and SRW, with white arrows indicating SAW wavefronts and black arrows indicating SRW wavefronts; (c) 2D OCT images of the agar; (d) the displacement profiles of SRW and SAW at 2.7 ms at the depths shown by the blue line in Fig. 10 (a); (e) the spatiotemporal displacement of SRW and SAW at the depths shown by the blue line in Fig. 10(a)

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    Lamb wave propagation modes in thin plates. (a) Symmetric mode; (b) antisymmetric mode

    Fig. 11. Lamb wave propagation modes in thin plates. (a) Symmetric mode; (b) antisymmetric mode

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    Application areas of optical coherent elastography

    Fig. 12. Application areas of optical coherent elastography

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    OCE results after corneal-3D refractive surgery[136]. (a) 2D structural image of the cornea, with red arrows indicating the boundary between the corneal cap and residual stromal bed; (b) corneal depth resolved elastography results, with red arrows indicating the boundary between the Young's modulus of the corneal cap and residual stromal bed after surgery

    Fig. 13. OCE results after corneal-3D refractive surgery[136]. (a) 2D structural image of the cornea, with red arrows indicating the boundary between the corneal cap and residual stromal bed; (b) corneal depth resolved elastography results, with red arrows indicating the boundary between the Young's modulus of the corneal cap and residual stromal bed after surgery

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    Results of OCE experiments after keratoconus cross-linking surgery[78]. (a) 2D structural image of the keratoconus after 15J-CXL treatment; (b) propagation process of the vibrational displacements at different times after the 15J-CXL treatment; (c) 2D structural image of the keratoconus in vivo after 30J-CXL treatment; (d) propagation process of the vibrational displacements at different times after the 30J-CXL treatment; (e) 15J-CXL depth-resolved image of the internal phase velocity of the keratoconus after treatment; (f) depth-resolved image of the internal phase velocity of the conical cornea after 30J-CXL treatment; (g) comparison of the average velocity values

    Fig. 14. Results of OCE experiments after keratoconus cross-linking surgery[78]. (a) 2D structural image of the keratoconus after 15J-CXL treatment; (b) propagation process of the vibrational displacements at different times after the 15J-CXL treatment; (c) 2D structural image of the keratoconus in vivo after 30J-CXL treatment; (d) propagation process of the vibrational displacements at different times after the 30J-CXL treatment; (e) 15J-CXL depth-resolved image of the internal phase velocity of the keratoconus after treatment; (f) depth-resolved image of the internal phase velocity of the conical cornea after 30J-CXL treatment; (g) comparison of the average velocity values

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    Mechanical stiffness of breast cancer tissue based on QEM. (a) Histopathological section of breast cancer; (b) enface diagram of OCT; (c) mechanical stiffness results of breast cancer tissue obtained by QEM technology to the OCT structure diagram

    Fig. 15. Mechanical stiffness of breast cancer tissue based on QEM. (a) Histopathological section of breast cancer; (b) enface diagram of OCT; (c) mechanical stiffness results of breast cancer tissue obtained by QEM technology to the OCT structure diagram

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    OCE experimental results of non-contact LSW in isolated porcine brain tissue. (a) In vitro pig brain tissue experimental samples; (b) two-dimensional OCT structural images of cerebral vascular regions; (c) three-dimensional OCT structural images of cerebral vascular regions; (d) M-scan mode image of the LSW propagation process in the left cerebral vascular region; (e) vibration displacement curves of LSW at different times; (f) M-scan mode image of the LSW propagation process in the right cerebral vascular region; (g) vibration displacement curves of LSW at different times

    Fig. 16. OCE experimental results of non-contact LSW in isolated porcine brain tissue. (a) In vitro pig brain tissue experimental samples; (b) two-dimensional OCT structural images of cerebral vascular regions; (c) three-dimensional OCT structural images of cerebral vascular regions; (d) M-scan mode image of the LSW propagation process in the left cerebral vascular region; (e) vibration displacement curves of LSW at different times; (f) M-scan mode image of the LSW propagation process in the right cerebral vascular region; (g) vibration displacement curves of LSW at different times

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    Results of OCE experiments based on SRW and SAW models for isolated porcine brain tissue. (a) The three regions of isolated porcine brain tissue selected in the experiments; (b) the propagation process of SRW and SAW at different moments in the FL region; (c) the results of the 3D reconstruction of the wave front surface of the propagation process at different moments of SRW and SAW; (d) the spatio-temporal displacement map of SRW and SAW

    Fig. 17. Results of OCE experiments based on SRW and SAW models for isolated porcine brain tissue. (a) The three regions of isolated porcine brain tissue selected in the experiments; (b) the propagation process of SRW and SAW at different moments in the FL region; (c) the results of the 3D reconstruction of the wave front surface of the propagation process at different moments of SRW and SAW; (d) the spatio-temporal displacement map of SRW and SAW

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    Characterization of the scar tissue in vivo with four different OCT modalities[196]. (a) Photograph of the scar area in a 28-year-old male volunteer; (b) its enlarged area with the direction of the mechanical wave propagation in the scar and adjacent skin site; (c) group velocity of the Rayleigh wave in the scar and in the normal skin tissue in two orthogonal directions; (d)‒(e) Structural OCT and OCT angiography images; (f) optic axis orientation map obtained with the PS-OCT system; (g) image of Rayleigh wave group velocity measured in the direction perpendicular to the scar within the area covered by a white dashed rectangle

    Fig. 18. Characterization of the scar tissue in vivo with four different OCT modalities[196]. (a) Photograph of the scar area in a 28-year-old male volunteer; (b) its enlarged area with the direction of the mechanical wave propagation in the scar and adjacent skin site; (c) group velocity of the Rayleigh wave in the scar and in the normal skin tissue in two orthogonal directions; (d)‒(e) Structural OCT and OCT angiography images; (f) optic axis orientation map obtained with the PS-OCT system; (g) image of Rayleigh wave group velocity measured in the direction perpendicular to the scar within the area covered by a white dashed rectangle

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    • Table 1. Comparison of different elastography technical parameters

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      Table 1. Comparison of different elastography technical parameters

      ModePalpationUSEMRELSEPAECBMOCE
      MethodTouchSound waveMagnetic waveLaserUltrasonicsLaserLaser
      Spatial resolutionSubjective~500 µm~500 µm~µm~50 µm~3 µm~10 µm
      Imaging depthSubjectivecmcm~1 mmcm~100 µm~ mm
      Proposed time~1991~1995~2012~2011~2008~1998
      Non-destructive, noninvasiveYesYesYesYesYesYesYes

    • Table 2. Elastic modulus results of the corneal tissue obtained from different OCE experiments

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      Table 2. Elastic modulus results of the corneal tissue obtained from different OCE experiments

      SampleConditionMethodShear modulus /PaYoung’s modulus /Pa
      In vivo rabbit corneaNormalARF-OCE27.4×103‒88.7×103136142
      cold cataract lens30.4×103[142
      NormalAir pulse-OCE93.7×103‒131.1×103[148
      Corneal collagen cross-linking (CXL)142.9×103‒203.2×103[148
      NormalSpace-coupled ultrasound OCE246.4×103[149
      Corneal collagen cross-linking (CXL)1.627×106[149
      Ex vivo rabbit corneaCorneal flap after FLExARF-OCE(71.7±24.6)×103[133
      Residual stromal bed after the FLEx surgery(305.8±48.5)×103[133
      Corneal cap after SMILE surgery(219.5±54.9)×103[133
      Residual stromal bed after SMILE surgery(221.5±43.2)×103[133
      Normal(91.7±28.1)×103[133
      Normal44.9×103‒58.5×103[150
      NormalARF-OCE53.1×103[151
      Space-coupled ultrasound OCE34×103‒261×103[15220×106‒44×106[152
      SS-OCE35×103‒80×103[153
      Ex vivo porcine corneaNormalARF-OCE12.45×103‒32.35×103[154-155
      Air pulse- OCE(5.70±2.26)×103[156(17.0±7.93)×103[156
      LF-OCE(198.25±5.97)×103[157
      Mechanical probe OCE20.5×103[102
      Ex vivohuman corneaKeratoconusARF-OCE49.1×103‒60.3×103[150
      Scarring corneaARF-OCE219.2×103‒294.9×103[151
      In vivohuman corneaNormalUltrasound elastography(696±113)×103[158
      Corneal indentation(755±159)×103[159
      Central corneaAir pulse- OCE(692±64)×103[139
      Limb(852±82)×103[139
      Normal(733 ± 164)×103[139
      Age(25‒67)Mechanical probe OCE(72±14)×103[137

    • Table 3. Elastic modulus results of the crystalline lens obtained from different OCE experiments

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      Table 3. Elastic modulus results of the crystalline lens obtained from different OCE experiments

      SampleConditionMethodShear modulus /PaYoung’s modulus/Pa
      Ex vivo rabbit eye lensNormal (juvenile)ARF-OCE(7.74±1.56)×103[160
      Normal (mature)(15.15±4.52)×103[160
      Ex vivo porcine eye lensNormalAir pulse-OCE2.7×103‒3.8×103[161
      NormalAir pulse-OCE(8.8±1.5)×103[162
      Oxidative cataract (added hydrogen peroxide)(123.6±20.8)×103[162
      Oxidative cataract with α-lipoic acid added(45.1±24.1)×103[162
      NormalAir pulse-OCE(11.3±3.4)×103[163
      Cold cataracts(21.8±7.8)×103[163
      Anterior part of the lensBrillouin Microscopy and OCE(1.98±0.74)×103[164
      The posterior part of the lens(2.93±1.13)×103[164
      Nucleus of the lens(11.90±2.94)×103[164

    • Table 4. Elastic modulus results of sclera tissue obtained from different OCE experiments

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      Table 4. Elastic modulus results of sclera tissue obtained from different OCE experiments

      SampleConditionMethodShear modulus /MPaYoung’s modulus /Pa
      In vivo rabbit eye scleraNormalARF-OCE
      Ex vivo rabbit eye scleraMechanical probe OCE248×103[165
      Ex vivo porcine eye sclerascleraMechanical vibration OCE0.56‒0.67166
      Limbal scleraARF-OCE48.43×103‒489.92×103[167
      Perioptic disc sclera29.87×103‒175.16×103[167
      NormalPZT probe OCE0.71±0.12168
      UV-riboflavin is crosslinking1.50±0.39168
      The sclera of the human eyeNormalMechanical probe OCE0.31±0.15137

    • Table 5. Elastic modulus results of retinal tissue obtained from different OCE experiments

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      Table 5. Elastic modulus results of retinal tissue obtained from different OCE experiments

      SampleConditionMethodShear modulus /PaYoung’s modulus /Pa
      In vivo rabbit eye retinaNormalARF-OCE3.09×103‒140×103[143169
      Mechanical probe OCE50.4×103‒134.6×103[165
      Ex vivo porcine retina of the eyeARF-OCE141.21×103±5.24×103[155
      ARF-OCE6.2×103[170
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    Yirui Zhu, Jiulin Shi, Lingkai Huang, Lihua Fang, Tomas E. Gomez Alvarez-Arenas, Xingdao He. Advances in Optical Coherence Elastography and Its Applications[J]. Laser & Optoelectronics Progress, 2025, 62(2): 0200002

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    Paper Information

    Category: Reviews

    Received: Jul. 2, 2024

    Accepted: Aug. 30, 2024

    Published Online: Jan. 3, 2025

    The Author Email:

    DOI:10.3788/LOP241618

    CSTR:32186.14.LOP241618

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology