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Prof. A.Gh Podoleanu

Head of Applied Optics Group

Professor of Biomedical Optics

Ingram Building Rm.301
Telephone: 01227 823272
Fax: 01227 827558

 

Expertise

Low coherence interferometry (LCI), low coherence reflectometry, optical coherence tomography (OCT) or partial coherence reflectometry all refer to the same basic set-up, an interferometer under low coherence illumination. A variety of LCI systems have been researched and applied to different fields, in measuring electric or magnetic field, pressure, acceleration, flows, etc. One of the most exciting application of LCI is OCT for imaging tissue. This has revolutionised the imaging technology of superficial tissue, images from retina with less than 5 microns have been recently reported.

Low-Coherence Interferometry is a powerful tool to "section" a transparent object. The technique is currently evolving quickly with applications in medicine in general and ophthalmology in particular. The OCT technology is non-invasive and provides high depth resolution, therefore the technology was applied to different types of tissue, skin, hair, burns, etc. Visualisation of cells, microorganisms, hair, brain and the interior of arteries have been reported with depth and transversal resolution of 5-15 microns. OCT has also been used to image integrated circuits, characterise fibre Bragg gratings and optical waveguides and in surface analysis. In combination with confocal microscopy, OCT can in principle offer 1 micron resolution along all three axes. The OCT field requires an interdisciplinary approach.

The AOG in Kent is at the forefront of OCT system development. The group has pioneered the en-face OCT technology, the first dual channel confocal-OCT instrument for the eye, multi-interferometer configuration to collect simultaneously images from different depths and produced 3D OCT visualisation in real time.



OCT technology
 

OCT derives from low-coherence interferometry. This is an absolute measurement technique which was developed for high- resolution ranging and characterisation of optoelectronics components.
[Al-Chalabi SA, Culshaw B, Davies DEN. Partially coherent sources in interferometric sensors. First Internat. Conf. Optical Fibre Sensors 26-28 April 1983, I.E.E. London, 132-135.Youngquist RC, Carr S, Davies DEN. Optical coherence-domain  reflectometry: A new optical evaluation technique. Opt Lett 1987;12(3):158-160.]

The first application of low-coherence interferometry in the biomedical optics field was for the measurement of eye length.
 [Fercher AF, Mengedoht K, Werner W. Eye length measurement by interferometry with partially coherent light. Opt Lett 1988;13(3):186-189.]b

Adding lateral scanning to a low-coherence interferometer, allows depth resolved acquisition of 3D information from the volume of biologic material.
[Huang D, Swanson EA, Lin CP, Schuman JS, et al. Optical coherence tomography, Science 1991 254:1178-1181.]

The concept was initially employed in heterodyne scanning microscopy.
[Sawatari T. Optical heterodyne scanning microscope Appl Optics. 1973;12(11): 2766 – 2772.]

 OCT has the potential of achieving high-depth resolution, which is determined by the coherence length of the source.
[Mandel L, Wolf E. Optical coherence and quantum optics, Cambridge University Press, 1995 (148-150)].
 


Early OCT in the AOG
 

During research on sensing between 1986-1995, the Applied Optics Group (AOG) has contributed towards several avenues which paved the way towards the later development of what is known today as OCT. AOG was involved in all three types of OCT; (i) Time domain OCT (essential a Michelson interferometer), (ii) Spectral or Fourier domain OCT, where the interferometer output is sent to an optical spectrometer and (iii) the Swept source OCT, where a laser source is used which is swept within an equivalent band to that of the broadband source used in the time domain OCT or Fourier domain OCT. 
 
A. Gh. Podoleanu S. Taplin
D. J. Webb
D. A. Jackson 		Theoretical Study of Talbot-like Bands Observed Using a Laser Diode Below Threshold J.    Pure and Applied Optics, Vol. 7, (1998), pp. 517-536.
http://stacks.iop.org/PAO/7/517
A. Gh. Podoleanu S. Taplin
D. J. Webb
D. A. Jackson
  		Talbot-like Bands for Laser Diode Below Threshold J. Pure and Applied Optics, vol. 6, issue 3, pp. 413 - 424, (1997).
http://stacks.iop.org/PAO/6/413
 
A. Gh. Podoleanu
S. Taplin
D. J. Webb
D. A. Jackson 		Channeled Spectrum Display using a CCD Array for
Student Laboratory Demonstrations 		European J. Phys., 15, pp. 266-271, (1994).
http://stacks.iop.org/EJP/15/266
 
 
A. Gh. Podoleanu S. Taplin,
D. J. Webb,
D. A. Jackson 		Channelled Spectrum Liquid Refractometer Rev. Sci. Instr., vol. 64, No.10,  pp. 3028-9, (1993).
 
 
S. Taplin,
A. Gh. Podoleanu
D. J. Webb,
 D. A. Jackson 		Displacement Sensor Using  Channeled Spectrum Dispersed on a
Linear CCD Array 		Electron. Lett.
29, No.10, (1993),  pp. 896-897.


En-face flying spot OCT

We have shown that there is no need for an external phase modulator if the object to be imaged is scattering and the image size is sufficiently large. The modulation is interestingly, created by scanning the beam over the target.

First, we have shown that a Newton ring pattern is sampled from the target

A. Gh.Podoleanu
G. M. Dobre
D. J. Webb
D. A. Jackson 		Coherence Imaging by Use of a Newton Rings Sampling Function,
Republished in “Selected Papers on Optical Low-Coherence Reflectometry & Tomography”, B. R. Masters and B. J. Thompson eds., SPIE Milestone Series, vol. MS165, SPIE Optical Engineering Press, Washington, 2000, USA, pp. 200-202. 		Opt. Lett., Vol. 21, pp. 1789-1791, (1996).
http://www.opticsinfobase.org/abstract.cfm?id=45207

 


Then we moved the centre of the Newton rings out from the image centre and sampled the target with a grid of line

A. Gh.Podoleanu
G. M. Dobre
D. A. Jackson 		En-face Coherence Imaging Using Galvanometer Scanner Modulation Opt. Letters, (1998), vol. 23, pp.
147-149.
http://www.opticsinfobase.org/abstract.cfm?id=36537

This report demonstrates for the first time, B-scan OCT images from the retina constructed from T-scans (en-face 1D OCT scans)

A. Gh.Podoleanu
M. Seeger,
G. M. Dobre
D. J. Webb
D. A. Jackson,
F. Fitzke 		Transversal and Longitudinal Images from the Retina of the Living Eye Using Low Coherence Reflectometry,
Republished in “Selected Papers on Optical Low-Coherence Reflectometry & Tomography”, B. R. Masters and B. J. Thompson eds., SPIE Milestone Series, vol. MS165, SPIE Optical Engineering Press, Washington, 2000, USA, pp. 461-469. 		Journal of Biomedical Optics, 3, (1), (1998),
pp. 12-20.
http://www.spie.org/web/journals/jbo/jbo_jan98.html


The OCT/SLO
 (collaboration with Ophthalmic Technologies Inc.)
 

The research on flying spot en-face OCT has shown us how to produce OCT images with the same orientation as that in microscopy, or in scanning laser ophthalmoscopy (SLO). This allowed us to devise and assemble a dual imaging system. The system outputs pairs of OCT and confocal images. Several ophthalmoogy groups are now using the OCT/SLO in imaging the eye.

A. Gh. Podoleanu D. A. Jackson Combined Optical Coherence Tomograph and Scanning Laser Ophthalmoscope Electron. Lett., Vol. 34, No. 11, (1998) pp. 1088-1090.

Recognisable patterns in the OCT C-scans could be associated to several diseases for easier diagnostic

Collaboration with New York Eye and Ear Infirmary and the Department of Ophthalmology
     Academic Medical Center, University of Amsterdam
M. E. J. Van Velthoven, F. D.Verbraak, L. A. Yannuzzi, R. B. Rosen, A. Gh. Podoleanu, Marc D. De Smet, Imaging the Retina by En-Face Optical Coherence Tomography, RETINA, 26:129–136, 2006. RETINA-THE JOURNAL OF RETINAL AND VITREOUS DISEASES, Issues/Year: 6.

 First OCT/ICG instrument for the eye, collaboration with New York Eye and Ear Infirmary
 

G. M. Dobre
A. Gh. Podoleanu
R. B. Rosen 		Simultaneous optical coherence tomography–Indocyanine
Green dye fluorescence imaging
system for investigations of the eye’s fundus 		Optics Letters, Vol. 30, No. 1 / January 1, 2005, 58-60.
 


Ultra high resolution OCT/SLO system, collaboration with New York Eye and Ear Infirmary
 

R. G. Cucu
A.Gh. Podoleanu
J. A. Rogers
J. Pedro
R. B. Rosen 		Combined confocal scanning ophthalmoscopy/en face T-scan based ultrahigh resolution OCT of the human retina in vivo
  		Optics Letters, Vol. 31, No. 11, June 1, 2006, 1684-1687.
http://www.opticsinfobase.org/abstract.cfm?id=89811


First OCT/SLO with AO correction, collaboration with National University of Ireland, Galway
 

R. G. Cucu
A.Gh. Podoleanu
J. A. Rogers
J. Pedro
R. B. Rosen 		Combined confocal scanning ophthalmoscopy/en face T-scan based ultrahigh resolution OCT of the human retina in vivo
  		Optics Letters, Vol. 31, No. 11, June 1, 2006, 1684-1687.
http://www.opticsinfobase.org/abstract.cfm?id=89811


Sequential OCT/confocal
Sequential instead of simultaneous allows all signal to be used in each channel, OCT or confocal (SLO).
(collaboration with New York Eye and Ear Infirmary) 

A.Gh.Podoleanu
G. M.Dobre
R. G. Cucu
R. Rosen 		Sequential OCT and Confocal Imaging Opt. Letters, 29 (4): 364-366 Feb. 15 2004
http://www.opticsinfobase.org/abstract.cfm?id=78717


Modulators and scanning methods for OCT
Using two RF modulators, we demonstrated simultaneous acquisition of two C-scans at two different depths

 

A. Gh.Podoleanu
G. M. Dobre
D. J. Webb
D. A. Jackson 		Simultaneous En-face Imaging of Two Layers in Human Retina Opt. Lett., Vol. 22, No. 13,
 pp. 1039-1041, (1997)
http://www.opticsinfobase.org/abstract.cfm?id=36206


Using a Mach Zehnder integrated modulator with independent RF excitation in each arm, we demonstrated simultaneous acquisition of two C-scans at two different depths, collaboration with University of Besancon

 

A.Gh. Podoleanu J. A. Rogers,
R. C. Cucu
D. A. Jackson
B Wacogne
H. Porte
T. Gharbi 		Simultaneous Low Coherence Interferometry Imaging at Two Depths Using an Integrated Optic Modulator Optics Communications, 191
(1-2): 21-30, May, 1, 2001.


Novel scanning delay line for fast A-scan but with less loss
 

C. C. Rosa
J. Rogers
A.Gh. Podoleanu 		Fast Scanning Transmissive Delay Line Optical Coherence Tomography
  		Opt. Lett. 30, 3263-3265 (2005)
http://www.opticsinfobase.org/
abstract.cfm?URI=ol-30-24-3263


Using two coupled interferometers we devised a novel method for measuring the eye length
 


 		 A. Gh.Podoleanu,
G. M. Dobre
D. J. Webb
D. A. Jackson 		Fiberised Set-up for Eye Length Measurement Full length article in Optics Commun., 137, pp. 397-405, (1997)


Signal to noise ratio analysis
Comparative noise analysis in the two channels of an OCT/SLO system
 


 		 A. Gh.Podoleanu
D. A. Jackson 		Noise Analysis of a Combined Optical Coherence Tomograph and a Confocal Scanning Ophthalmoscope
Republished in “Selected Papers on Optical Low-Coherence Reflectometry & Tomography”, B. R. Masters and B. J. Thompson eds., SPIE Milestone Series, vol. MS165, SPIE Optical Engineering Press, Washington, 2000, USA, pp. 511-526. 		Appl. Optics, Vol. 38, (1999), No. 10, pp. 2116 -   2127.
http://www.opticsinfobase.org/abstract.cfm?id=44269


This reports shows that fast OCT system have to work in excess photon noise regime limitation and not in shot noise regime
 

A.Gh.Podoleanu Unbalanced versus balanced operation in an OCT system Appl. Opt., 2000, Vol. 39, No. 1, pp. 173-182.
http://www.opticsinfobase.org/abstract.cfm?id=914


Two novel noise bandwidth definitions are introduced to consider the excess photon noise in balanced OCT under wide bandwidth excitation
 

C. C. Rosa,
A. Podoleanu 		Limitation of the achievable signal to noise ratio in OCT due to mismatch of the balanced receiver Applied Optics, 43 (25): 4802-4815, 2004
http://www.opticsinfobase.org/abstract.cfm?id=80957
 


Corrections of distortions in OCT images
We make distinction between scanning and refractive type distortions in OCT. This report also predicts a distorted elevation of the RPE layer in the fovea in the OCT images of the retina, due to differences in the indeces of refraction of vitreous and retina
(collaboration with University of Central Florida, School of Optics / CREOL and New York Eye and Ear Infirmary)
 

A. Podoleanu
I. Charalambous
L. Plesea,
A. Dogariu
R. Rosen 		Correction of distortions in OCT imaging of the eye Physics in Medicine and Biology, 49,
2004, 1277-1294.
http://www.iop.org/EJ/abstract/0031-9155/49/7/015/
 
http://stacks.iop.org/PMB/49/1277


OCT in ophthalmology
Posterior pole
The majority of reports above referred to examples in imaging the retina.
A novel method for topography using en-face OCT was presented in the following report
(collaboration with Institute of Ophthalmology, London)
 

J. A. Rogers
A.Gh. Podoleanu
G. M. Dobre
D. A. Jackson
F. W. Fitzke 		Topography and volume measurements of the optic nerve
using en-face optical coherence tomography 		Opt. Express, Vol. 9, No. 10, Nov. 5, 2001,
pp. 476 – 545
http://www.opticsexpress.org/oearchive/source/34986.htm
 

The utility of adjustable depth resolution required by en-face OCT method is presented in:
 

A.Gh.Podoleanu
J. A. Rogers
D. A. Jackson 		OCT En-face Images from the Retina with Adjustable Depth Resolution in Real Time

 		 IEEE Journal of Selected Topics in Quantum Electron.,
1999, Vol.5, No.4, 1176-1184.
http://ieeexplore.ieee.org/search/wrapper.jsp?
arnumber=796344
or
http://ieeexplore.ieee.org/iel5/2944/17287/00796344.pdf?tp=
&arnumber=796344&isnumber=17287
=&arnumber=796344&isnumber=17287


Anterior pole
 

A. Gh. Podoleanu
J. A. Rogers
G. M. Dobre,
R. G. Cucu,
D. A. Jackson 		En-face OCT imaging of the anterior chamber Coherence Domain Optical Methods in Biomedical Science and Clinical Applications V, SPIE Proc. Vol. 4619, V. V. Tuchin, J. A. Izatt, J. G. Fujimoto eds, Photonics West, SPIE Conf.  BIOS2002, Jan. 21-23 Jan., 2002, pp. 240-243.


OCT in imaging skin
3D images are constructed from en-face OCT
 

A.Gh.Podoleanu
J. A. Rogers
D. A. Jackson
S. Dunne 		Three dimensional OCT images from retina and skin Opt. Express, Vol. 7,  No. 9,
p. 292-298, (2000), http://www.opticsexpress.org/abstract.cfm?URI=OPEX-7-9-292


OCT in dentistry
(collaboration with School of Dentistry, University of Liverpool)

B. T. Amaechi
S.M.Higham
A.Gh. Podoleanu
J. A. Rogers
D. A. Jackson 		Use of optical coherence tomography for assessment of dental carries: quantitative procedure Journal of Oral Rehabilitation, 2001, 28, pp. 1092-1093
B. T. Amaechi,
A. Gh. Podoleanu
S.M. Higham
D. Jackson 		Correlation of Quantitative Light-induced Fluorescence and Optical Coherence Tomography
Applied for Detection and Quantification of Early Dental Caries 		Journal Biomedical Optics,
8(4); 642-647; 2003


OCT in imaging larynx and cochlea
 (Collaboration with Otolaryngology-Head & Neck Surgery Department, Guy's Hospital, London)
 

A. G. Bibas
A.Gh.Podoleanu
R. G. Cucu
M. Bonmarin
G. M. Dobre
V. M. M Ward
E. Odell
A. Boxer
M. L Harries
M.J. Gleeson 		3-D Optical Coherence Tomography of the laryngeal mucosa
  		Clinical Otolaryngology, 29 (6): Dec. 2004, pp. 713-720.

 


OCT in imaging breast tissue
(Collaboration with the Department of Histopathology, Imperial College School of Medicine, Hammersmith Hospital, London)
 

P. J. Tadrous
A. Gh. Podoleanu S. Shousha
et al. 		3D tissue imaging - A practical method using automated image registration and its application to the development of in vivo histological imaging techniques J. Pathology
195: 1A-1A Suppl. S Sep. 2001
P. J. Tadrous
A. Gh. Podoleanu
G. M. Dobre
G.W.H. Stamp 		Application of VRML for 3-dimensional, interactive, real-time comparison of OCT structures with standard histology Coherence Domain Optical Methods and Optical Coherence Tomography in Biomedicine VII,
Valery V. Tuchin, Joseph A. Izatt, James G. Fujimoto, Editors, Proceedings of SPIE
Vol. 4956 (2003) © 2003 SPIE · 1605-7422/03/
Photonics West, BIOS2003, Jan. 27-29 Jan., p. 42-47.


Profilometry of craters using coherence radar
 

L. Kay
A. Gh.Podoleanu
M. Seeger
C. J. Solomon 		A New Approach to the Measurement and Analysis of Impact Craters Int. J. Impact Engn., Vol. 19, No. 8, 739-753, (1997).


Imaging paintings
 En-face OCT allows visualisation of under-drawings
 (Collaboration with the Nottingham Trent University, British Museum London and National Gallery, London)
 

H. Liang
M. G. Cid
R. Cucu
G.M. Dobre
J. Pedro
D. Saunders
A. Gh. Podoleanu 		Application of Optical Coherence
Tomography to Examination of Easel
Paintings 		Optics Express, Vol. 13, No. 16  August 08, 2005,  p. 6133 - 6144 http://www.opticsexpress.org/abstract.cfm?URI=OPEX-13-16-6133

Gallery of some OCT images, others can be viewed by linking to the web pages indicated in the
A. Podoleanu's publication list
 

Terminology (transversal or en-face versus longitudinal)

 

Sequence of 100 en-face OCT images from the optic nerve

Animation of OCT/SLO (en-face) pair images from the optic nerve

  See four clips of 
3D en-face OCT images from the optic nerve and 
3D en-face OCT images from the finger on 
Optics Express, Vol. 7,  No. 9,Oct. 23, 2000, 292-8
Longitudinal OCT images from the fovea and optic nerve Longitudinal OCT images from carried teeth
Animation of OCT/SLO (en-face) pair images from a carried tooth
Assembly of the OCT/SLO systems Longitudinal OCT images from the cornea
En-faceOCT images from the cornea
Topography and volume measurements of the optic nerve using en-face optical coherence tomography, Optics Express, Vol. 9, No. 10  November 05, 2001  Page: 533 - 545 New Images soon

Surface analysis and volume imaging using Coherence Radar

Achievements: