|
1.IntroductionA pterygium is the most obvious ophthalmic disease and is characterized by growth of the conjunctiva. It commonly encroaches onto the cornea as a triangular or wing shape (Fig. 1). Pterygia are usually small and relatively benign, but cause considerable irritation and often recur after surgery. A proportion of cases appear to be inherited,1 but other factors—including dust, wind, heat, infection, inflammation, and sunlight—have been proposed as causes. Nevertheless, the pathogenesis of pterygium remains unclear. While there are still no defined causes for pterygium formation, some techniques including ultra-structural pathology,2 3 immunology,4 and the peroxidation of the lipids5 are used to characterize the differences of microstructure, compositions, and metabolism between the pterygium and normal bulbar conjunctiva tissue. Among these techniques, ultrastructural pathology, such as transmission electron microscope (TEM), could only provide the ultra-structure of tissue but was limited to describe the molecular composition of tissues directly. Furthermore, neither immunohistochemical staining nor peroxidation of the lipids could identify the composition of biomedical tissues with elaborate information about molecules. Raman spectroscopy (RS) permits accurate, rapid, nondestructive, and noninvasive identification of tissues. The fingerprint spectral region, from 600 to 1800 cm−1, contains a series of sharp bands that can be used to characterize a particular molecule and in some cases to identify the composition of complex tissue’s samples. Since Yu et al. first introduced the application of RS in ophthalmology in 1975,6 investigations have focused on RS characterization of the cornea,7 the aqueous humor,8 the vitreous,9 and the retinal pigment.10 11 12 Up to now, no published papers involve RS characterization of human pterygium tissue. To characterize the molecular composition of pterygium and normal bulbar conjunctiva tissues and confirm the results of ultra-structural pathology, immunology, and peroxidation of lipids, Raman spectra of pterygium and normal bulbar conjunctiva tissue, which were obtained by employing visible excitations, as well as preliminary discussions of Raman scattering properties of pterygium in conjunction with results of correlative studies, are first reported here. 2.Materials and Method2.1.Ethical ApprovalThis protocol was approved by the relevant Local Research Ethics Committees (China). 2.2.Sample PreparationSurgical specimens of pterygia and normal conjunctival specimens from age-matched pterygia patients were obtained from Wuhan AIER Eye Hospital, Wuhan, China. Written informed consent was obtained from all patients. Specimens from the patients, which included 7 women and 13 men treated for pterygia, were separated into two parts. One was used for a histochemical H&E stain (Fig. 2), and the other one was used for a frozen section. Cryosections (25 μm in thickness) were obtained from the biopsy specimens and placed on a gold sheet for measurement of Raman spectroscopy. There were no extra Raman peaks for the gold sheet in the fingerprint spectral region, from 600 to 1800 cm−1 with somewhat low noise at the excitation wavelength of 514.5 nm. During measurement, the conjunctiva tissue section was thawed to reach room temperature and allowed to dry in air and discarded after use. 2.3.Raman InstrumentationA Renishaw Raman microspectrometer (System RM1000, Renishaw, Wotton under Edge, U.K.), similar to the system used by Puppels et al.,13 was optimized for maximum throughput, detection sensitivity, and fluorescence suppression. The argon ion laser (Spectra Physics, Mountain View, California) provided a 20-mW excitation light at 514.5 nm. After attenuation through prisms and filters, the power of the laser exposed on the samples was only about 4 mW, which makes it almost impossible for the laser to lead to degradation of the tissues. Spectra were measured from tissues with a 20× short-working-distance objective (NA 0.40), and the signal was integrated for 30 to 120 seconds and measured over a spectral range of 600 to 1800 cm−1 with respect to the excitation frequency. The system included a stigmatic spectrometer with two motorized gratings, of which the 1800 grooves/mm grating was used to provide a spectral resolution of the Raman scatter of about 5 cm−1. Raman scattering was detected by using an air-cooled 578×385-pixel CCD camera. Peak frequencies and rapid checking of instrumental performance were calibrated with the silicon phonon line at 520 cm−1. Spectral data were visualized on a computer and processed for baseline correction and normalization by the GRAMS/32 spectroscopic software (Thermo Galactic). Profile data were then imported into Origin 7.0 software (Origin Lab Corporation). 3.ResultsThe confocal Raman system (CRS) technique yielded rapid acquisition of high-SNR Raman spectra of the human normal bulbar conjunctiva and pterygium tissue using 514.5-nm laser irradiation. Typical Raman spectra obtained from normal bulbar conjunctiva (a) and pterygium (b) tissue, without any sample preparation, are shown in Fig. 3. The inset in Fig. 3 shows the spectra of the above-mentioned tissue before background subtraction. The CRS as presented here has various advantageous properties, as mentioned in many reports.13 The high gain of this optical system design is the high numerical aperture objective lens and a highly sensitive CCD camera. The confocal arrangement prevents the detection of stray light and enables the probing of small optical volumes, yielding adequate spatial resolution. To minimize the auto-fluorescence of tissues under visible excitation, the CRS should be optimized by reducing the slit and CCD area to suppress fluorescence and get high performance. Furthermore, laser bleaching was often employed, which means most samples should be irradiated by laser about 1 min to minimize its auto-fluorescence. This system had the highest spatial and spectral resolution; the laser was focused to a small spot within the sample and the Raman scattered light collected only from that point.13 Theoretically, the size of laser spot in our experiments could be given by s=0.61⋅λ/NA, and it was about 0.8 μm. Factually, the laser beam was focused manually on individually spots by means of a microscope objective to a spot of 1 to 2 μm in diameter. The power density was generally defined as the ratio of the power of the laser to the area of the spot, which means power density here was about 1 mw/μm2. Therefore, the spectra that were collected with such low excitation powers did not reveal changes that could be attributed to tissue heating.14 The main Raman bands and their assignments are listed in Table 1. The primary Raman peaks of tissue were observed at 1003, 1172, 1306, 1362, 1395, 1585, and 1639 cm−1, etc., presented in both tissue samples except for the bands at 1156, 1524, 1656, and 1748 cm−1, which only appeared in the spectra of pterygium. Additionally, the Raman band appears at ∼1450 cm−1 in the spectra of bulbar conjunctiva but at ∼1440 cm−1 in that of pterygium, which should be assigned to CH 3(CH 2) deformation vibration of proteins. Table 1
Raman bands of tissues, including the bulbar conjunctiva and pterygium tissue, result primarily from protein vibrations, such as amide I at ∼1656 and 1639 cm−1, amide III in the 1220 to 1300-cm−1 region,15 CH 2 (or CH 3) deformation vibration of protein at ∼1450 cm−1,16 and CH 2 twisting and wagging vibration at 1306 and 1172 cm−1.17 Furthermore, there are more specific Raman scattering for smaller molecular compounds, such as the very characteristic sharp band for ring-breathing vibration of phenylalanine at ∼1003 cm−1, which appears in all protein-containing samples. On the other hand, vibration of lipids also appears in the spectra of two types of tissue, such as the band at ∼1585 cm−1, which should be assigned to the stretching vibration of C=C in unsaturated fat acids, and the band at 1364 cm−1, which may be assigned to CH 3 symmetrical deformation vibration of lipids.17 4.DiscussionFigure 3 depicts the typical Raman spectra of normal bulbar conjunctiva [Fig. 3(a)] and pterygium [Fig. 3(b)] tissues in the range of Raman shift from 600 to 1800 cm−1. Even at an exposure time of less than 3 min, the SNR is sufficiently clear to distinguish the pterygium from normal bulbar conjunctiva. 4.1.Elastic Fibers: The Main Composition of PterygiumThe connective tissues are generally composed of elastic fibers and collagenous fibers, and these two typical fibers are mainly made up of elastin and collagen, respectively. Accumulation of elastin in solar elastosis in photodamaged skin has been demonstrated in transgenic mice, by both immunohistochemistry and molecular biology techniques.18 19 20 It is likely that the pathological changes in conjunctiva in response to chronic UV irradiation are similar to those in chronically sun-damaged skin. The results of pathological ultra-structure of pterygium stressed that multiplication and degeneration of elastic and collagenous fibers are the prominent pathological changes, and the pre-elastic fibers and denatured elastic fibers are the main compositions of pterygium.2 3 Comparing the spectra of normal conjunctiva and pterygium tissue as shown in Fig. 3, there are obvious differences in the region of amide I. The bands near 1639 cm−1 and 1656 cm−1, which should be assigned to amide I vibration of collagen and elastin, respectively, both appear in the spectra of pterygium tissue. However, only the band at 1639 cm−1 appears in the spectra of normal bulbar conjunctiva tissue and even its relative intensity is higher than that in the spectra of pterygium. It is demonstrated that elastin is the main type of tissue in pterygium and there are also small amount of collagen in it, which is consistent with the results of ultrastructural pathology.2 3 4.2.Lymphocyte: Significant Increase in PterygiumSeveral investigators have noted an increase of mast cell (MC), lymphocyte, and plasma cell numbers in pterygium.4 21 22 This study demonstrates the validity of these results in that there are significant increases of lymphocyte in pterygium. Carotenoids are widely spread in all sorts of organ tissues especially in lymphocyte, and lymphocyte may be the main carrier of carotenoids in pterygium. There are two characteristic bands at ∼1521 cm−1 and ∼1156 cm−1 of carotenoids, which should be assigned to carbon-carbon double-bond stretch vibrations of the molecule’s backbone and carbon-carbon single-bond stretch vibrations of carotenoids, respectively.23 Carotenoids are π-electron conjugated carbon-chain molecules (C 40 H 56) and are similar to polyenes in their structure and optical properties. Because of the molecular structure of polyene molecules, they elicit very strong Raman scattering, especially when resonantly excited in their π-π* electronic absorption transition in the visible (violet/green) wavelength range.24 In comparison with the spectra of normal bulbar conjunctiva tissue, typical characteristic Raman bands of carotenoids were observed only in the spectra of pterygium as shown in Fig. 3(b). This result proves that the content of carotenoids is more in pterygium tissue than in normal tissue. According to the results of immunology,21 22 it may be concluded that the pathological changes in pterygium tissue indicate a chronic inflammatory condition with fibrosis, and lymphocytes are thus presumed to have an important role in the pathogenesis of pterygium tissue. 4.3.Unsaturated Fatty Acids: Significant Decrease in PterygiumHuman tissues, especially for biomembrane (including cell membrane and organelle membrane), contain abundant unsaturated fatty acids. Light could induce a lipid peroxidation chain reaction of unsaturated fatty acids in limbus corneae’s histiocytes. The end products of a lipid peroxidation reaction are small molecule compounds, such as aldehyde and ketone, etc. Malondialdehyde is one of the end products of lipid peroxidation reaction and is a marker of lipid peroxidation reaction. The study of lipid peroxidation reaction stressed that the concentration of malondialdehyde in the pathologic samples was much higher than that in the normal samples (P<0.01). 5 From Fig. 3, the Raman band near ∼1585 cm−1 should be assigned to a C=C unsaturated fatty acids stretch of lipids in the pterygium tissue. It was obviously lower than that in normal bulbar conjunctiva tissue. Accordingly, the Raman band near ∼1748 cm−1, which should be ascribed to a C=O stretch of aldehyde or ketone, only appears in the spectra of the pterygium tissue. These results sufficiently confirm that there are significant decreases of unsaturated fatty acids in pterygium as a result of a lipid peroxidation reaction but a significant increase of malondialdehyde accordingly. Since the late 1970s, there has been an increasing flow of articles on applied Raman spectroscopy in ophthalmology. This increase reflects the expectation that this valuable technique will be introduced in the future into clinical practice. However, to introduce the Raman technique as a clinically applied diagnostic tool, much more work has to be done. The discrepancy between system sensitivity and eye safety is the main drawback of the RS system for ophthalmic use, which still needs to be overcome to allow the safe clinical application of this optical technique for the noninvasive assessment of conjunctiva in vivo. However, we believe that with adequate improvement in system safety, RS could potentially be applied as a noninvasive tool for the assessment of conjunctiva in vivo with clinical relevance for the early diagnosis of pterygium. 5.ConclusionsThis study has demonstrated the facility of confocal Raman microspectroscopy to distinguish between pterygium and normal bulbar conjunctiva tissue and the great potential of Raman spectroscopy in combination with optical fiber probes for rapidly investigating the pathology of pterygium in vivo. In conjunction with the results of ultrastructural pathology, immunology, and the peroxidation of the lipids, pterygium were discovered that had more elastic fibers, mast cells, and lymphocytes, but fewer unsaturated fat acids than normal bulbar conjunctiva tissue. We also found that elastic fibers were the main component of pterygium. AcknowledgmentsThe authors gratefully acknowledge all the staff in the Wuhan AIER Eye Hospital for their generous cooperation. This project was supported by the National Natural Science Foundation of China (No. 20405011, No. 20427002, and No. 20375029) and the Natural Science Fund of Hubei Province. REFERENCES
F. Hecht
and
M. G. Shoptaugh
,
“Winglets of the eye: dominant transmission of early adult pterygium of the conjunctiva,”
J. Med. Genet. , 27 392
–394
(1990). Google Scholar
P. Austin
,
F. A. Jackobiec
, and
T. Iwamoto
,
“Elastodysplasia and elasto-dystrophy as the pathologic bases of ocular pterygia and pingguecula,”
Ophthalmology , 90 96
–101
(1988). Google Scholar
G. X. Xu
,
L. Y. Zhou
,
Y. Tong
,
P. Liang
,
F. S. Lin
, and
L. Y. Chen
,
“Pathological ultrastructure study of pterygium,”
Chin. J. Ophthalmol. , 32 438
–440
(1996). Google Scholar
L. Liu
and
D. Yang
,
“Immunological studies on the pathogenesis of pterygium,”
Chin. Med. Sci. J. , 8 84
–88
(1993). Google Scholar
L. Lv
,
R. G. Wang
,
X. H. Song
,
H. Li
,
D. S. Dong
, and
L. H. Zou
,
“Pterygium and lipid peroxidation,”
Chung Hua Yen Ko Tsa Chih , 32 227
–229
(1996). Google Scholar
N. T. Yu
and
E. J. East
,
“Laser Raman spectroscopic studies of ocular lens and its isolated protein fractions,”
J. Biol. Chem. , 250 2196
–2202
(1975). Google Scholar
D. C. W. Siew
,
G. M. Clover
,
R. P. Coonet
, and
P. M. Wiggins
,
“Micro-Raman spectroscopy study of organ cultured corneae,”
J. Raman Spectrosc. , 26 3
–8
(1995). Google Scholar
R. J. Erckens
,
M. Motamedi
,
J. P. Wicksted
, and
W. F. March
,
“Raman spectroscopy for non-invasive characterization of ocular tissue: potential for detection of biological molecules,”
J. Raman Spectrosc. , 28 293
–299
(1997). Google Scholar
J. Sebag
,
S. Nie
,
K. Reiser
,
M. A. Charles
, and
N. T. Yu
,
“Raman spectroscopy of human vitreous in proliferative diabetic retinopathy,”
Invest. Ophthalmol. Visual Sci. , 35 2976
–2980
(1994). Google Scholar
L. Huang
,
H. Deng
, and
Y. Koutalos
,
“A resonance Raman study of the C=C stretch modes in bovine and octopus visual pigments with isotopically labeled retinal chromophores,”
Photochem. Photobiol. , 66 747
–754
(1997). Google Scholar
D. Zhao
,
S. W. Wintch
,
W. Gellermann
, and
P. S. Bernstein
,
“Resonance Raman spectroscopic measurement of macular carotenoid pigments in patients with choroidal and retinal dystrophies,”
Invest. Ophthalmol. Visual Sci. , 43 U598
–U598
(2002). Google Scholar
D. Zhao
,
S. W. Wintch
,
W. Gellermann
, and
P. S. Bernstein
,
“Resonance Raman measurement of macular carotenoids in retinal, choroidal, and macular dystrophies,”
Arch. Ophthalmol. (Chicago) , 121 967
–972
(2003). Google Scholar
K. Maquelin
,
L. P. Choo-Smith
,
T. van Vreeswijk
,
H. P. Endtz
,
B. Smith
,
R. Bennett
,
H. A. Bruining
, and
G. J. Puppels
,
“Raman spectroscopic method for identification of clinically relevant microorganisms growing on solid culture medium,”
Anal. Chem. , 72 12
–19
(2000). Google Scholar
M. G. Shim
and
B. C. Wilson
,
“The effect of ex vivo handling procedures on the near-infrared Raman spectra of normal mammalian tissues,”
Photochem. Photobiol. , 63 662
–671
(1996). Google Scholar
M. J. Anita
and
R. K. Rebecca
,
“Raman spectroscopy for the detection of cancers and precancers,”
J. Biomed. Opt. , 1 31
–70
(1996). Google Scholar
M. G. Shim
and
B. C. Wilson
,
“The effect of ex vivo handling procedures on the near-infrared Raman spectra of normal mammalian tissues,”
Photochem. Photobiol. , 63 662
–671
(1996). Google Scholar
E. F. Bernstein
,
D. B. Brown
,
F. Urbach
,
D. Forbes
,
M. Del Monaco
,
M. Wu
,
S. D. Katchman
, and
J. Uitto
,
“Ultraviolet radiation activates the human elastin promoter in transgenic mice: a novel in vivo an in vitro model of cutaneous photoaging,”
J. Invest. Dermatol. , 105 269
–273
(1995). Google Scholar
W. Montagna
,
S. Kirchner
, and
K. Carlisle
,
“Histology of sun-damaged skin,”
J. Am. Acad. Dermatol. , 21 907
–918
(1989). Google Scholar
S. Okisaka
,
M. Kudo
,
M. Funahashi
, and
S. Nakada
,
“The pathogenesis of pterygium,”
Ophthalmology , 27 633
–642
(1985). Google Scholar
Y. Kadota
,
“Morphological study on the pathogenesis of pterygium,”
Nippon Ganka Gakkai Zasshi , 91 324
–334
(1987). Google Scholar
W. Gellermann
,
M. Sharifzadeh
,
M. Ermakova
, and
I. V. Ermakov
,
“Resonant Raman detectors for noninvasive assessment of carotenoid antioxidants in human tissue,”
Proc. SPIE , 4958 78
–87
(2003). Google Scholar
S. Arikan
,
H. S. Sands
,
R. G. Rodway
, and
D. N. Batchelder
,
“Raman spectroscopy and imaging of β-carotene in live corpus luteum cells,”
Anim. Reprod. Sci. , 71 249
–266
(2002). Google Scholar
|