Keywords
Cell nucleus - cytoplasm - fractal - histology - pathology
Introduction
The American Cancer Association estimated 52.070 new cases of thyroid neoplasms and
2.170 deaths due to these diseases for 2019 in the United States. Although constant,
the mortality rate for thyroid cancer is low compared to other types of neoplasms.[1] The introduction and routine usage of ultrasound resulted in the detection of small
nodules and thus contributing to the increased incidence of thyroid cancers.[1] It is worth noting that better diagnostic methods are resulting in early diagnosis
and diagnosis of advanced stage cancer, independent of the type of cancer.[2]
In the clinical literature, it is documented that the majority of thyroid neoplasms
begin in follicular cells of the thyroid gland and their progression varies from well-differentiated
thyroid cancers to anaplastic cancers.[3],[4] There are different types of malignant thyroid neoplasms depending on the cell of
origin and the extent of differentiation, or if they are medullar or anaplastic.[5] Differentiated thyroid neoplasms include papillary, follicular, and Hürthle cell
cancer; most differentiated tumors are heterogeneous, including papillary and follicular
patterns simultaneously, which was formerly described as mixed follicular and papillary
carcinomas.[3] However, the current classifications differentiate among the most predominant histological
pattern within differentiated thyroid carcinomas, establishing variants of papillary
carcinoma.[3] Nevertheless, it has been considered that differentiated neoplastic cells share
similar morphologic features with normal cells when under microscopy.[5]
The initial diagnostic criteria of the papillary carcinoma were established through
a growth pattern; then, the shape of the nucleus was more relevant, given that the
nuclear characteristics are considered as a diagnostic pattern of the tumor.[6] Studies conducted to evaluate the shape of the nucleus of papillary tissues have
found that this structure is bigger and oval shaped when compared to the nucleus of
benign follicular cells, although it is common to find similar nuclear features.[6] Thus, the necessity for modalities that can differentiate the features at ultrastructural
level has arisen, in which an extreme polymorphism in the nucleus of differentiated
thyroid carcinomas has been found, some presenting spherical forms sliced by a deep
narrow furrow in two unequal parts or the appearance of ground-glass, among other
features.[7]
Fractal irregular objects that are the base of fractal geometry[8],[9] and its notions have been applied for the characterization of irregular structures
of the human body, revealing the possibility of developing more precise measures of
the irregularity of these structures.[10],[11],[12],[13],[14],[15],[16],[17],[18],[19],[20],[21] Among the designed methods to evaluate the degree of irregularity of fractal objects,
the Box-Counting method is found. This method evaluates fractal dimension of fractal
objects called wild fractals[8],[9] such as coronary arteries[14] and has been applied to clinically characterize and diagnose glaucoma, the normal
human vasculature, breast cancer tissues, and others.[18],[19],[20] From this line of investigation, different diagnostic methodologies of clinical
application that evaluate the different lesions of cervical cells have been developed
capable of differentiating benign from malignant atypical squamous cells of undetermined
significance relying on the occupied spaces of the nucleus and cytoplasm.[16]
Considering that thyroid cells exhibit irregular features suggesting their fractality
and in the frame of previous research, the purpose of this study is to conduct an
application of a methodology developed by Rodríguez with the purpose of characterizing
the irregularity of the nucleus and cytoplasm of cells obtained from biopsy samples
of normal and benign and malignant papillary and follicular thyroid neoplasms through
the box-counting method and to compare the values of the occupied spaces of the surface
and border of these structures.
Subjects and Methods
Surface of the object
Quantity of pixels occupied by the cytoplasm or nucleus.
Border of the object
Quantity of pixels occupied by the edges of the cytoplasm or nucleus.
Fractal dimension
Evaluates the degree of irregularity of fractal objects, which are both the cytoplasm
and the nucleus of cells, through the following formula:
Equation 1
Where D: Fractal dimension; N: Quantity of spaces occupied by the surface or the border
of the fractal objects; and k, the partition of the grid.
Population
Histological samples prepared with quality and staining criteria were obtained from
biopsy samples of patients with different sex and ages who had indication of thyroid
gland biopsy. From these samples, different sets of cells were organized and observed,
considering normal thyroid cells as well as benign and malignant thyroid papillary
and follicular carcinomas according to the traditional evaluation performed by an
expert pathologist like this: 2 sets of 10 normal papillary and follicular cells;
2 sets of 10 cells with adenoma and follicular carcinoma; and 4 sets of 10 cells with
papillary thyroid carcinoma classical variant, poorly differentiated papillary carcinoma,
anaplastic thyroid carcinoma with one nucleus, and anaplastic thyroid carcinoma with
2 or more nuclei.
Procedure
The histological samples were observed with a light microscope using transmitted moderately
intense light under oil immersion at a magnification of ×100 and were then photographed
with a digital camera. All the photographs were adjusted to be saved with the same
width in pixels, and the borders of the cytoplasm and nucleus of each cell were defined
with an image editor. Then, these images were treated with a software designed in
C++ that recognizes these edges and allows to measure the structures.
In order to find the fractal dimension of each cell (Equation 1), two grids of 5 (R5)
and 10 (R10) pixels are overlapped on the images. Then, a quantification of the squares
occupied by the border and the surface of each cell was done. The measurement of the
number of squares occupied by the surface of the cell with the R5 and R10 grids allows
to obtain fractal dimension. Spaces occupied by the borders of the objects were as
well considered for measurement.
Ethical aspects
As the samples were obtained from patients who had a medical indication of thyroid
biopsy, consent was taken from patients in order to authorize the processing of their
samples for research purposes. The integrity and anonymity of the participants was
preserved at all times. The Institutional Ethics Committee of Fundación Universitaria
Autónoma de las Américas approved the development of the project. According to the
article 11 of the Resolution 8430 of 1993 and the law 84 of 1989 emitted by the Ministerium
of Health, the kind of risk related to this research is minimum, since physical and
mathematical calculations are performed over results.
Results
[Table 1] and [Table 2] display the histopathological diagnosis for the group of follicular and papillary
cells as well as the values of the spaces occupied in R5 and R10 grids. Values of
fractal dimension were not considered in the characterization of cells due to overlapping
of numbers. The analysis of normal cells highlights that the number of squares occupied
when overlapping the two grids, both the surface and cytoplasm overlap. Besides, it
was noted that the nucleus and cytoplasm of normal papillary tissues had bigger occupied
spaces, consistent with other studies.[6]
Table 1
Drugs
|
Number
|
Follicular thyroid cells
|
|
Histopathological diagnostic
|
Nucleus
|
Cytoplasm
|
|
R5
|
R10
|
S
|
Con
|
Df
|
R5
|
R10
|
S
|
Con
|
Df
|
|
Ca – Carcinoma
|
|
1
|
Normal
|
54
|
27
|
2088
|
194
|
1
|
115
|
46
|
1473
|
464
|
1.322
|
|
2
|
Normal
|
47
|
25
|
2099
|
183
|
0.911
|
120
|
51
|
1752
|
448
|
1.234
|
|
3
|
Normal
|
38
|
19
|
1404
|
134
|
1
|
121
|
55
|
3025
|
455
|
1.138
|
|
4
|
Normal
|
24
|
12
|
736
|
92
|
1
|
94
|
40
|
1884
|
366
|
1.233
|
|
5
|
Normal
|
34
|
19
|
1394
|
127
|
0.840
|
144
|
68
|
3370
|
549
|
1.082
|
|
6
|
Follicular adenoma
|
33
|
17
|
1297
|
134
|
0.957
|
85
|
36
|
1611
|
363
|
1.239
|
|
7
|
Follicular adenoma
|
37
|
20
|
1339
|
134
|
0.888
|
68
|
32
|
1204
|
298
|
1.087
|
|
8
|
Follicular adenoma
|
38
|
20
|
1835
|
161
|
0.926
|
63
|
32
|
1468
|
261
|
0.977
|
|
9
|
Follicular adenoma
|
33
|
17
|
1515
|
144
|
0.957
|
78
|
31
|
928
|
330
|
1.331
|
|
10
|
Follicular adenoma
|
37
|
19
|
1755
|
148
|
0.962
|
81
|
33
|
1344
|
313
|
1.295
|
|
11
|
Follicular Ca.
|
47
|
23
|
2025
|
191
|
1.031
|
124
|
59
|
3178
|
544
|
1.072
|
|
12
|
Follicular Ca.
|
52
|
26
|
2960
|
199
|
1
|
139
|
66
|
4128
|
555
|
1.075
|
|
13
|
Follicular Ca.
|
38
|
20
|
1146
|
157
|
0.926
|
98
|
40
|
1471
|
420
|
1.293
|
|
14
|
Follicular Ca.
|
42
|
22
|
1600
|
169
|
0.933
|
112
|
50
|
2583
|
458
|
1.163
|
|
15
|
Follicular Ca.
|
41
|
22
|
1709
|
164
|
0.898
|
117
|
57
|
3527
|
486
|
1.037
|
Table 2
Histopathological diagnostics and values of representative papillary thyroid cells
|
Number
|
Follicular thyroid cells
|
|
Histopathological diagnostic
|
Nucleus
|
Cytoplasm
|
|
R5
|
R10
|
S
|
Con
|
Df
|
R5
|
R10
|
S
|
Con
|
Df
|
|
Ca – Carcinoma; Pa – Papillary; Pd – Poorly-differentiated; An – Anaplastic; M – Multinucleate
|
|
1
|
Pa. thyroid Ca. classical variant
|
46
|
24
|
2233
|
138
|
0.939
|
112
|
48
|
2248
|
450
|
1.222
|
|
2
|
Pa. thyroid Ca. classical variant
|
47
|
25
|
2391
|
196
|
0.911
|
124
|
59
|
2918
|
510
|
1.072
|
|
3
|
Pa. thyroid Ca. classical variant
|
39
|
18
|
2045
|
158
|
1.115
|
99
|
45
|
1820
|
410
|
1.138
|
|
4
|
Pa. thyroid Ca. classical variant
|
38
|
20
|
1857
|
162
|
0.926
|
93
|
42
|
1699
|
416
|
1.147
|
|
5
|
Pa. thyroid Ca. classical variant
|
45
|
21
|
2125
|
171
|
1.100
|
104
|
46
|
2144
|
407
|
1.177
|
|
6
|
Pd. Pa Ca.
|
43
|
22
|
2461
|
177
|
0.967
|
118
|
60
|
3665
|
502
|
0.976
|
|
7
|
Pd. Pa Ca.
|
51
|
25
|
2977
|
200
|
1.029
|
124
|
60
|
2773
|
519
|
1.047
|
|
8
|
Pd. Pa Ca.
|
46
|
23
|
2237
|
188
|
1
|
139
|
62
|
3552
|
551
|
1.165
|
|
9
|
Pd. Pa Ca.
|
37
|
19
|
1394
|
147
|
0.962
|
107
|
53
|
3440
|
441
|
1.014
|
|
10
|
Pd. Pa Ca.
|
47
|
25
|
2489
|
190
|
0.911
|
119
|
54
|
2309
|
482
|
1.140
|
|
11
|
An. thyroid Ca.
|
28
|
14
|
802
|
107
|
1
|
78
|
34
|
1331
|
308
|
1.198
|
|
12
|
An. thyroid Ca.
|
43
|
21
|
1442
|
157
|
1.034
|
136
|
63
|
3720
|
519
|
1.110
|
|
13
|
An. thyroid Ca.
|
37
|
20
|
1086
|
139
|
0.888
|
106
|
49
|
2274
|
433
|
1.113
|
|
14
|
An. thyroid Ca.
|
22
|
10
|
686
|
96
|
1.138
|
74
|
31
|
1613
|
320
|
1.255
|
|
15
|
An. thyroid Ca. M
|
41
|
21
|
2247
|
160
|
0.965
|
246
|
121
|
25476
|
936
|
1.024
|
|
16
|
An. thyroid Ca. M
|
37
|
20
|
1407
|
147
|
0.888
|
243
|
123
|
26396
|
920
|
0.982
|
|
17
|
An. thyroid Ca. M
|
35
|
19
|
1105
|
128
|
0.881
|
233
|
115
|
26714
|
902
|
1.019
|
|
18
|
An. thyroid Ca. M
|
40
|
20
|
2015
|
155
|
1.000
|
243
|
120
|
25741
|
929
|
1.018
|
|
19
|
An. thyroid Ca. M
|
25
|
11
|
481
|
85
|
1.184
|
228
|
116
|
27516
|
859
|
0.975
|
Furthermore, it can be observed that the differences of the spaces occupied when overlapping
the two grids in the variations of the nucleus of the of the other cellular groups
with regard to normal cells were quite small. The values for normal follicular thyroid
cells varied between 38–26 and 19–12 with the R5 and R10 grids, while these values
were 42–33 and 23–16 for normal papillary thyroid cells, respectively. With respect
to the cytoplasm, slight changes are noted with respect to all the cellular groups
when compared with the normal group of follicular and papillary tissues, which were
144–89 and 132–84, respectively.
In exchange, the values of the surfaces and borders allow further characterization
between the groups of follicular and papillary tissues. For example, the nuclear surface
of normal follicular cells varied between 1404 and 502 while adenoma cells varied
between 1835 and 1297 and follicular carcinoma cells varied between 2960 and 1146.
This indicates that the nuclear surface of follicular carcinoma is bigger than for
normal tissues; similar findings are obtained when analyzing the values of the borders.
The values of the surface of the cytoplasm of papillary normal cells varied between
3370 and 1526, whereas follicular adenoma cell varied between 1611 and 928, and follicular
carcinoma occupies a bigger space.
Discussion
This is the first investigation that conducts an application of a methodology based
on the notions of fractal and Euclidean geometry in order to characterize different
groups of follicular and papillary thyroid cells, through the analysis of the degree
of irregularity of the cellular surfaces and borders. The results of the evaluated
groups with the box-counting method reveal the possibility of obtaining new methods
of characterization from the occupied spaces by the nucleus and cytoplasm.
In the medical literature, it is mentioned that well-differentiated thyroid carcinomas,
whether papillary or follicular, are morphologically similar to normal tissues under
microscopy.[5] This study found that the values of the occupied spaces with the two grids in normal
follicular and papillary cells are overlapped, but papillary cells are slightly bigger.
Although these results are consistent with some clinical results,[6] the measurements developed from the values of the surface and border of cells reveal
the possibility of enhancing the distinctions between these cellular groups, which
in the future can contribute to the design of a complementary diagnostic methodology
for thyroid cancer.
On the other hand, cervical cancer has been analyzed under this line of investigation,
achieving the development of diagnostic methodologies with which is possible to conduct
objective and reproducible characterizations of preneoplastic and neoplastic states.[15],[16],[18] This research highlights as well that current oncologic knowledge can further be
amplified with methodologies that measure cellular structures and establish mathematical
numerical values that allow diagnose cellular lesions.
The development of precise methodologies that reduce the inter- and intraobserver
diagnostic variability has been a priority in medicine to ensure clearer diagnostics.
This has been achieved through the theoretical physics and mathematical thinking that
seeks to generalize phenomena, independent of risk factors or the experience of the
operator. For example, the studies developed in neonatal, fetal, and adult cardiology
are proof of the applicability of this thinking, from which alterations of cardiac
dynamics and mortality can be predicted.[22],[23],[24]
Limitations
This study and other methods,[22],[23],[24] although highly promising in the clinical context, can only be clinically applicable
if automatized through specialized software that allows to obtain immediate diagnostics.
Furthermore, the acausal perspective of this research does not answer causal relationship
among phenomena, which is why this evaluation must be complemented with other methods
that elucidate the etiology of diseases.
Conclusions
A novel method based on fractal and Euclidean geometries was used to characterize
thyroid cellular features. This method could enhance the diagnosis of thyroid cancer
since it is independent of the operator diagnostic criteria and expertise; however,
diagnostic parameters must be first established in other diagnostic agreements studies
between this method and the current histopathological criteria with larger samples
that confirm our findings. Furthermore, this method must be fully automated since
the application performed in this study was manual.
Acknowledgment
We thank Visión de las Américas Universitary Foundation for their support to our investigations,
specially to the department of Research of the university and the Faculty of Medicine
for the financial support provided through the project P126-2018. Special thanks to
doctors Verónica García Maya, Research director, Edwin Meneses, director of the group
“investigación en salud y comunidad,” and doctor Mauricio Hidelberg Montoya, dean
of the Faculty of Medicine for their support to our investigations.
