Open Access

Epidemiologic characteristics of oral cancer: single-center analysis of 4097 patients from the Sun Yat-sen University Cancer Center

Contributed equally
Chinese Journal of Cancer201635:24

https://doi.org/10.1186/s40880-016-0078-2

Received: 9 May 2015

Accepted: 30 November 2015

Published: 3 March 2016

Abstract

Background

Oral cancer is a common type of head and neck cancers. Knowing its epidemiologic characteristics is crucial to preventing, diagnosing, and treating this cancer. This study aimed to explore the epidemiologic characteristics of oral cancer in South China.

Methods

We retrospectively analyzed data from 4097 oral cancer patients treated at the Sun Yat-sen University Cancer Center between 1960 and 2013. We compared the age of onset, sex ratio, pathologic type, and primary tumor location among three subcultural areas (Guangfu, Hakka, and Chaoshan) and between an economically developed region and a less-developed one in Guangdong.

Results

Overall, oral cancer had a male-to-female ratio of approximately 2:1, and this ratio decreased over time. Oral cancer occurred mostly in patients of 45–64 years old (54.5%), and the percentage of older patients gradually increased over time. The most common tumor location was the tongue. Squamous cell carcinoma was the predominant pathologic type. The percentage of blood type O in oral cancer patients was lower than that in the healthy population. The male-to-female ratio in the Chaoshan area was higher than that in the Guangfu and Hakka areas, whereas the age of disease onset in Guangfu was higher than that in Hakka and Chaoshan. The male-to-female ratio was lower and the age of disease onset was higher in the economically developed region than in the less-developed region.

Conclusion

The incidence of oral cancer in South China presents typical characteristics to which doctors should pay attention when diagnosing and treating oral cancer patients.

Keywords

Oral cancerEpidemiologyGuangdong

Background

More than two million deaths of cancer per year [1] make it a major public issue in China. Worldwide, the 263,900 cases of oral cancer per year make it the 10th most common cancer in men [2]. The incidence of oral cancer is widely believed to be associated with the use of tobacco, alcohol, betel quid (a vine with mild stimulant properties), and areca nut (a palm nut with mild stimulant properties often chewed with betel quid) [3]. People of lower socioeconomic class may also be more prone to oral cancer than those of higher class [4], perhaps because of poor oral hygiene and nutrition. Some researchers believe that the incidence is also associated with air pollution [5].

The Sun Yat-sen University Cancer Center is the largest cancer hospital in Guangdong Province and in South China and treats more cancer patients than most hospitals in this region. Therefore, patients treated in this center largely present with typical characteristics of diseases in this region, including oral cancer, which is a major disease diagnosed and treated here. We retrospectively analyzed data from patients with oral cancer treated at the cancer center to determine the disease characteristics prevalent in South China, with the aim of providing a sound knowledge base for its prevention, diagnosis, and treatment.

Methods

Patient collection

Data from all patients with oral cancer treated at the Sun Yat-sen University Cancer Center between 1960 and 2013 were collected. All the patients were diagnosed by pathologic analysis.

Data collection

In addition to standard demographic data, we collected data on the date of hospital admission, location of the primary tumor, blood type, native place, long-term residence, and so on.

Patients were classified into five groups by period of admission (1960–1973, 1974–1983, 1984–1993, 1994–2003, and 2004–2013) and seven age groups (0–24, 25–34, 35–44, 45–54, 55–64, 65–74, and ≥75 years).

The location of the primary tumor in each patient was identified as being in one of six parts of the mouth: the body of the tongue (the front two-thirds of the tongue, not including the root), the floor of the mouth, the buccal mucosa, the alveolus, the retromolar area, and the hard palate (not including the soft palate).

Guangdong Province was divided into three subcultural, geographic areas according to residents’ dialects, diets, and living habits: Guangfu (also known as Cantonese, including Guangzhou, Shenzhen, Zhuhai, Foshan, Zhanjiang, Zhaoqing, Jiangmen, Maoming, Yangjiang, Qingyuan, Dongguan, Zhongshan, and Yunfu), Hakka (Meizhou, Huizhou, Heyuan, and Shaoguan), and Chaoshan (Chaozhou, Shantou, Jieyang, and Shanwei). Patients’ native places were classified into one of these three geographic areas.

Guangdong was further divided into two regions: the Pearl River Delta region (Guangzhou, Shenzhen, Zhuhai, Foshan, Zhaoqing, Jiangmen, Huizhou, Dongguan, and Zhongshan) and the non-Pearl River Delta region. The Pearl River Delta region is markedly more economically developed [6]. Patients’ long-term residences were classified in these two geographic regions.

Statistical analysis

All data were sorted and analyzed with SPSS 21.0 (SPSS Inc., Chicago, IL, USA). Alpha was set at 0.05, and all tests were two-tailed. Frequencies and proportions were calculated for the demographic data. The Chi square test was used to analyze the associations of oral cancer with sex and blood type. The Analysis of Variance (ANOVA) was used when analyzing the age distribution. The Bonferroni correction was applied for multiple comparisons.

Results

Data from 4097 patients, 2729 males and 1368 females, were analyzed (Table 1).
Table 1

Residential and hospital admission characteristics of 4097 oral cancer patients in South China by sex

Variate

Total

Male

Female

M:F ratio

P

Period of hospital admission

4097

2729

1368

1.99

<0.05

 1960–1973

432

293

139

2.11

 

 1974–1983

500

344

156

2.21

 

 1984–1993

803

549

254

2.16

 

 1994–2003

959

635

324

1.96

 

 2004–2013

1403

908

495

1.83

 

Subcultural areaa

3630

2418

1212

2.00

<0.05

 Guangfu (Cantonese)

2470

1602

868

1.85

 

 Hakka

488

315

173

1.82

 

 Chaoshan

481

340

141

2.41

 

 Unknown

191

161

30

5.37

 

Economic regionb

3661

2427

1234

1.97

<0.05

 Pearl river delta region

2479

1617

862

1.88

 

 Non-pearl river delta region

1072

736

336

2.19

 

 Unknown

110

74

36

2.06

 

aA total of 467 non-Cantonese patients were excluded from this analysis

bA total of 436 patients who live in other provinces were excluded from this analysis

Age distribution

The median age of disease onset of the patients was 53 years (range, 3–97 years). The age of onset was concentrated between the ages of 45 and 64 years (Table 2). In addition, over the study period of approximately 50 years, the percentage of older patients significantly increased (F = 17.29, P < 0.001).
Table 2

Residential and hospital admission characteristics of 4097 oral cancer patients in South China by age at admission

Variate

Total

Age (years)

P

 

0–24

25–34

35–44

45–54

55–64

65–74

75–

Period of hospital admission

4097

96

287

711

1056

1178

622

147

<0.001

 1960-1973

432

17

36

110

103

114

48

4

 

 1974-1983

500

10

44

83

171

131

54

7

 

 1984-1993

803

22

55

145

197

250

119

15

 

 1994-2003

959

16

68

157

236

270

162

50

 

 2004-2013

1403

31

84

216

349

413

239

71

 

Subcultural areaa

3630

86

239

623

927

1049

569

137

<0.001

 Guangfu (Cantonese)

2470

46

152

402

612

740

421

97

 

 Hakka

488

16

33

95

142

129

58

15

 

 Chaoshan

481

12

42

95

134

133

50

15

 

 Unknown

191

12

12

31

39

47

40

10

 

Economic regionb

3661

86

251

630

929

1054

575

136

<0.001

 Pearl river delta region

2479

41

145

394

627

738

433

101

 

 Non-pearl river delta region

1072

33

92

213

279

295

130

30

 

 Unknown

110

12

14

23

23

21

12

5

 

aA total of 467 non-Cantonese patients were excluded from this analysis

bA total of 436 patients who live in other provinces were excluded from this analysis

Tumor location

Most tumors were on the tongue (64.3%), followed by the gingiva, hard palate, buccal mucosa, floor of the mouth, lips, and retromolar area (Table 3).
Table 3

Disease characteristics of 4097 oral cancer patients in South China

Variate

Number of cases

Percentage (%)

Tumor location

4097

 

 Body of tongue

2230

54.4

 Floor of mouth

305

7.4

 Buccal mucosa

367

9.0

 Gingiva

534

13.0

 Retromolar area

18

0.4

 Hard palate

381

9.3

 Lips

187

4.6

 Unknown

75

1.8

Pathologic type

4097

 

 Squamous cell carcinoma

3642

88.9

 Adenoid cystic carcinoma

119

2.9

 Mucoepidermoid carcinoma

77

1.9

 Malignant melanoma

48

1.2

 Adenocarcinoma

32

0.8

 Basaloid carcinoma

28

0.7

 Malignant mixed tumor

25

0.6

 Sarcoma

22

0.5

 Myoepithelial carcinoma

4

0.1

 Others

100

2.4

Blood type

4097

 

 A

1021

24.9

 B

1039

25.4

 AB

253

6.2

 O

1519

37.1

 Unknown

265

6.5

Pathologic type

Squamous cell carcinoma was the most common type of oral cancer (88.9%; Table 3). Of the 3642 cases of squamous cell carcinoma, 2126 were highly differentiated, 928 were moderately differentiated, 289 were poorly differentiated, and 299 were unknown.

Blood type

The blood type of 265 patients was not identified. The distribution of blood types of the remaining patients is presented in Table 3.

Distribution of native places

Most patients were Cantonese (3630 patients). The distributions of Cantonese patients by their native places were Guangfu (2470), Hakka (488), Chaoshan (481), and unknown (191).

The male-to-female ratio differed significantly in the three subcultural areas (χ 2  = 6.36, P < 0.05). Pairwise comparisons indicated that the ratio in the Chaoshan area was significantly higher than those in the Hakka and Guangfu areas (Table 1).

The age of disease onset also differed significantly among the three subcultural areas (F = 9.96, P < 0.001). Pairwise comparisons indicated that the age of disease onset in Guangfu was significantly higher than those in Hakka and Chaoshan (Table 2).

Economic conditions

A total of 436 patients who live in other provinces were excluded from this analysis. Of the 3661 residents in Guangdong, 2479 lived in the Pearl River Delta region, 1072 lived in the non-Pearl River Delta region, and 110 were unknown. The male-to-female ratio differed significantly between these two regions (χ 2  = 3.94, P < 0.05), with a higher ratio in the Pearl River Delta region (Table 1). Age at disease onset differed significantly between the Pearl River Delta and non-Pearl River Delta regions (F = 31.51, P < 0.001), with an older age at disease onset in the Pearl River Delta region (Table 2).

Discussion

According to our study, the incidence of oral cancer differs by sex, age, blood type, life style, and economic condition.

The incidence of oral cancer in males was significantly higher than that in females. The male-to-female ratio is 10.5 in Taiwan, China [7] and 1.42 in the United States [8]. The male-to-female ratio in the present study was approximately two. This disparity may result from sex differences in exposure to risk factors for oral cancer [8, 9]. For example, men generally consume more alcohol and cigarettes than women.

In the present study, the male-to-female ratio showed a slightly downward trend, and the percentage of female oral cancer patients gradually increased from 32.2% in 1960s to 35.3% now. Other investigators have reported similar findings. For example, the worldwide epidemiologic study of oral cancer by Warnakulasuriya et al. [9] found that the male-to-female ratio of oral cancer had decreased in recent decades, which might be associated with changes in the degree of exposure to risk factors.

In our study, half the patients were between 45 and 64 years old. This result is consistent with most other reports. For example, Wen et al. [10] reported that the highest prevalence was between the ages of 41 and 60 years.

In the present study, over approximately 50 years, the percentage of younger patients with oral cancer gradually decreased, whereas the percentage of older patients gradually increased. This change may be explained by the fact that, in recent decades, the Chinese economy has been rapidly expanded and living conditions have been rapidly improved. Additionally, due to the implementation of family planning policies, the size of the aging population has increased, with a consequent increase in the proportion of older people in the population. Increased life span, resulting from the improved living conditions, has further increased this proportion. Therefore, the increase in the proportion of older patients may not reflect an actual increase in the incidence in older people.

The most common tumor sites of oral cancer in the United States are the tongue, alveolus, and lips [11]. Data from Southeast China showed that the three most common locations were the tongue, floor of the mouth, and gingiva in males and the tongue, buccal mucosa, and gingiva in females [12]. In the present study, we found that two-thirds of tumors were on the tongue, followed by the gingiva, hard palate, buccal mucosa, floor of the mouth, lips, and retromolar area.

As in most other reports, our study also found that the cancer type with the highest incidence was squamous cell carcinoma, which accounted for nearly 90% of cancers. In West China, approximately two-thirds of oral and maxillofacial malignant tumors were squamous cell carcinomas [10]. Other common types in our study were malignant lymphoma, mucoepidermoid carcinoma, adenoid cystic carcinoma, and adenoma. However, we found fewer lymphomas than that reported in West China, perhaps because we excluded cases of cancer in the oropharynx, which includes locations such as the tonsils, soft palate, and root of the tongue.

Many reports have shown that the ABO blood type system is associated with the development of cancers. Type A has been associated with gastric [1315], pancreatic [1619], ovarian [16, 20], esophageal [21], salivary gland [21], and breast cancers [16], whereas type B has been associated with esophageal [22, 23] and laryngeal cancers [21]. Some reports showed that people with blood type O have lower risks for lung [24], endometrial [25], pancreatic [26], renal cell [27], and ovarian cancers [28], and colorectal adenocarcinoma [29]. However, we found no studies that assessed the association between blood type and oral cancer. We combined the data for types A, B, and AB (type other) and compared the proportions of blood types for our patients with control data from a representative sample of the Guangdong population published by Chen et al. [30]. Of our patients, 1519 had type O and 2313 had type other, whereas in the control group, 10,702 had type O and 14,210 had type other. The proportion of oral cancer patients with type O blood was significantly lower than that of controls (χ 2  = 14.97, P < 0.001).

In this study, almost 90% of our patients were Cantonese. There are three major subcultural areas in Guangdong province: Guangfu, Hakka, and Chaoshan. The dialects, diets, and living habits in these three areas differ markedly. The male-to-female ratio of oral cancer patients in the Chaoshan area was significantly higher than that in the Guangfu and Hakka areas, the possible reasons for which are as follows. Smoking and drinking are more prevalent in the Chaoshan area, with men more often addicted to drinking and smoking than women. It is well known that drinking [31, 32] and smoking [31, 3335] promote the development and progression of oral cancer. In addition, in most families in the Chaoshan area, men are absolutely dominant; therefore, if women experience symptoms, they might remain silent, or their complaint may not receive enough attention from family members, leading to lower diagnosis and treatment rates in large hospitals.

The age of onset in patients from the Guangfu area was older than that of the other two areas. It is possible that the lifestyle habits of people in Hakka and Chaoshan more likely lead to early exposure to carcinogenic factors. For example, Chaoshan people like to drink very hot Kungfu tea (often approximately 75 °C or 167 °F). Hakka cuisine also stresses that food should be eaten when it is hot. Eating very hot food or tea has been reported to increase the risk of gastrointestinal tumors through mucosal damage, inflammatory factors, and heat shock protein activity [36, 37]. The high incidence of esophageal cancer and laryngeal cancer in this area might be associated with this habit. Hakka cuisine uses more salt and oil. Excessive salt or oil intake is associated with the development of tumors [38]. Chaoshan people like pickled food, fish sauce, and barbecued food, which are considered to have cancer-promoting effects [38, 39]. The prevalence of smoking and drinking in the Chaoshan area could also significantly increase the incidence of oral cancer.

The Pearl River Delta region is markedly more economically developed than the rest of Guangdong province. The male-to-female ratio of oral cancer patients in the non-Pearl River Delta region was significantly higher than that in the Pearl River Delta region, possibly because bad health habits, such as drinking and smoking, were more common in people, mainly males, in the economically underdeveloped regions.

The mean age of disease onset in the Pearl River Delta region was higher than that in the non-Pearl River Delta region. It is possible that people in the economically underdeveloped regions had a higher chance of encountering carcinogenic factors at an early age than those in the developed regions. For example, a poor working environment [40], poor nutritional status and developmental retardation [36, 41], a low education level [38], low awareness of dental care and poor oral hygiene [42], common poor health habits (such as excessive drinking and smoking), few physical examinations for cancer prevention, and low levels of medical care [40] would affect the age distribution of oral cancer patients.

This study design is a retrospective single center analysis, so an unavoidable problem is missing data. We drew conclusions about the epidemiologic features of oral cancer in different areas from some indirect evidence. Prospective controlled studies need be carried out to support our conclusions.

Conclusions

We infer from our data that during the process of screening for oral cancer, clinicians should pay attention to middle-aged and older people, men, and individuals with non-O blood type. Physicians should pay attention to every corner of the oral cavity and focus on examining sites of predilection. To help prevent the development of oral cancer, targeted information should be disseminated to encourage residents to change poor lifestyle habits. We should also appeal to the government to increase investment in medical care in economically underdeveloped regions.

Notes

Declarations

Authors’ contributions

JZ participated in the design of the study and drafted the manuscript. FG carried out the data interpretation and took part in the study design. AY and WC participated in conceiving the study. SC and HL carried out the data collection and participated in the design of the study. XZ and ZY participated in the data collection. XC performed the statistical analysis and participated in the design of the study. MS conceived and designed the study, and directed the writing of the manuscript. All authors read and approved the final manuscript.

Acknowledgements

This study was supported by grants from the National Natural Science Foundation of China (No. 81172568).

Competing interests

The authors declare that they have no competing interests.

Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Authors’ Affiliations

(1)
State Key Laboratory of Oncology in South China, Collaborative Innovation Center of Cancer Medicine, Sun Yat-sen University Cancer Center
(2)
Department of Head and Neck Surgery, Sun Yat-sen University Cancer Center
(3)
Department of Intensive Care, Sun Yat-sen University Cancer Center
(4)
Department of Preventive Medicine and Biostatistics, School of Basic Medical Science, Guangzhou Higher Education Mega Center, Guangzhou University of Chinese Medicine

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