Iranian Journal of Medical Sciences

Document Type : Original Article(s)

Authors

1 Endocrinology and Metabolism Research Center, Shiraz University of Medical Sciences, Shiraz, Iran

2 Department of Pathology, School of Medicine, Shiraz University of Medical Sciences, Shiraz, Iran

Abstract

Background: The role of human papillomavirus (HPV), as a common infection, has been evaluated in many cancers such as the cervix and squamous cell carcinoma of the head and neck. To the best of our knowledge, for the first time, the association of HPV with papillary thyroid carcinoma (PTC) and its pathologic features are investigated.
Methods: A retrospective cross-sectional study was conducted from May 2014 to January 2018 in several hospitals affiliated to Shiraz University of Medical Sciences, Shiraz, Iran. Thyroid tissue specimens of patients diagnosed with PTC (n=82) and benign thyroid nodules (n=77) were collected using the consecutive sampling method. The presence of HPV in PTC, adjacent normal tissue, and benign thyroid nodules was evaluated using the polymerase chain reaction (PCR) method. The frequency of HPV positivity in PTC tissues was compared with benign thyroid nodules and adjacent normal tissue. Association of pathologic features of PTC with HPV positivity was also investigated. Data were analyzed using SPSS version 21.0, and P values less than 0.05 were considered statistically significant.
Results: HPV PCR positivity was observed in 3.8% of benign thyroid nodules and 13.4% of PTC samples but in none of the adjacent normal tissues. After adjustment for age and sex, the prevalence of HPV PCR positivity in the PTC tissues was significantly more than the benign thyroid nodules (P=0.015). The prevalence was also significantly higher than the adjacent normal tissues (p <0.001).
Conclusion: There was a significant association between PTC and HPV positivity. Further studies are required to determine the cause and effect of the association between these two conditions.

Keywords

What’s Known

Known risk factors for the development of papillary thyroid carcinoma are exposure to ionizing radiation, high iodine intake, autoimmune thyroid diseases, and genetic predisposition. The role of parvovirus B19, herpesvirus, and polyomavirus in the pathogenesis of papillary thyroid carcinoma has been suggested. Human papillomavirus causes various cancer types.

What’s New

For the first time, we demonstrated the presence of human papillomavirus DNA in thyroid tissue and its association with papillary thyroid carcinoma.

Introduction

Papillary thyroid carcinoma (PTC) is the most common thyroid malignancy comprising 50-90% of the differentiated (follicular cell) thyroid carcinomas. 1 Despite many research studies, the etiology of this common thyroid malignancy remains unclear. 2 Possible risk factors for PTC are exposure to ionizing radiation, high iodine intake, autoimmune thyroid disease, and genetic predisposition. 2 The role of parvovirus B19 in the pathogenesis of PTC has also been suggested. 3 , 4 A study reported the presence of a high proportion of parvovirus B19 nucleic acids and proteins in PTC tissues. 3 In addition, a correlation between parvovirus B19 and all types of thyroid cancer has been reported. 4 A probable effect of parvovirus B19 on the activation of nuclear factor-kappa light chain enhancer of activated B cells (NF-kB ) has been indicated as a factor in the pathogenesis of PTC. 4 In contrast to previous studies, Adamson and others reported no association between parvovirus B19 and PTC. 5 A recent study, however, showed that thyroid cancer tissues harbored viral DNA or viral gene products of both the polyoma and herpes family viruses. 6

Human papillomavirus (HPV) is a non-enveloped, double-stranded DNA virus from the papillomavirus family, which has more than 170 HPV genotypes. 7 , 8 HPV is divided into two groups, based on the ability to cause neoplastic transformation, first is the benign type and the second is high-risk HPV types (HPV 16, 18, 31, 33, 35, 45, 51, 52, and 56). 9 They play an important role in cancers of the anus and genital organs. 9 A previous study has shown that persistent HPV infection can lead to precancerous lesions. 10 Recently, HPV has been implicated in head and neck carcinomas, especially oropharyngeal cancer. 7 HPV was detected in 25% of the head and neck squamous cell carcinoma cases. 11 In addition, it is suggested that HPV vaccines can have a significant health benefit in preventing oropharyngeal cancers. 11 However, it is unclear whether this virus can also play a role in other cancers of the head and neck, such as thyroid cancer. 10 , 11

Despite a relatively high prevalence of thyroid cancer and the availability of HPV vaccines for cancer prevention, studies on the role of HPV infection in thyroid cancers are scarce. The present study aimed to evaluate the association between HPV infection and PTC in comparison with benign thyroid nodules and normal thyroid tissues. In addition, the association between HPV infection and PTC severity was evaluated using tumor staging criteria and pathologic features. To the best of our knowledge, this is the first time such a study has been conducted.

Materials and Methods

A retrospective cross-sectional study was conducted from May 2014 to January 2018 in hospitals affiliated to Shiraz University of Medical Sciences, Shiraz, Iran. The study was approved by the Ethics Committee of Shiraz University of Medical Sciences (code: IR.SUMS.REC.1396 S90).

Sample Size

In the absence of any previous studies on the association between PTC and HPV, data from studies on the association between PCT and other viruses were used. The sample size was calculated (95% confidence interval, 5% significance level) using the MedCalc statistical software (Ver. 19.1.7; Med Calc software Ltd., Ostend, Belgium).

The calculated sample size was 44 for each group, but it was increased to 82 PTC samples and 77 benign thyroid nodules.

Tissue Samples

Thyroid tissue specimens from patients diagnosed with PTC and benign thyroid nodules were collected using the consecutive sampling method. A total of 175 paraffin-embedded thyroid tissues with the diagnosis of PTC and benign thyroid nodules were collected. All thyroid tissues were re-examined by two expert thyroid pathologists to confirm the diagnosis. Medical records of the patients were evaluated to exclude samples from patients, who were immunocompromised, had a history of head and neck radiation or underwent chemotherapy. Accordingly, 16 samples from patients with Hashimoto thyroiditis or Graves’ disease were excluded from the study. Eventually, 82 PTC and 77 benign thyroid nodules (adenomatous and colloid nodules) specimens were included. In PTC specimens, samples from adjacent normal non-tumoral thyroid tissue were also taken. The data was anonymized throughout the study using irreversible encryption.

Tumor Staging and Pathologic Criteria

In accordance with the classification by the World Health Organization (WHO), 12 PTC histological types were classified into six groups: classic, encapsulated follicular, infiltrative follicular, tall cell, cribriform, and diffuse sclerosing variants. Tumor staging was determined according to the American Joint Committee on Cancer and tumor-node-metastasis staging system. 13 Pathologic features were evaluated according to the criteria specified by the College of American pathologists. 14

Sample Preparation and Analysis

Tissue specimens were cut in 7 µm thickness, deparaffinized in xylene (GeNet Bio, South Korea), and then washed in ethanol (GeNet Bio, South Korea). DNA extraction was performed using the PrimePrep Genomic DNA isolation kit (GeNet Bio, South Korea).

All DNA samples were amplified with both primer pairs as described in table 1. The first-round polymerase chain reaction (PCR) amplification was as follows: 12.5 µL Taq 2X Master Mix (BioFact, South Korea), 0.4 µm of each MY09 and MY11 primers (Metabion, Germany), 20 ng of DNA, and up to 25 µL PCR-grade water. The second-round PCR (nPCR) was carried out using GP5+/6+ primers and a housekeeping gene (β-actin) to assess DNA integrity with forward primer 5`-ATCATGTTGAGACCTCCAA-3`and reverse primer 5`-CATCTCTTGCTCGAAGTCCA-3`. The nPCR reaction contained 12.5 µL Taq 2X Master Mix, 0.3 µm of each Gp5+/6+ primers, 0.2 µm of each of the forward and reverse β-actin primers, 2 µL of PCR product of the first-round PCR, and 8 µL of the PCR-grade water. All PCR amplifications were performed on a 96-well thermal cycler (Applied Biosystems, Foster, CA, USA) using a PCR.

Name Sequence (5’-3’) Size (base pair)
MY9 GTCCMARRGGAWACTGATC 450
MY11 GCMCAGGGWCTATAAYAATGG
GP5+ TTTGTTACTGTGGTAGATACYAC 140
GP6+ GAAAAATAAACTGTAAATCATATTC
Table 1.Human papillomavirus nested polymerase chain reaction primer sequences

PCR products were electrophoresed on a 2.5% agarose gel (BioFact, South Korea)in 1X TAE buffer (BioFact, South Korea), stained with gel Red EcoDyeTM Nucleic Acid Staining Solution (BioFact, South Korea), and visualized with a UV trans-illumination (UVItec Ltd, UK). The DNA amplification was 450 bp for the first-round PCR, 150 dp for the nPCR, and 317 dp for the β-actin gene. Uterine cervix tissue of a known HPV positive specimen, earlier analyzed during nPCR, was used as a positive tissue control to evaluate the success of the amplification. Blood samples of babies suspicious of kala-azar were used as negative controls (figure 1).

Figure 1. Agarose gel electrophoresis image of common human papillomavirus DNA in a nested multiplex polymerase chain reaction in a papillary thyroid cancer specimen. The length of amplicons generated with MY09/011* primers is 450 base pairs, GP05/06* is 150 base pairs, and β-actin primers 317 base pairs in size. Lane 1 is distilled water control. Distilled water in place of the DNA template was used as a negative control. Lane 2 is a negative control sample (317 base pairs β-actin) for the true negative result of common human papillomavirus detection. Lanes 5-6 are positive samples for first and nested human papillomavirus polymerase chain reaction and β-actin. Lanes 7 and 9 are positive samples for the nested and β-actin polymerase chain reaction. Lane 8 is positive control consisted of DNA from vaginal condyloma acuminatum. Lanes 10, 11, 13 are negative samples for the first and nested human papillomavirus polymerase chain reaction. Lane 12 is DNA Ladder: 50 base pairs. *MY09/011 and GP05/06 are primers for the detection of human papillomavirus in the polymerase chain reaction.

Statistical Analysis

Data were analyzed using SPSS software (version 21.0, Chicago, IL, USA). HPV positive tests were compared in two groups of PTC and thyroid nodule, and PTC and adjacent normal tissue using Chi-squared and Fisher’s exact tests. These tests were also used to evaluate the association between the qualitative pathologic features of PTC and the presence of HPV. The independent sample t test was used to compare quantitative variables such as age and tumor diameter. P values less than 0.05 were considered statistically significant.

Results

Of the 159 samples, 77 tissue specimens were benign thyroid nodules and 82 were PTC. A total of 30 samples were from male patients and 129 from female patients. The benign thyroid nodules are composed of 32 colloids (42%) and 45 (58%) adenomatous nodules ( table 2). The prevalence of HPV PCR positivity in the PTC tissues was significantly higher than the benign thyroid nodules. Logistic regression analysis (“enter” method) was used to eliminate age and sex as the two probable confounding factors ( table 3). The results showed that the prevalence of HPV positive PCR in the PTC group remained significantly higher than the benign thyroid nodules group (P=0.015). HPV was not detected in any adjacent normal non-tumoral thyroid tissue samples and the difference with the PTC group was significant (P<0.001).

Variable PTC N (%) Thyroid nodule N (%) Total P value
82 (51.5) 77 (48.5) 159 (100) -
Sex Male 21 (25.6) 9 (11.6) 30 (18.8) 0.025*
Female 61 (74.4) 68 (88.3) 129 (81.2)
HPV+ 11 (13.4) 3 (3.8) 14 (8) 0.034*
Age (year) 40.7±14.9§ 46.9±13.3§ - 0.006**
*Chi-squared test, **Independent sample t test, §Mean±standard deviation; PTC: Papillary thyroid carcinoma, HPV: Human papillomavirus
Table 2.Comparison of sex, age, and human papillomavirus positivity in specimens with papillary thyroid carcinoma and benign thyroid nodule
Variables Regression coefficient Wald test result P value Odds ratio 95% confidence interval
Lower Upper
Age -0.34 6.97 0.008 0.96 0.94 0.99
Sex -1.10 5.66 0.017 0.33 0.13 0.82
HPV 1.56 4.76 0.029 4.77 1.17 19.40
Constant 2.26 9.54 0.002 9.63
HPV: Human papillomavirus
Table 3.The results of logistic regression analysis

The association between the pathologic characteristics of patients with PTC and HPV positivity was evaluated ( table 4). Although the positive rate (%) of mitosis, lymph node involvement, capsular invasion, and tumor diameter in HPV positive PTC was higher than HPV negative PTC, it was not significant. By comparing the prevalence of HPV positivity in benign thyroid nodules and normal thyroid tissue, no significant association between HPV presence and benign thyroid nodules was observed (P=0.11).

Pathologic characteristics HPV-positive papillary cancer N (%) HPV-negative papillary cancer N (%) Total P value
11 (13) 71 (87) 82 (100) -
Mitosis 2 (18.2) 6 (8.5) 8 (10) 0.291*
Atypia 0 (0) 6 (8.5) 6 (7) 0.409*
Encapsulation 8 (72.7) 41 (57.7) 49 (60) 0.346*
Capsular invasion 7 (87.5) 22 (53.6) 29 (35) 0.07*
Lymph vessel invasion 3 (27.3) 19 (26.8) 22 (27) 0.613*
Blood vessel invasion 3 (27.3) 16 (22.5) 19 (23) 0.495*
Extra thyroid extension 1 (9.1) 11 (15.5) 12 (15) 0.495*
Surgical margin involvement 0 (0) 7 (9.9) 7 (8.5) 0.35*
Multi-center tumor 3 (27.3) 16 (22.5) 19 (23) 0.496*
Lymph node involvement 2 (18.2) 8 (11.3) 10 (12) 0.401*
Diameter of tumor (mm) 32.3±11.4§ 29.5±18.5§ - 0.295**
*Chi-squared and Fisher test, **Independent sample t test, §Mean±SD; N (%): Number (percentage), HPV: Human papillomavirus
Table 4.Association between human papillomavirus polymerase chain reaction positive results and pathologic characteristics of patients with papillary thyroid carcinoma

Fifty-six percent of PTC were classic type, 23.2% were follicular variant, and 14.6% were micropapillary carcinoma. The prevalence of oncocytic, sclerosing, Warthin tumor, and tall cell types was 2.4%, 1.2%, 1.2%, and 1.2%, respectively. There was no significant association between the PTC types and HPV positivity (P=0.384). Of all PTC tissue samples, 72% were in stage І, 13.4% in stage ІІ, 13.4% in stage ІІІ, and 1.2% in stage IV. Of the 71 HPV negative samples, 51 (71.8%) were in stage І, 9 (12.6%) in stage ІІ, 10 (14%) in stage ІІІ, and 1 (1.4%) in stage IV. In 11 HPV positive samples, the numbers and frequencies in stages І, ІІ, ІІІ, and IV were 8 (72.7%), 2 (18.1%), 1 (9%), and 0 (0%), respectively. There was no significant association between HPV positivity and tumor staging (P=0.728).

Discussion

To the best of our knowledge, this is the first study that evaluated the association between HPV infection and PTC, as well as PTC severity, based on tumor staging and pathologic features. An association between HPV and PTC was found, and HPV was more significantly present in tissues involved with PTC than the benign thyroid nodules and normal thyroid tissues. This association was independent of age and sex. In addition, there was a trend in favor of capsular invasion in HPV positive PTC, but this association was not statistically significant.

Several factors, such as viral infections, might be involved in the development of PTC. 2 Previous studies have suggested a possible role of parvovirus B19, herpesvirus, and polyomavirus. 3 - 5 In the present study, we demonstrated a probable role of HPV as a newly identified risk factor for the development of some PTC cases. Some studies have shown the role of HPV in the pathogenesis of cancer, especially oropharyngeal, anogenital, and head and neck cancers. 7 , 10 The reported prevalence of oral HPV infection in healthy adults is 4.5%. However, this rate is higher in human immunodeficiency virus-infected patients. 10 It has been shown that the prevalence is higher in men, particularly in older adults. 10 Two studies have shown that primary tumors in HPV-positive head and neck squamous cell carcinoma (HNSCC) were loco-regionally more advanced and had extended lymph node involvement. 15 , 16 Although these tumors were more aggressive than the HPV-negative HNSCC, patients had better survival and better response to treatment. 15 , 17 - 19 Keller and others showed the possible role of HPV in HNSCC of unknown origin. 20 They also showed an association between HPV infection and tumor staging and extra-capsular extension. Masand and others reported the role of HPV in some cases of adenosquamous carcinoma of the head and neck and concluded that this subset of patients had better survival. 21 Hartley and others did not find any association between small cell neuroendocrine carcinoma of the lung and HPV infection in high-risk HPV population. 22

Another group of studies evaluated the effect of HPV in genital carcinomas. 23 - 25 Based on epidemiologic and molecular studies, persistent infection with high-risk HPV variants is the leading cause of uterine cervical cancer. 23 Ghedira and others showed an association between infection with high-risk variants of HPV and squamous intraepithelial lesions of the cervix in Tunisian women. 24 Another study in the United States showed the association between HPV infection and penile carcinogenesis. 25 However, Fonseca and others found no correlation between HPV infection and histological findings suggestive of poor prognosis or lymph metastasis in penile carcinoma. 26 Frega and others revealed that HPV-mRNA, as a marker of persistent HPV infection, is a risk factor for the onset of metachronous lesions in intraepithelial neoplasm of the lower female genital tract. 27

HPVs are epithelial viruses, which spread through respiratory secretion by close mucosal or skin contact. 9 , 10 They can also be transferred by peripheral blood mononuclear cells, 28 and as in our study, may reach the thyroid through the blood. Multiple mechanisms such as gene mutation and gene structural alteration are suggested for HPV tumorigenesis. 10 , 15 For instance, some HPV-associated tumors reveal an E2F1 amplification (20q1), which is necessary for cell cycle proliferation. Another important structural change in HPV infection is the deletion of TRAF3, that occurs in about 20% of HPV-associated tumors. This gene plays an important role in antiviral immunity and is a regulator for NF-kB. Therefore, HPV may play a role in the activation of NF-kB in PTC. 15 NF-kB regulates genes involved in cell growth and proliferation. 29 In thyroid cancer cells, the activity of NF-kB is increased and may be involved in thyroid carcinogenesis. 29

In the present study, for the first time, we showed the presence of HPV DNA in thyroid tissue, and an association between PTC and HPV. The main limitations of our study were the lack of resources and laboratory equipment, and the fact that we did not use other methods for HPV detection (e.g., immunohistochemistry, in situ hybridization). These may have resulted in an underestimation of HPV positivity rates in our samples. Considering that PTC is a common thyroid carcinoma, and HPV vaccines are currently available and have shown to be effective in preventing some HPV-associated cancers, further studies in this field are strongly recommended.

Conclusion

For the first time, a link between HPV and some cases of PTC was established. However, the role of infection in cancer initiation could not be proven. Further studies with large sample size and among different populations are required to determine the exact role of HPV in the pathogenesis of PTC.

References

  1. Davies L, Welch HG. Current thyroid cancer trends in the United States. JAMA Otolaryngol Head Neck Surg. 2014; 140:317-22. DOI | PubMed
  2. Khodamoradi F, Ghoncheh M, Mehri A, Hassanipour S, Salehiniya H. Incidence, Mortality, and Risk Factors of Thyroid Cancer in the World: A Review. World Cancer Research Journal. 2018; 5:e1093.
  3. Wang JH, Zhang WP, Liu HX, Wang D, Li YF, Wang WQ, et al. Detection of human parvovirus B19 in papillary thyroid carcinoma. Br J Cancer. 2008; 98:611-8. Publisher Full Text | DOI | PubMed
  4. Etemadi A, Mostafaei S, Yari K, Ghasemi A, Minaei Chenar H, Moghoofei M. Detection and a possible link between parvovirus B19 and thyroid cancer. Tumour Biol. 2017; 39:1010428317703634. DOI | PubMed
  5. Adamson LA, Fowler LJ, Ewald AS, Clare-Salzler MJ, Hobbs JA. Infection and persistence of erythrovirus B19 in benign and cancerous thyroid tissues. J Med Virol. 2014; 86:1614-20. DOI | PubMed
  6. Stamatiou DP, Derdas SP, Zoras OL, Spandidos DA. Herpes and polyoma family viruses in thyroid cancer. Oncol Lett. 2016; 11:1635-44. Publisher Full Text | DOI | PubMed
  7. Spence T, Bruce J, Yip KW, Liu FF. HPV Associated Head and Neck Cancer. Cancers (Basel). 2016; 8Publisher Full Text | DOI | PubMed
  8. Bzhalava D, Guan P, Franceschi S, Dillner J, Clifford G. A systematic review of the prevalence of mucosal and cutaneous human papillomavirus types. Virology. 2013; 445:224-31. DOI | PubMed
  9. Bansal A, Singh MP, Rai B. Human papillomavirus-associated cancers: A growing global problem. Int J Appl Basic Med Res. 2016; 6:84-9. Publisher Full Text | DOI | PubMed
  10. Ljubojevic S, Skerlev M. HPV-associated diseases. Clin Dermatol. 2014; 32:227-34. DOI | PubMed
  11. D’Souza G, Dempsey A. The role of HPV in head and neck cancer and review of the HPV vaccine. Prev Med. 2011; 53 Suppl 1:S5-S11. Publisher Full Text | DOI | PubMed
  12. Cameselle-Teijeiro JM, Sobrinho-Simoes M. New WHO classification of thyroid tumors: a pragmatic categorization of thyroid gland neoplasms. Endocrinol Diabetes Nutr. 2018; 65:133-5. DOI | PubMed
  13. Tuttle RM, Haugen B, Perrier ND. Updated American Joint Committee on Cancer/Tumor-Node-Metastasis Staging System for Differentiated and Anaplastic Thyroid Cancer (Eighth Edition): What Changed and Why?. Thyroid. 2017; 27:751-6. Publisher Full Text | DOI | PubMed
  14. Lam E, Vy N, Bajdik C, Strugnell SS, Walker B, Wiseman SM. Synoptic pathology reporting for thyroid cancer: a review and institutional experience. Expert Rev Anticancer Ther. 2013; 13:1073-9. DOI | PubMed
  15. Vokes EE, Agrawal N, Seiwert TY. HPV-Associated Head and Neck Cancer. J Natl Cancer Inst. 2015; 107:djv344. DOI | PubMed
  16. Chatfield-Reed K, Gui S, O’Neill WQ, Teknos TN, Pan Q. HPV33+ HNSCC is associated with poor prognosis and has unique genomic and immunologic landscapes. Oral Oncol. 2020; 100:104488. DOI | PubMed
  17. Ozcan-Wahlbrink M, Schifflers C, Riemer AB. Enhanced Radiation Sensitivity of Human Papillomavirus-Driven Head and Neck Cancer: Focus on Immunological Aspects. Front Immunol. 2019; 10:2831. Publisher Full Text | DOI | PubMed
  18. O’Rorke MA, Ellison MV, Murray LJ, Moran M, James J, Anderson LA. Human papillomavirus related head and neck cancer survival: a systematic review and meta-analysis. Oral Oncol. 2012; 48:1191-201. DOI | PubMed
  19. Kaka. , Kirsch CM, Old MO, et al. Highly aggressive human papillomavirus-related oropharyngeal cancer: clinical, radiologic, and pathologic characteristics. Oral Surg Oral Med Oral Pathol Oral Radiol 2013; 116:327-35. Publisher Full Text | DOI | PubMed
  20. Keller LM, Galloway TJ, Holdbrook T, Ruth K, Yang D, Dubyk C, et al. p16 status, pathologic and clinical characteristics, biomolecular signature, and long-term outcomes in head and neck squamous cell carcinomas of unknown primary. Head Neck. 2014; 36:1677-84. Publisher Full Text | DOI | PubMed
  21. Masand. Adenosquamous carcinoma of the head and neck: relationship to human papillomavirus and review of the literature. Head Neck Pathol. 2011; 5:108-16. Publisher Full Text | DOI | PubMed
  22. Hartley CP, Steinmetz HB, Memoli VA, Tafe LJ. Small cell neuroendocrine carcinomas of the lung do not harbor high-risk human papillomavirus. Hum Pathol. 2015; 46:577-82. DOI | PubMed
  23. Crosbie EJ, Einstein MH, Franceschi S, Kitchener HC. Human papillomavirus and cervical cancer. Lancet. 2013; 382:889-99. DOI | PubMed
  24. Ghedira R, Mahfoudh W, Hadhri S, Gabbouj S, Bouanene I, Khairi H, et al. Human papillomavirus genotypes and HPV-16 variants distribution among Tunisian women with normal cytology and squamous intraepithelial lesions. Infect Agent Cancer. 2016; 11:61. Publisher Full Text | DOI | PubMed
  25. Hernandez BY, Goodman MT, Unger ER, Steinau M, Powers A, Lynch CF, et al. Human papillomavirus genotype prevalence in invasive penile cancers from a registry-based United States population. Front Oncol. 2014; 4:9. Publisher Full Text | DOI | PubMed
  26. Fonseca AG, Soares FA, Burbano RR, Silvestre RV, Pinto LO. Human Papilloma Virus: Prevalence, distribution and predictive value to lymphatic metastasis in penile carcinoma. Int Braz J Urol. 2013; 39:542-50. DOI | PubMed
  27. Frega A, Sesti F, Sopracordevole F, Biamonti A, Votano S, Catalano A, et al. Multiple intraepithelial neoplasias of the lower female genital tract: the reliability of HPV mRNA test. J Low Genit Tract Dis. 2014; 18:174-81. DOI | PubMed
  28. Bodaghi S, Wood LV, Roby G, Ryder C, Steinberg SM, Zheng ZM. Could human papillomaviruses be spread through blood?. J Clin Microbiol. 2005; 43:5428-34. Publisher Full Text | DOI | PubMed
  29. Giuliani C, Bucci I, Napolitano G. The Role of the Transcription Factor Nuclear Factor-kappa B in Thyroid Autoimmunity and Cancer. Front Endocrinol (Lausanne). 2018; 9:471. Publisher Full Text | DOI | PubMed