There are large disparities in relative survival among patients with HPV‐associated cancers by sex, race, and age. HPV vaccination and improved access to screening (of cancers for which screening tests are available) and treatment, especially among groups that experience higher incidence and lower survival, may reduce disparities in survival from HPV‐associated cancers. Cancer 2018;124:203‐211. Published 2017. This article is a U.S. Government work and is in the public domain in the USA.

The 5‐year age‐standardized relative survival rate was 64.2% for cervical carcinomas, 52.8% for vaginal squamous cell carcinomas (SCCs), 66% for vulvar SCCs, 47.4% for penile SCCs, 65.9% for anal SCCs, 56.2% for rectal SCCs, and 51.2% for oropharyngeal SCCs. Five‐year relative survival was consistently higher among white patients compared with black patients for all HPV‐associated cancers across all age groups; the greatest differences by race were observed for oropharyngeal SCCs among those aged <60 years and for penile SCCs among those ages 40 to 49 years compared with other age groups.

The authors examined high‐quality data from 27 population‐based cancer registries covering approximately 59% of the US population. The analyses were limited to invasive cancers that were diagnosed during 2001 through 2011 and followed through 2011 and met specified histologic criteria for HPV‐associated cancers. Five‐year relative survival was calculated from diagnosis until death for these cancers by age, race, and sex.

Human papillomavirus (HPV) vaccines can potentially prevent greater than 90% of cervical and anal cancers as well as a substantial proportion of vulvar, vaginal, penile, and oropharyngeal cancers caused by certain HPV types. Because more than 38,000 HPV‐associated cancers are diagnosed annually in the United States, current studies are needed to understand how relative survival varies for each of these cancers by certain demographic characteristics, such as race and age.

INTRODUCTION Human papillomavirus (HPV) infection is the most common sexually transmitted infection among men and women in the United States, with approximately 14 million new infections occurring each year.1 Persistent infections with high‐risk HPV (including HPV types 16, 18, 31, 33, 45, 52, and 58) cause nearly all cervical cancers and a substantial proportion of other cancers.2, 3 HPV‐associated cancers can be defined as invasive cancers at anatomic sites (cervix, vulva, vagina, penis, oropharynx, anus, and rectum) with cell types in which HPV DNA is frequently identified—all carcinomas of the cervix, including adenocarcinomas and squamous cell carcinomas (SCCs), and SCCs only for the other anatomic sites. A recent genotyping study estimated that HPV DNA was present in 91% of cervical cancers, 75% of vaginal cancers, 69% of vulvar cancers, 91% of anal cancers, 63% of penile cancers, and 71% oropharyngeal cancers.4 However, cancer registries do not routinely collect information on the presence of HPV DNA in cancer tissues. Therefore, to estimate the number of cancers attributed to HPV, the Centers for Disease Control and Prevention (CDC) multiplied the number of HPV‐associated cancers by the percentage of each cancer type attributable to HPV based on the genotyping study. On the basis of these attributable fractions, 79% of the 38,793 “HPV‐associated cancers” diagnosed annually in the United States during 2008 through 2012 could be attributed to HPV.5 Many studies to date have focused on cervical cancers, because almost all of these cancers are associated with HPV infection. Furthermore, cervical and oropharyngeal cancers account for greater than one‐half of all HPV‐associated cancers.5 However, in recent years, considerable attention has been given to oropharyngeal cancers and the role of HPV infection in these cancers. Although many studies have focused on the incidence of HPV‐associated cancers, very few have examined survival, and most of these have focused on cervical and oropharyngeal cancers.3, 5-8 Survival reports on less common HPV‐associated cancers, such as vaginal, vulvar, penile, anal, and rectal malignancies, are lacking. Thus, to better understand survival in HPV‐associated cancers in the United States along with any disparities by sex, race, or age that may exist, the objective of this study was to examine survival among patients diagnosed with HPV‐associated cancers using data from the CDC's National Program of Cancer Registries (NPCR) from 2001 through 2011.

MATERIALS AND METHODS The NPCR data set includes cancer incidence data from central cancer registries funded by the NPCR in 45 states, the District of Columbia, and Puerto Rico.9 Data on all new diagnoses of cancer from patient records at such medical facilities as hospitals, physicians' offices, therapeutic radiation facilities, freestanding surgical centers, and pathology laboratories are reported to central cancer registries, which collate these data and use state vital records to collect information about any cancer deaths that were not reported as cases. The central cancer registries use uniform data items and codes as documented by the North American Association of Central Cancer Registries. These data are submitted annually in November to the CDC and are combined into 1 data set. Cancer registries demonstrate that data are of high quality by meeting US Cancer Statistics publication criteria. Information on primary site and histology is coded according to the International Classification of Diseases for Oncology, Third Edition and categorized according to the revised Surveillance, Epidemiology, and End Results (SEER) recodes dated January 27, 2003, which define standard groupings of primary cancer sites (available at; https://seer.cancer.gov/siterecode accessed December, 2016). The data include information about diagnostic confirmation of each case, including whether histologic type was determined by microscopic examination of tumor tissue. For the current analysis we used survival data for invasive cancer cases diagnosed during 2000 through 2011 using the NPCR November 2014 data submission.10 We limited our analysis to registries that met the NPCR data‐quality standards for inclusion in US Cancer Statistics publications11 and also performed active patient follow‐up or linkage with the National Death Index. These 27 registries represent 59% of the US population. We limited our analysis to invasive cancers that were microscopically confirmed and met specified histologic criteria for HPV‐associated cancers using the same framework as in prior studies.7, 12 Cancers were classified by anatomic site using International Classification of Diseases for Oncology, Third Edition codes.13 All epithelial carcinomas (histology codes 8010‐8671 and 8940‐8941) were included for cervical cancers (site codes C53.0‐C53.9).14 For other sites, we included SCCs (histology codes 8050‐8084 and 8120‐8131) for sites in the vulva (site codes C51.0‐C51.9), vagina (site code C52.9), penis (site codes C60.0‐60.9), anus and rectum (site codes C21.0‐C21.9 and C20.9), and certain subsites of the oropharynx (site codes C01.9, C02.4, C02.8, C05.1, C05.2, C09.0, C09.1, C09.8, C09.9, C10.0, C10.1, C10.2, C10.3, C10.4, C10.8, C10.9, C14.0, C14.2, and C14.8).5 Oropharyngeal subsites (including the base of tongue; pharyngeal tonsils, anterior and posterior tonsillar pillars, and glossotonsillar sulci; anterior surface of soft palate and uvula; and lateral and posterior pharyngeal walls) were based on sites in which HPV DNA is frequently identified.4, 5, 7, 12, 14-17 Although rectal SCC was not included in the genotyping study,4 we included it in this analysis, because recent studies indicate that rectal SCCs, although rare, are similar to anal SCCs and probably misclassified anal SCCs, and are likely to be HPV‐associated.3, 18 By using sex‐specific and state‐specific life tables for all races and black and white race from the National Center for Health Statistics, we calculated 5‐year relative survival percentages for patients diagnosed during 2001 through 2011 on all those who had follow‐up through 2011. Relative survival was defined as the ratio of the observed all‐cause survival in a group of individuals with cancer to the expected all‐cause survival of the general population. For this study, 5‐year relative survival was calculated using the Ederer II relative survival method.19 Relative survival was calculated for each of the HPV‐associated cancers by age at diagnosis, race, sex, and SEER Summary Stage 2000 (local, regional, distant). For patients who had multiple HPV‐associated cancers diagnosed during the study period, all cancers were included in the analysis. All analyses were age‐standardized using the International Cancer Survival Standard.20 Survival was calculated only for white and black racial groups, because expected life tables were not available for other racial/ethnic groups. SEER*Stat software version 8.3.2 was used for analysis.21 Survival estimates were calculated as a ratio and estimates with counts <25 suppressed. Formal statistical testing for pairwise comparisons was not performed to avoid multiple comparison problems. Ninety‐five percent confidence intervals (95% CIs) are provided to allow for informal comparisons of survival estimates. Although examining overlap between CIs to determine differences in estimates is conservative, the sample sizes from more than 10 years of national data are generally large for most groups.

RESULTS In total, 220,211 HPV‐associated cancers were diagnosed during 2001 through 2011, and the majority consisted of oropharyngeal SCCs (OPSCCs) and cervical carcinomas (36.4% and 36.1%, respectively) followed by anal SCCs (11.8%) (Table 1). When comparing survival by cancer site, 5‐year age‐standardized relative survival was highest for vulvar and anal SCCs (66% and 65.9%, respectively) and lowest for penile and oropharyngeal SCCs (47.4% and 51.2%, respectively) compared with other sites (Table 2). Table 1. Population Characteristics for Patients Diagnosed With Human Papillomavirus‐Associated Cancer: National Program of Cancer Registries, 2001‐2011 HPV‐Associated Cancers Total No. Total No. (%) % White % Women % Localized Stage at Diagnosisb Cervical carcinoma 79,425 36.1 77.2 100 47.1 Vaginal SCC 4871 2.2 80.9 100 37.5 Vulvar SCC 19,345 8.8 88.7 100 57.5 Penile SCC 6248 2.8 85.4 — 35.0 Anal SCC 26,026 11.8 86.3 63.6 50.8 Rectal SCC 4145 1.9 85.5 68.2 43.3 Oropharyngeal SCC 80,151 36.4 86.7 20.8 15.9 Total 220,211 100.0 83.0 32.7c 36.4 For many HPV‐associated cancers, 5‐year age‐standardized relative survival decreased with increasing age at diagnosis; however, we observed slightly increased survival for cancers diagnosed among those ages 40 to 49 years compared with those aged <40 years at the time of diagnosis for vaginal SCCs (66.6% and 62.7%, respectively), vulvar SCCs (85.9% and 84.5%, respectively), and anal SCCs (72.6% and 66.1%, respectively). Survival consistently decreased with increasing age for cervical carcinomas, penile SCCs, and OPSCCs (Table 2). The difference in 5‐year relative survival was at least 10% higher for those aged <40 years at the time of diagnosis compared with those aged ≥60 years at the time of diagnosis for all HPV‐associated cancers, with the exception of anal SCCs, in which the difference was <2% (Table 2). A greater percentage of cases were diagnosed at older ages for most cancer types, except cervical cancer (73% were diagnosed at age <60 years), anal cancer (53% were diagnosed at aged <60 years), and oropharyngeal cancer (51% were diagnosed at age <60 years). Table 2. Age‐Standardized 5‐Year Relative Survival for Human Papillomavirus‐associated cancers by Stage of Cancer at Diagnosis, Age, Race, and Sex: National Program of Cancer Registries, 2001‐2011 HPV‐Associated Total Localizedb Regionalc Distantd Cancers No. % Survival 95% CI No. % Survival 95% CI No. % Survival 95% CI No. % Survival 95% CI Cervical carcinomae 79,425 64.2 63.8‐64.7 37,449 86.0 85.3‐86.7 28,409 55.3 54.5‐56.1 9049 NA NA Age at diagnosis, yf <40 21,212 82.3 81.7‐82.9 13,493 94.0 93.5‐94.4 5460 64.3 62.9‐65.7 1120 23.7 20.9‐26.6 40‐49 21,159 74.2 73.5‐74.9 11,136 91.9 91.3‐92.5 7108 61.6 60.2‐62.8 2015 20.9 18.9‐23.0 50‐59 16,009 64.5 63.6‐65.4 6132 87.9 86.8‐88.9 6640 58.8 57.3‐60.2 2426 19.2 17.4‐21.1 ≥60 21,075 52.4 51.5‐53.3 6696 80.3 78.8‐81.7 9207 48.1 46.7‐49.4 3489 13.2 11.8‐14.7 Race White 61,061 64.8 64.2‐65.3 29,689 86.5 85.7‐87.3 21,348 55.6 54.7‐56.6 6784 NA NA Black 12,819 57.0 55.8‐58.1 5112 80.1 78.2‐81.8 5131 50.0 48.1‐51.9 1748 NA NA Vaginal SCCg 4871 52.8 50.9‐54.6 1829 65.7 62.7‐68.5 1786 53.7 50.6‐56.7 693 20.7 16.9‐24.7 Age at diagnosis, yf <40 165 62.7 54.1‐70.2 76 83.3 71.9‐90.3 58 48.4 33.2‐62.0 NR NR NR 40‐49 506 66.6 61.7‐71.1 210 78.5 71.2‐84.1 185 67.0 58.4‐74.1 65 22.9 12.0‐35.9 50‐59 909 62.5 58.6‐66.1 340 76.3 70.1‐81.3 337 60.9 54.3‐66.8 121 32.0 22.2‐42.3 ≥60 3298 46.4 44.0‐48.7 1204 59.3 55.2‐63.1 1206 48.7 44.8‐52.5 490 16.3 12.2‐21.1 Race White 3932 52.6 50.6‐54.6 1498 65.1 61.7‐68.2 1427 54.1 50.6‐57.4 559 19.9 15.8‐24.4 Black 745 50.8 46.1‐55.3 256 67.2 58.2‐74.7 297 51.1 43.3‐58.4 109 NA NA Vulvar SCCg 19,345 66.0 65.1‐67.0 11,125 79.0 77.7‐80.3 6561 52.5 50.9‐54.1 799 16.5 13.2‐20.2 Age at diagnosis, yf <40 1035 84.5 81.8‐86.9 692 91.9 89.1‐94.0 253 71.1 64.4‐76.8 35 26.3 11.3‐44.1 40‐49 2770 85.9 84.3‐87.4 1822 92.2 90.5‐93.7 755 75.9 72.0‐79.3 82 33.0 20.7‐45.8 50‐59 3468 79.8 78.1‐81.4 2103 88.7 86.8‐90.4 1103 70.4 67.0‐73.5 134 26.4 17.1‐36.6 ≥60 12,117 57.5 56.2‐58.8 6532 73.6 71.7‐75.4 4451 41.8 39.7‐43.8 548 10.9 7.8‐14.8 Race White 17,141 66.3 65.2‐67.3 9888 79.4 78.0‐80.7 5830 52.3 50.5‐54.0 690 17.0 13.4‐20.9 Black 1769 61.9 57.9‐65.6 988 71.1 65.2‐76.2 612 56.9 50.4‐62.8 93 15.0 8.1‐24.0 Penile SCCg 6248 47.4 45.7‐49.2 2184 66.6 63.4‐69.6 2251 41.2 38.3‐44.0 1320 26.7 23.3‐30.3 Age at diagnosis, yf <40 131 65.3 55.5‐73.4 51 87.5 71.0‐94.9 43 56.7 40.0‐70.3 NR NR NR 40‐49 560 56.6 51.6‐61.2 177 80.2 72.0‐86.3 205 51.1 43.0‐58.6 140 38.7 28.6‐48.6 50‐59 1487 51.2 48.1‐54.2 458 71.9 66.2‐76.9 601 47.1 42.4‐51.7 330 29.8 23.6‐36.3 ≥60 4076 45.3 43.1‐47.4 1500 63.3 59.3‐67.1 1403 39.9 36.4‐43.3 826 24.3 20.2‐28.6 Race White 5317 48.4 46.4‐50.3 1933 67.2 63.8‐70.3 1925 41.9 38.9‐44.9 1055 26.6 22.8‐30.8 Black 528 34.7 28.5‐41.0 110 57.8 37.9‐73.4 219 31.1 22.5‐40.1 160 22.0 13.4‐31.9 Anal SCCg 26,026 65.9 65.0‐66.9 13,215 77.6 76.2‐79.0 7841 58.5 56.6‐60.2 2521 31.7 29.0‐34.5 Age at diagnosis, yf <40 1111 66.1 62.8‐69.1 585 76.4 72.3‐80.0 331 58.3 52.1‐64.0 104 30.4 20.8‐40.5 40‐49 5072 72.6 71.2‐74.0 2582 82.6 80.8‐84.3 1612 65.3 62.5‐68.0 428 41.6 36.1‐46.9 50‐59 7703 72.5 71.2‐73.8 3923 82.5 80.8‐84.0 2339 66.8 64.3‐69.2 802 38.9 34.6‐43.2 ≥60 12,165 64.5 63.2‐65.7 6135 77.1 75.3‐78.7 3559 56.7 54.3‐59.0 1187 29.6 26.1‐33.2 Race White 22,472 66.5 65.5‐67.6 11,537 78.1 76.6‐79.5 6670 58.7 56.7‐60.5 2147 32.4 29.5‐35.3 Black 2971 61.8 57.9‐65.4 1412 73.3 67.3‐78.4 1001 56.9 50.2‐63.1 319 28.8 19.6‐38.6 Sex Women 16,541 69.3 68.1‐70.4 8260 80.2 78.5‐81.7 4976 63.4 61.2‐65.5 1763 36.8 33.5‐40.0 Men 9485 59.8 57.9‐61.7 4955 73.1 70.3‐75.7 2865 49.1 45.6‐52.5 758 18.6 14.5‐23.1 Rectal SCCg 4145 56.2 54.0‐58.3 1796 70.4 67.0‐73.6 976 53.7 49.2‐58.0 558 13.3 10.0‐17.1 Age at diagnosis, yf <40 136 65.9 56.9‐73.5 60 83.8 70.6‐91.4 28 50.5 30.1‐67.8 NR NR 40‐49 617 62.2 57.5‐66.4 268 78.0 71.5‐83.2 164 48.8 38.6‐58.3 83 34.3 22.9‐46.1 50‐59 1139 65.0 61.5‐68.3 483 76.3 71.1‐80.8 296 67.4 60.2‐73.6 156 14.1 7.8‐22.2 ≥60 2254 53.7 50.9‐56.5 985 68.8 64.3‐72.8 488 53.0 46.8‐58.9 300 10.5 6.5‐15.7 Race White 3539 57.2 54.9‐59.5 1558 70.6 67.0‐74.0 827 55.8 51.0‐60.4 461 14.5 10.7‐18.8 Black 505 46.6 39.7‐53.3 202 63.8 52.2‐73.3 129 41.6 27.2‐55.4 89 13.6 6.2‐24.0 Sex Women 2812 61.2 58.5‐63.7 1255 73.4 69.3‐76.9 686 58.0 52.8‐62.9 332 17.6 12.8‐23.0 Men 1333 45.5 41.6‐49.3 541 63.4 56.4‐69.6 290 40.1 31.7‐48.3 226 6.9 3.6‐11.6 Oropharyngeal SCCg 80,151 51.2 50.7‐51.8 12,738 59.4 58.1‐60.7 50,877 54.5 53.7‐55.3 13,162 30.8 29.6‐32.0 Age at diagnosis, yf <40 1603 73.4 70.9‐75.8 255 81.3 75.1‐86.2 1050 77.0 73.9‐79.7 233 48.4 40.6‐55.8 40‐49 11,714 69.1 68.1‐70.0 1481 77.5 74.9‐79.9 8054 72.9 71.7‐74.0 1738 43.4 40.6‐46.2 50‐59 28,053 64.2 63.5‐64.9 3668 71.4 69.5‐73.1 18,821 68.9 68.0‐69.7 4550 40.3 38.5‐42.1 ≥60 38,911 49.1 48.4‐49.8 7354 55.5 53.9‐57.1 22,979 53.3 52.4‐54.2 6642 30.0 28.5‐31.5 Race White 69,377 53.5 52.9‐54.1 11,136 60.5 59.1‐61.9 44,597 56.9 56.1‐57.7 10,822 33.2 31.9‐34.5 Black 8971 32.4 30.6‐34.1 1287 46.1 41.6‐50.4 5235 35.0 32.5‐37.4 2056 16.6 13.7‐19.7 Sex Women 16,694 49.8 48.8‐50.8 3676 60.0 57.8‐62.1 6919 51.1 49.7‐52.5 2572 29.9 27.6‐32.2 Men 63,457 51.7 50.9‐52.4 9062 59.1 57.4‐60.8 41,261 55.6 54.6‐56.5 10,590 30.9 29.5‐32.4 Most of our study population was white (83%). More than 85% of each of the HPV‐associated cancers were diagnosed among whites, with the exception of cervical carcinomas and vaginal SCCs, in which smaller proportions were diagnosed among whites (77.2% and 80.9%, respectively) (Table 1). Five‐year age‐standardized relative survival was consistently higher for whites compared with blacks for all HPV‐associated cancers, with higher survival observed for cervical carcinomas (64.8% and 57%, respectively), penile SCCs (48.4% and 34.7%, respectively), anal SCCs (69.3% and 59.8%, respectively), rectal SCCs (61.2% and 45.5%, respectively), and OPSCCs (53.5% and 32.4%, respectively) (Table 2). The lowest survival and the greatest differences by race were observed for blacks compared with whites for OPSCCs and penile SCCs (32.4% vs 53.5% and 34.7% vs 48.4%, respectively) (Table 2). When examining survival by age at diagnosis and race, the largest differences in survival between whites and blacks were observed for patients with OPSCCs ages 40 to 49 years (73.2% and. 40%, respectively), 50 to 59 years (67.6% and 38.6%, respectively), and <40 years (76% and 51.7%, respectively) at the time of diagnosis. In addition, large differences in survival between whites and blacks were observed for men ages 40 to 49 years with penile SCCs (58.5% and 34.5%, respectively) (Fig. 1). Figure 1 Open in figure viewer PowerPoint Age‐standardized 5‐year relative survival is illustrated for human papillomavirus (HPV)‐associated cancers by race and age at diagnosis (data from the National Program of Cancer Registries, 2001‐2011). Cervical carcinomas were age standardized to the International Cancer Survival Standard 2 (ages ≥ 15 years). Vaginal, vulvar, penile, anal, rectal, and oropharyngeal squamous cell carcinomas (SCCs) were age standardized to the International Cancer Survival Standard 1 (ages ≥ 15 years). Data from the National Program of Cancer Registries (2001‐2011) were compiled from 27 population‐based cancer registries that participate in the National Program of Cancer Registries, meet the data‐quality standards for inclusion in US Cancer Statistics, and meet the criteria for inclusion in the survival data set, which covers approximately 59% of the US population. Note that statistics could not be displayed for blacks aged <40 years for penile SCC because there were <25 patients. For cancers that occurred among both men and women, more than one‐half of anal and rectal SCCs occurred among women compared with only 20% of OPSCCs (Table 1). Compared with men, women had higher 5‐year relative survival for anal SCCs (69.3% and 59.8%, respectively) and rectal SCCs (61.2% and 45.5%, respectively) and slightly decreased survival for OPSCCs (Table 2). The greatest differences in survival by sex were observed for rectal SCCs. More than one‐third of all HPV‐associated cancers were diagnosed at localized stage, with the exception of OPSCCs, in which 16% were diagnosed at localized stage (Table 1). The 5‐year relative survival rate was higher for all HPV‐associated cancers diagnosed at localized stage and decreased for cancers diagnosed at regional and distant stages. The 5‐year age‐standardized relative survival rate ranged from 59.4% to 86% for cancers diagnosed in localized stage, from 41.2% to 58.5% for cancers diagnosed in regional stage, and from 13.3% to 31.7% for cancers diagnosed in distant stages. The shortest survival was observed for rectal SCCs diagnosed at distant stage (13.3%). The greatest differences in survival between cancers diagnosed in localized and distant stages were observed for vulvar SCCs (79% and 16.5%, respectively) and OPSCCs (59.4% and 30.8%, respectively) (Table 2). When examining 5‐year relative survival by population characteristics and disease stage at diagnosis, the poorest survival was observed for men who had rectal SCCs and for patients aged ≥60 years who had rectal and vulvar SCCs diagnosed at distant stage (6.9%, 10.5%, and 10.9%, respectively) (Table 1).

DISCUSSION This study is the largest population‐based study of survival for HPV‐associated cancers in the United States, covering 59% of the population. Previous studies covered a smaller number of the US population, ranging from <100 to approximately 50,000 cases, whereas the current analysis included 220,211 cases.22-30 Furthermore, this study is the first comprehensive survival analysis for all HPV‐associated cancers that includes 7 cancer sites. We report the highest 5‐year age‐standardized relative survival for cervical carcinomas, vulvar, and anal SCCs and the lowest for penile SCCs and OPSCCs. Our overall findings include higher survival rates for whites compared with blacks, with the largest differences observed among those with OPSCCs, as well as higher survival rates for those who had cancers diagnosed at localized stage compared with those diagnosed at regional or distant stages. In addition, although survival usually decreased with age, we observed slightly higher 5‐year age‐standardized relative survival rates for those diagnosed between ages 40 and 49 years with vaginal SCC, vulvar SCC, and anal SCC compared with those diagnosed at age ≤40 years with these cancers, a finding that merits further investigation (eg, whether there were differences by sex or human immunodeficiency virus status for anal SCCs). More than two‐thirds of cases in our study were cervical carcinomas or HPV‐associated OPSCCs. For patients with cervical carcinoma, the 5‐year relative survival rate was high, which may be because of screening and early detection (almost one‐half of cervical carcinomas in our study were detected at localized stage). For patients with OPSCC, the survival rate was lower compared with that for patients with other HPV‐associated cancers, which is concerning given the recent increase in OPSCCs as well as the lack of routinely recommended, population‐based screening tests.31 Similar to previous findings, we report that most HPV‐associated OPSCCs were observed among whites and men, and about one‐half occurred in patients aged ≤60 years.12, 22, 23, 32, 33 These findings, combined with the observation that survival was consistently lower among patients with OPSCC, is troubling. Furthermore, similar to the report by Goodman and colleagues, we observed that a large proportion of HPV‐associated OPSCCs were diagnosed at regional stage; > 60% of HPV‐associated OPSCCs, compared with <40% of other HPV‐associated cancers, were diagnosed at regional stage.7 The few studies that have examined whether there is a difference in survival by HPV status among patients with OPSCC have indicated that patients with HPV‐positive OPSCC survive longer than those with HPV‐negative OPSCC.7, 32 We could not examine survival by HPV status, because our classification of HPV‐associated cancers was based on histologic type and not on actual assessments of individual tumor status for the presence of HPV DNA. For other rare HPV‐associated cancers, we observed the highest survival for anal SCC and the lowest for penile SCC. The published evidence about survival from these cancers is limited and includes smaller populations as well as various definitions of HPV‐associated cancers. In a study of HPV‐associated anal cancers that included rectal SCCs in the United States, Joseph et al reported that more than one‐half of these cancers were diagnosed in localized stage, similar to our findings. Those authors also observed higher survival among women compared with men and among whites compared with blacks.30 Relatively little is known about the epidemiology of penile SCCs, and recent survival studies for penile cancers are lacking.34 A small study representing 12% of the US population and with data from 1973 through 1998 reported that the average duration of disease‐specific survival was < 5 years and decreased for localized, regional, and distant tumors, which is similar to our findings of decreased survival with advanced stages of cancer at diagnosis.35 Several factors highlight the importance of primary prevention of HPV‐associated cancers. First, the incidence of HPV‐associated cancers increased during 2004 through 2012 in the United States, indicating an increased burden from HPV infection.5 Second, the proportion of OPSCCs in all age groups with HPV‐positive status increased from 21% before the 1990s to > 70% today8, 15, 31, 36; and, if increasing trends continue, then OPSCC will become the most common HPV‐associated cancer by 2020.31 Third, our study demonstrated that survival from HPV‐associated cancers is poor compared with survival from all sites combined (67%) and compared with other cancers, such as breast cancers (90%) and prostate cancers (99%).37 In the absence of routine screening recommendations for any HPV‐associated cancers, with the exception of cervical carcinomas, primary prevention through HPV vaccine is essential, especially for OPSCC, in which there is an increasing trend in incidence. HPV vaccines are approved and recommended for use among both boys and girls.38 Beyond primary prevention, assessing tumor HPV status is essential for OPSCC management and treatment, because some studies have noted differential responses to therapy in HPV‐positive versus HPV‐negative head and neck cancers.23, 31, 39-42 There are a few limitations to our study. The main limitation includes the classification of HPV‐associated cancers, which was based on histologic criteria and not on actual assessment of individual tumor status for the presence of HPV DNA. In addition, we were not able to examine survival for any other racial/ethnic groups, because current life tables are only available for whites and blacks. Although, to our knowledge, this is the largest study to date of survival for HPV‐associated cancers among blacks, the 95% CIs were wider for blacks than for whites, indicating that comparisons should be made with caution. Finally, treatment data were not available; therefore, we were not able to account for treatment differences in this analysis. Although it is not a limitation, it is important to note that relative survival is not disease‐specific and is a net survival measure representing the likelihood that a patient will not die from causes associated specifically with the cancer under study. Furthermore, patients with cancer can die from comorbidities unrelated to their cancer diagnosis. A recent study concluded that, of all deaths that occurred in patients diagnosed with breast, prostate, colon, and rectal cancers at localized stage, a small proportion were because of cancer compared with other comorbidities, and the proportions of death from cancer increased with increasing stages of cancer at diagnosis.43 On the basis of the largest population‐based study of survival for HPV‐associated cancers in the United States, we observed large disparities in relative survival for HPV‐associated cancers by sex, race, and age, especially by race and age for penile and oropharyngeal SCCs and by sex for rectal SCCs. HPV vaccination and improved access to screening and treatment, especially among groups that experience higher incidence and lower survival, may reduce disparities in survival from HPV‐associated cancers.

FUNDING SUPPORT No specific funding was disclosed.

CONFLICT OF INTEREST DISCLOSURES The authors made no disclosures.

AUTHOR CONTRIBUTIONS Hilda Razzaghi: Contributed to the conception, design, analysis, and interpretation of data; wrote the initial draft; approved the final version submitted for publication; and agreed to be accountable for all aspects of the work. Mona Saraiya: Contributed to the conception, design, and interpretation of data; contributed to revising the article critically for important intellectual content; approved the final version submitted for publication; and agreed to be accountable for all aspects of the work. Trevor D. Thompson: Contributed to the conception, design, analysis and interpretation of data; contributed to drafting and revising the article critically for important intellectual content; approved the final version submitted for publication; and agreed to be accountable for all aspects of the work. S. Jane Henley: Contributed to the conception, design, analysis, and interpretation of data; contributed to drafting and revising the article critically for important intellectual content; approved the final version submitted for publication; agreed to be accountable for all aspects of the work. Laura Viens: Contributed to study conception and design, revised the article critically for important intellectual content, approved the final version submitted for publication, and agreed to be accountable for all aspects of the work. Reda Wilson: Contributed to the conception, design, and interpretation of data; revised the article critically for important intellectual content; approved the final version submitted for publication; and agreed to be accountable for all aspects of the work.