Skip to main content
PMC home page
British Journal of Cancer logoLink to British Journal of Cancer
. 2015 Mar 3;112(Suppl 1):S108–S115. doi: 10.1038/bjc.2015.49

Stage at diagnosis and early mortality from cancer in England

S McPhail 1,*, S Johnson 1, D Greenberg 2, M Peake 1, B Rous 2
PMCID: PMC4385983  PMID: 25734389

Abstract

Background:

Stage at diagnosis is a key predictor of overall cancer outcome. For the first time, stage completeness is high enough for robust analysis for the whole of England.

Methods:

We analysed data from the National Cancer Registration Service's (NCRS) Cancer Analysis System on persons diagnosed with breast, colorectal, lung, prostate or ovarian cancers in England in 2012. One-year relative survival (followed-up to the end of 2013) was calculated along with adjusted excess rate ratios, for mortality within 1 year.

Results:

One-year relative survival decreased with increasing stage at diagnosis. For breast, prostate and colorectal cancers survival showed a major reduction for stage 4 cancers, whereas for lung and ovarian cancers there were substantial decreases in relative survival for each level of increase in stage. Excess rate ratios for mortality within 1 year of diagnosis showed that stage and age were the most important cofactors, but they also identified the statistically significant effects of sex, income deprivation and geographic area of residence.

Conclusions:

Further reductions in mortality may be most effectively achieved by diagnosing all cancers before they progress to stage 4, but for lung and ovarian cancers there is also a need for a stage shift to earlier stages together with efforts to improve stage-specific survival at all stages.

Keywords: survival, stage, mortality, early diagnosis

Improving cancer survival is a key challenge identified in ‘Improving outcomes: a strategy for cancer (Department of Health, 2011)'. Cancer survival estimates in England currently fall below those in many European countries across most cancer types (Richards, 2007; Verdecchia et al, 2007; Coleman et al, 2011; De Angelis et al 2014). It has been estimated that if cancer survival in England was made comparable with the European average, then 5000 or more deaths within 5 years of diagnosis could be avoided annually (Abdel-Rahman et al, 2009; Richards 2009a). However, if analyses are restricted to include only those who survive at least a year from diagnosis, then the difference in conditional 5-year survival between England and European countries is, in general, smaller (Thomson and Forman, 2009; Holmberg et al, 2010). This would suggest that differences in 1-year survival are an important driver of differences in longer-term survival.

Stage at diagnosis is highly predictive of cancer mortality, and a possible explanation for the difference in cancer survival between England and Europe is that a higher proportion of patients are diagnosed at a later stage in England (Sant et al, 2003; Foot and Harrison, 2011; Walters et al, 2013a, 2013b). The completeness of stage at diagnosis for cancers registered in England by the NCRS has improved greatly in recent years. Staging completeness now exceeds 80% for several major cancers (including breast, colorectal, lung, ovarian and prostate) diagnosed in 2012, allowing more robust analyses than have previously been possible. The remainder of staging data may be missing for various reasons: certain morphological tumour types have no formal agreed staging system; it was clinically inappropriate to stage the patient; diagnosis and/or treatment was outside the National Health Service; the patient died before staging was complete; or staging information was not transferred to the NCRS.

In England, a National Awareness and Early Diagnosis Initiative was established in 2008 (Richards, 2009b) as a joint initiative between the Government and Cancer Research UK. Much of its work has focussed on ways of promoting awareness of the early symptoms of cancer to patients and primary-care physicians. The ability to measure stage at diagnosis at a population level is vital to study the impact of such initiatives, study the scale and nature of variation in stage at diagnosis within England and to enable international comparisons.

The purpose of this study is to characterise the stage at presentation for major cancers, which have the highest recorded stage completeness, and to examine the relationship between stage at diagnosis, early mortality and major demographic variables.

Materials and methods

Details of 156 131 malignant breast, colorectal, lung, prostate and ovarian (ICD-10 C50, C18-20, C34, C61 and C56) tumours diagnosed in 2012 in residents of England were extracted from the NCRS registration data set. Of these, 2663 cases were excluded on the basis that they were a death certificate only registration. Other exclusions comprised the following: 281 male breast cancers; 168 aged under 15 years or over 99 years at diagnosis; 187 recorded as stage 0 – for breast cancer – this is Paget's disease of the nipple, included under ICD-10 C50; 9 had a misordered date of diagnosis and date of death; and 2 had a missing deprivation quintile. Information on deaths was provided by the Office for National Statistics as part of a routine data feed to NCRS, and follow-up is complete to the end of 2013. Cancers were staged according to the TNM version 7 classification, based on clinical, imaging and pathological information (Sobin et al, 2009). The income deprivation quintile was derived by linking each tumour to the Index of Multiple Deprivation 2010 (Communities and Local Government, 2011) using postcode at the time of diagnosis to derive the Lower Statistical Output Area of residence at diagnosis. Equal population quintiles (of the general population) were derived from the income domain score. Geographic area of residence at the time of diagnosis was defined by the strategic clinical networks (SCNs) established in England in 2013. These SCNs have populations ranging from 2.1 to 9.0 million.

Relative survival is the ratio of the observed survival in the patient cohort and the expected survival of a cohort from the general population matched by age, sex, socioeconomic deprivation and geographic region (Government Office Region). It was calculated using the strs programme (Dickman et al, 2004) with break points set at 1, 3, 6 and 12 months and using the Ederer II method. The life tables used (Cancer Research UK Cancer Survival Group, 2006) were available with background mortality up to 2009. Age-standardised relative survival was calculated using a method of Corazziari et al, 2004.

Observed mortality, expected mortality and person-years of exposure time were calculated using the strs command in Stata 12.1 (StataCorp., 2011) for the same periods as for survival. These were summed into an overall excess mortality for the year following diagnosis. This outcome measure was chosen both for simplicity of expression and because mortality in the first year of diagnosis is of wide interest; exploration of the variation in excess mortality within the first year of diagnosis is left for future work. Excess mortality rate ratios were modelled using the glm command as per the ‘grouped' methodology of Dickman et al (2004) with sex, age band, income deprivation quintile, SCN and stage as independent variables. The baseline SCN for the calculation of rate ratios was selected from one of the two median SCNs in the distribution of 1-year relative survival. Stage 4 was used as the baseline for stage at diagnosis. Interactions between variables were explored by considering further models including an interaction between each pair of variables with a likelihood ratio test performed by comparing the model with and without interactions to determine the significance of each interaction term.

Results

Description of cohort

A total of 152 821 newly diagnosed malignant cancers of interest, after exclusions, were diagnosed in England in 2012. Table 1 shows the number of tumours included and the proportion broken down by age, sex, income deprivation, SCN and stage at diagnosis for breast, colorectal, lung, ovarian and prostate cancers. The median age varies between 63.0 years (breast and ovarian cancer) and 70.8 (colorectal) and 71.9 (lung) years, whereas the difference in the proportions of cases occurring in the most and least deprived varies between −11% (lung cancer) and +12% (prostate cancer). There is substantial variation in the stage breakdown with cancer type: more than two-thirds of breast cancers present at stage 1 or 2 and more than two-thirds of lung cancers present at stage 3 or 4. The other three cancers are intermediate between these two distributions. Stage completeness varies between 89% (colorectal cancer) and 82% (prostate cancer).

Table 1. Tumour cohort broken down by cancer type, sex, age, income deprivation, strategic clinical network and recorded stage.

  Breast
 Colorectal
 Lung
 Ovarian
 Prostate
  n % n % n % n % n %
All 42 071 100 34 011 100 34 997 100 5455 100 36 287 100
Sex
Male 0 0 19 215 56.5 19 120 54.6 0 0 36 287 100
Female 42 071 100 14 796 43.5 15 877 45.4 5455 100 0 0
Age (years)
Median 63.0
 70.8
 71.9
 63.0
 70.8
15–49 8504 20.2 2071 6.1 973 2.8 1077 19.7 405 1.1
50–59 8881 21.1 3713 10.9 3445 9.8 956 17.5 3727 10.3
60–69 11 002 26.2 8501 25.0 9583 27.4 1369 25.1 12 691 35.0
70–79 7193 17.1 10 493 30.9 11 937 34.1 1223 22.4 12 887 35.5
80–89 5307 12.6 7857 23.1 7867 22.5 720 13.2 5795 16.0
90–99 1184 2.8 1376 4.0 1192 3.4 110 2.0 782 2.2
Income deprivation
Least deprived 9474 22.5 7306 21.5 4723 13.5 1089 20.0 8661 23.9
Quintile 2 9573 22.8 7488 22.0 6370 18.2 1225 22.5 8904 24.5
Quintile 3 8976 21.3 7298 21.5 7115 20.3 1177 21.6 7704 21.2
Quintile 4 7788 18.5 6488 19.1 7961 22.7 1060 19.4 6197 17.1
Most deprived 6260 14.9 5431 16.0 8828 25.2 904 16.6 4821 13.3
Strategic clinical network
N50 2148 5.1 1804 5.3 2285 6.5 300 5.5 1831 5.0
N51 3233 7.7 2820 8.3 3522 10.1 479 8.8 2772 7.6
N52 2553 6.1 2233 6.6 2975 8.5 335 6.1 2036 5.6
N53 4078 9.7 3362 9.9 4299 12.3 533 9.8 3381 9.3
N54 5042 12.0 4039 11.9 3809 10.9 689 12.6 4705 13.0
N55 3874 9.2 3088 9.1 2985 8.5 522 9.6 3206 8.8
N56 4464 10.6 3726 11.0 3510 10.0 594 10.9 4175 11.5
N57 4133 9.8 3431 10.1 2876 8.2 516 9.5 3648 10.1
N58 3660 8.7 3002 8.8 2682 7.7 454 8.3 3299 9.1
N59 1702 4.0 1202 3.5 936 2.7 188 3.4 1304 3.6
N60 2499 5.9 2049 6.0 1628 4.7 294 5.4 2292 6.3
N61 4685 11.1 3255 9.6 3490 10.0 551 10.1 3638 10.0
Recorded stage
Stage 1 15 752 37.4 5255 15.5 4636 13.2 1711 31.4 11 896 32.8
Stage 2 14 148 33.6 8402 24.7 2640 7.5 276 5.1 6269 17.3
Stage 3 3583 8.5 9258 27.2 7012 20.0 1567 28.7 5625 15.5
Stage 4 2366 5.6 7351 21.6 17 151 49.0 929 17.0 5836 16.1
Stage NK 6222 14.8 3745 11.0 3558 10.2 972 17.8 6661 18.4
Open in a new tab

Abbreviation: NK=not known.

Table 2 shows the variation in stage at diagnosis by sex, age and income deprivation (variation by SCN is included in the Supplementary Online Material and Supplementary Table 5). More men with colorectal cancer present at stage 1 compared with women (16 vs 14%, P<0.001), whereas for lung cancer slightly fewer men present at stage 1 compared with women (12 vs 15%, P<0.001). More men present with stage 4 lung cancer compared with women (50 vs 48%, P<0.001).

Table 2. Variation in stage at diagnosis by sex, age and income deprivation.

    Breast
 Colorectal
 Lung
 Ovarian
 Prostate
Cohort Stages n % n % n % n % n %
Sex
Female Stage 1 15752 37.4% 2111 14.0% 2395 15.0% 1711 31.4%
Male   3144 16.0% 2241 12.0% 11896 32.8%
Female Stage 2 14148 33.6% 3722 25.0% 1128 7.0% 276 5.1%
Male   4680 24.0% 1512 8.0% 6269 17.3%
Female Stage 3 3583 8.5% 3922 27.0% 3097 20.0% 1567 28.7%
Male   5336 28.0% 3915 20.0% 5625 15.5%
Female Stage 4 2366 5.6% 3215 22.0% 7618 48.0% 929 17.0%
Male   4136 22.0% 9533 50.0% 5836 16.1%
Female Stage NK 6222 14.8% 1826 12.0% 1639 10.0% 972 17.8%
Male   1919 10.0% 1919 10.0% 6661 18.4%
Age (years)
15–49 Stage 1 2545 29.9% 282 13.6% 126 12.9% 588 54.6% 185 45.7%
50–59   3927 44.2% 526 14.2% 368 10.7% 387 40.5% 1438 38.6%
60–69   5462 49.6% 1647 19.4% 1282 13.4% 389 28.4% 4618 36.4%
70–79   2493 34.7% 1777 16.9% 1704 14.3% 243 19.9% 4247 33.0%
80–89   1132 21.3% 933 11.9% 1036 13.2% 97 13.5% 1332 23.0%
90–99   193 16.3% 90 6.5% 120 10.1% 7 6.4% 76 9.7%
15–49 Stage 2 3431 40.3% 384 18.5% 68 7.0% 52 4.8% 84 20.7%
50–59   2832 31.9% 788 21.2% 233 6.8% 60 6.3% 738 19.8%
60–69   3215 29.2% 2019 23.8% 716 7.5% 74 5.4% 2497 19.7%
70–79   2478 34.5% 2836 27.0% 962 8.1% 57 4.7% 2286 17.7%
80–89   1850 34.9% 2104 26.8% 602 7.7% 30 4.2% 625 10.8%
90–99   342 28.9% 271 19.7% 59 4.9% 3 2.7% 39 5.0%
15–49 Stage 3 997 11.7% 634 30.6% 171 17.6% 199 18.5% 37 9.1%
50–59   747 8.4% 1216 32.7% 716 20.8% 240 25.1% 587 15.7%
60–69   748 6.8% 2510 29.5% 2104 22.0% 441 32.2% 2157 17.0%
70–79   633 8.8% 2856 27.2% 2420 20.3% 440 36.0% 2148 16.7%
80–89   397 7.5% 1835 23.4% 1425 18.1% 230 31.9% 632 10.9%
90–99   61 5.2% 207 15.0% 176 14.8% 17 15.5% 64 8.2%
15–49 Stage 4 363 4.3% 478 23.1% 515 52.9% 87 8.1% 36 8.9%
50–59   385 4.3% 916 24.7% 1874 54.4% 141 14.7% 409 11.0%
60–69   488 4.4% 1790 21.1% 4750 49.6% 258 18.8% 1539 12.1%
70–79   543 7.5% 2144 20.4% 5742 48.1% 257 21.0% 2086 16.2%
80–89   499 9.4% 1723 21.9% 3710 47.2% 157 21.8% 1501 25.9%
90–99   88 7.4% 300 21.8% 560 47.0% 29 26.4% 265 33.9%
15–49 Stage NK 1168 13.7% 293 14.1% 93 9.6% 151 14.0% 63 15.6%
50–59   990 11.1% 267 7.2% 254 7.4% 128 13.4% 555 14.9%
60–69   1089 9.9% 535 6.3% 731 7.6% 207 15.1% 1880 14.8%
70–79   1046 14.5% 880 8.4% 1109 9.3% 226 18.5% 2120 16.5%
80–89   1429 26.9% 1262 16.1% 1094 13.9% 206 28.6% 1705 29.4%
90–99   500 42.2% 508 36.9% 277 23.2% 54 49.1% 338 43.2%
Income deprivation
Least deprived Stage 1 3650 38.5% 1184 16.2% 615 13.0% 347 31.9% 2898 33.5%
2   3704 38.7% 1168 15.6% 842 13.2% 345 28.2% 2874 32.3%
3   3505 39.0% 1207 16.5% 924 13.0% 361 30.7% 2571 33.4%
4   2724 35.0% 918 14.1% 1062 13.3% 343 32.4% 1963 31.7%
Most deprived   2169 34.6% 778 14.3% 1193 13.5% 315 34.8% 1590 33.0%
Least deprived Stage 2 2965 31.3% 1827 25.0% 363 7.7% 56 5.1% 1536 17.7%
2   3223 33.7% 1879 25.1% 481 7.6% 65 5.3% 1610 18.1%
3   3061 34.1% 1783 24.4% 529 7.4% 64 5.4% 1338 17.4%
4   2702 34.7% 1628 25.1% 587 7.4% 52 4.9% 1066 17.2%
Most deprived   2197 35.1% 1285 23.7% 680 7.7% 39 4.3% 719 14.9%
Least deprived Stage 3 745 7.9% 2053 28.1% 903 19.1% 321 29.5% 1244 14.4%
2   760 7.9% 2048 27.4% 1290 20.3% 365 29.8% 1406 15.8%
3   766 8.5% 1950 26.7% 1415 19.9% 337 28.6% 1212 15.7%
4   690 8.9% 1733 26.7% 1588 19.9% 280 26.4% 1007 16.2%
Most deprived   622 9.9% 1474 27.1% 1816 20.6% 264 29.2% 756 15.7%
Least deprived Stage 4 465 4.9% 1522 20.8% 2368 50.1% 179 16.4% 1259 14.5%
2   442 4.6% 1564 20.9% 3080 48.4% 207 16.9% 1365 15.3%
3   457 5.1% 1553 21.3% 3523 49.5% 213 18.1% 1284 16.7%
4   529 6.8% 1459 22.5% 3887 48.8% 189 17.8% 1048 16.9%
Most deprived   473 7.6% 1253 23.1% 4293 48.6% 141 15.6% 880 18.3%
Least deprived Stage NK 1649 17.4% 720 9.9% 474 10.0% 186 17.1% 1724 19.9%
2   1444 15.1% 829 11.1% 677 10.6% 243 19.8% 1649 18.5%
3   1187 13.2% 805 11.0% 724 10.2% 202 17.2% 1299 16.9%
4   1143 14.7% 750 11.6% 837 10.5% 196 18.5% 1113 18.0%
Most deprived   799 12.8% 641 11.8% 846 9.6% 145 16.0% 876 18.2%
Open in a new tab

Abbreviation: NK=not known.

For all cancer types, the proportion of missing data increases with age, particularly in those aged 80+ years. The proportion of ovarian cancers diagnosed at stage 1 drops from 54.6% in those aged 15–49 years to 19.9% in those aged 70–79 years, whereas there is no statistically significant change in lung cancer. Prostate cancer is intermediate with a change from 45.7 to 33.0%. For colorectal and breast cancer a linear change is not observed, and the highest proportion of stage 1 diagnoses occur in 60–69-year-olds.

The effect of income deprivation on stage distribution is generally <2.0% between most and least deprived for colorectal and lung cancer, and not statistically significant for ovarian cancer. For breast cancer presentation at stage 1, and at unknown stage, is more common for the least deprived (P<0.001), whereas presentation at stages 2, 3 and 4 is more common in the most deprived (P<0.001). For prostate cancer, presentation at stage 2 (P<0.001) and unknown stage (P<0.05) is more common for the least deprived, whereas presentation at stages 3 (P<0.05) and 4 (P<0.001) is more common in the most deprived.

Variation in relative survival

Table 3 shows relative survival and age-standardised relative survival broken down by the same independent variables. Age standardisation changes overall 1-year relative survival by −0.9% (breast), +1.4% (lung), +1.0% (colorectal), −6.4% (ovarian) and +0.1% (prostate).

Table 3. Unadjusted and age-standardised relative survival by cancer type, sex, age, income deprivation, strategic clinical network and recorded stage.

  Breast
 Colorectal
 Lung
 Ovarian
 Prostate
  RS 95% CI ASRS 95% CI RS 95% CI ASRS 95% CI RS 95% CI ASRS 95% CI RS 95% CI ASRS 95% CI RS 95% CI ASRS 95% CI
All 96.4 96.2–96.6 95.6 95.2–95.9 77.7 77.2–78.2 79.1 78.6–79.5 36.3 35.7–36.8 37.2 36.7–37.8 74.7 73.5–75.8 68.3 66.9–69.6 96.6 96.3–96.9 96.6 96.3–96.8
Sex
Male 79.4 78.8–80.0 80.1 79.4–80.7 33.7 33.0–34.4 34.4 78.6–79.5 33.7–35.1 96.6 96.3–96.9 96.6 96.3–96.8
Female 96.4 96.2–96.6 95.6 95.2–95.9 75.4 74.7–76.1 77.9 77.2–78.6 39.3 38.5–40.1 40.6 78.6–79.5 74.7 73.5–75.8 68.3 39.8–41.3
Age (years)
15–49 98.5 98.2–98.7 88.1 86.6–89.4 47.2–53.5 91.2–94.3 96.3–99.3
50–59 98.3 98.0–98.6 86.4 85.3–87.5 41.3–44.7 86.3–90.4 98.7–99.5
60–69 98.0 97.7–98.3 85.2 84.4–86.0 41.2–43.2 77.4–81.7 98.7–99.2
70–79 95.1 94.5–95.7 79.5 78.6–80.3 35.8–37.5 63.6–69.1 97.7–98.5
80–89 90.6 89.5–91.7 65.3 64.1–66.4 25.1–27.2 36.3–43.8 88.6–90.8
90–99 84.5 81.3–87.5 44.8 41.7–47.9 14.9–19.7 14.9–32.3 63.1–71.8
Income deprivation
Least deprived 97.3 96.9–97.7 96.4 95.8–97.0 80.4 79.4–81.4 81.6 80.7–82.6 38.0 36.6–39.4 40.1 38.7–41.6 78.3 75.7–80.7 73.5 70.4–76.3 96.9 96.4–97.4 96.7 96.1–97.2
Quintile 2 96.8 96.3–97.2 96.2 95.6–96.8 78.8 77.8–79.8 80.6 79.6–81.5 37.0 35.8–38.3 38.5 37.3–39.8 73.5 70.9–75.9 68.4 65.6–71.0 96.6 96.1–97.1 96.5 95.9–97.0
Quintile 3 96.6 96.1–97.1 95.9 95.2–96.5 77.7 76.7–78.8 79.2 78.2–80.2 35.5 34.4–36.7 36.8 35.6–38.0 73.9 71.2–76.4 67.8 64.8–70.7 96.9 96.3–97.4 96.9 96.3–97.4
Quintile 4 95.3 94.7–95.9 94.3 93.5–95.0 76.3 75.1–77.4 77.7 76.6–78.8 36.2 35.1–37.3 36.9 35.8–37.9 72.6 69.8–75.3 65.3 61.9–68.5 96.3 95.6–97.0 96.4 95.6–97.0
Most deprived 95.6 95.0–96.2 94.3 93.4–95.2 74.0 72.7–75.2 74.9 73.6–76.1 35.4 34.4–36.4 35.6 34.6–36.7 75.3 72.2–78.1 64.8 61.0–68.4 96.1 95.2–96.9 96.1 95.1–96.8
Strategic clinical network
N50 95.8 94.6–96.8 94.8 93.2–96.0 77.7 75.5–79.7 78.3 76.2–80.2 36.7 34.7–38.8 37.3 35.3–39.4 73.7 68.1–78.4 65.9 60.0–71.2 95.9 94.5–97.1 95.6 94.1–96.7
N51 96.6 95.7–97.4 95.7 94.4–96.7 77.8 76.1–79.5 78.2 76.5–79.8 36.5 34.8–38.1 37.0 35.4–38.7 74.8 70.5–78.5 67.7 62.8–72.1 95.9 94.8–96.9 95.9 94.7–96.8
N52 96.0 95.0–96.9 95.2 93.7–96.3 76.1 74.1–78.0 77.6 75.7–79.4 34.7 33.0–36.5 35.9 34.1–37.7 73.1 67.9–77.7 66.4 60.3–71.8 97.3 96.1–98.4 96.6 95.0–97.7
N53 96.6 95.8–97.3 95.5 94.4–96.4 76.6 75.1–78.2 78.5 77.0–79.9 37.9 36.4–39.4 38.8 37.3–40.4 74.7 70.7–78.3 69.3 64.6–73.5 95.7 94.7–96.6 95.5 94.5–96.4
N54 95.9 95.2–96.5 95.1 94.1–95.9 76.0 74.6–77.4 77.8 76.4–79.1 35.5 34.0–37.1 36.7 35.1–38.3 74.5 71.0–77.7 68.9 64.9–72.5 96.4 95.6–97.1 96.7 95.9–97.3
N55 96.7 95.9–97.3 95.4 94.3–96.4 76.4 74.8–78.0 77.7 76.1–79.2 35.9 34.1–37.6 37.1 35.3–38.9 73.8 69.7–77.5 66.0 61.3–70.3 95.9 94.9–96.8 95.9 94.9–96.7
N56 96.0 95.3–96.7 95.2 94.2–96.1 78.2 76.7–79.6 79.3 77.9–80.7 35.8 34.2–37.4 37.0 35.3–38.7 76.5 72.8–79.8 68.6 64.3–72.5 97.8 97.0–98.5 97.7 96.8–98.4
N57 97.3 96.6–97.9 96.8 95.8–97.5 78.8 77.3–80.2 80.5 79.1–81.9 35.9 34.1–37.7 37.0 35.1–38.8 73.4 69.2–77.1 68.2 63.6–72.4 95.8 94.8–96.6 96.2 95.3–97.0
N58 97.0 96.2–97.6 96.3 95.3–97.1 77.8 76.2–79.4 79.7 78.1–81.2 33.0 31.2–34.8 33.9 32.1–35.8 73.2 68.7–77.1 69.0 64.1–73.3 97.0 96.1–97.8 96.9 95.9–97.6
N59 97.0 95.9–97.9 96.3 94.5–97.5 80.2 77.6–82.5 81.5 79.1–83.7 38.8 35.6–42.0 39.3 36.0–42.5 81.5 75.0–86.6 76.2 68.4–82.3 98.1 96.7–99.1 97.6 95.8–98.6
N60 95.8 94.7–96.7 94.9 93.5–96.0 79.0 77.0–80.9 81.4 79.6–83.1 36.0 33.6–38.4 37.4 35.0–39.8 70.8 65.0–75.8 66.7 60.5–72.2 97.0 95.9–98.0 97.4 96.3–98.2
N61 96.4 95.7–97.0 95.4 94.3–96.3 79.3 77.8–80.8 80.1 78.6–81.5 38.9 37.2–40.5 39.6 37.9–41.3 77.4 73.5–80.7 68.8 63.9–73.1 97.3 96.5–98.0 96.4 95.4–97.2
Recorded stage
Stage 1 100.0 99.8–100.2 99.9 97.4–100.0 98.1 97.4–98.6 98.0 97.3–98.5 84.0 82.8–85.2 85.1 84.0–86.2 98.1 97.1–98.8 96.9 94.5–98.3 101.2 100.9–101.4 101.4 101.0–101.7
Stage 2 99.5 99.2–99.7 99.5 99.0–99.7 93.9 93.2–94.5 94.6 93.9–95.1 69.5 67.6–71.4 71.0 69.2–72.8 88.6 84.0–92.1 87.5 81.4–91.8 100.8 100.4–101.2 100.8 100.3–101.3
Stage 3 97.3 96.5–97.9 96.5 95.3–97.4 89.1 88.3–89.8 89.1 88.3–89.8 44.6 43.4–45.8 45.3 44.1–46.4 71.3 68.9–73.5 66.6 64.1–68.9 100.9 100.4–101.3 100.8 100.3–101.3
Stage 4 66.4 64.4–68.4 65.3 63.1–67.4 42.5 41.3–43.6 43.8 42.6–44.9 17.1 16.5–17.7 17.6 17.0–18.2 51.5 48.1–54.7 49.5 46.2–52.6 82.7 81.6–83.8 85.1 84.1–86.1
Stage NK 91.3 90.4–92.1 91.2 90.2–92.1 53.5 51.8–55.2 60.2 58.4–62.0 25.5 24.0–26.9 28.8 27.1–30.5 57.0 53.7–60.1 55.5 52.1–58.8 93.0 92.1–93.7 94.8 94.1–95.4
Open in a new tab

Abbreviations: ASRS=age-standardised relative survival; CI=confidence interval; NK=not known; RS=relative survival.

For the non-sex-specific cancers, survival is 4.0% higher in men (colorectal cancer) and 5.6% higher in women (lung cancer) compared with the opposite sex. Age-standardised figures are 2.2% for colorectal cancer and 6.1% for lung cancer. Relative survival varies strongly with age but, depending on cancer type, either showed only a small decline up to a certain age and then a steeper decline (breast, colorectal and prostate cancers) or declined with every increment in age category (lung and ovarian cancer). Relative survival decreases with increasing income deprivation, between the least and most deprived by 1.7% (breast), 6.5% (colorectal), 2.6% (lung), 3.0% (ovarian) and 0.8% (prostate). The age-standardised figures are 2.1%, 6.7%, 4.5%, 8.6% and 0.6%, respectively.

The variation of the relative survival between SCNs has a standard deviation of 0.5% (breast), 1.3% (colorectal), 1.6% (lung), 2.6% (ovarian) and 0.8% (prostate), assuming a normal distribution across SCNs. Relative survival is reduced with increasing stage; again some cancer types show a small reduction for lower-stage categories (breast, colorectal and prostate) followed by larger reductions in higher-stage categories, whereas other cancer types (lung and ovarian) show substantial reductions for each increase in stage at diagnosis.

Variation in excess mortality rate ratio

Table 4 shows the excess mortality rate ratio for each independent variable. For early-stage breast and stage 1–3 prostate cancers, the mortality rate ratio is close to zero (relative to the baseline case of stage 4). Of the independent variables, stage and age have the greatest influence. Women have 14% higher excess mortality for colorectal cancer and 13% lower for lung cancer than men (P<0.001 for both). Rate ratios increase with increasing age and increasing deprivation, and they are statistically significant for each cancer type for older ages compared with the youngest group. Except for prostate cancer, higher income deprivation is associated with higher excess mortality. There is some statistically significant variation in the rate ratios geographically, with 5 out of 50 combinations of cancer types and SCN being statistically significant at a 95% level.

Table 4. Modelled excess mortality rate ratio within 1 year of diagnosis by cancer type, sex, age, income deprivation, strategic clinical network and recorded stage.

  Breast
 Colorectal
 Lung
 Ovarian
 Prostate
  EMRR 95% CI P EMRR 95% CI P EMRR 95% CI P EMRR 95% CI P EMRR 95% CI P
Sex
Male       1.00 (Ref.) <0.001 1.00 (Ref.) <0.001            
Female       1.14 1.08–1.19   0.87 0.84–0.89              
Age (years)
15–49 1.00 (Ref.) <0.001 1.00 (Ref.) <0.001 1.00 (Ref.) <0.001 1.00 (Ref.) <0.001 1.00 (Ref.) <0.001
50–59 1.25 0.98–1.59   1.30 1.12–1.52   1.27 1.15–1.40   1.29 0.96–1.74   0.67 0.27–1.65  
60–69 1.72 1.38–2.15   1.73 1.50–1.98   1.44 1.32–1.59   2.11 1.63–2.73   0.89 0.38–2.09  
70–79 2.64 2.14–3.27   2.67 2.33–3.05   1.83 1.67–2.01   3.53 2.75–4.54   1.42 0.61–3.30  
80–89 3.82 3.10–4.70   4.78 4.19–5.45   2.61 2.38–2.86   8.98 7.01–11.5   3.59 1.55–8.33  
90–99 6.22 4.76–8.11   7.00 6.02–8.13   3.50 3.13–3.91   14.48 10.5–20.0   8.83 3.77–20.7  
Income deprivation
Least deprived 1.00 (Ref.) <0.001 1.00 (Ref.) <0.001 1.00 (Ref.) <0.001 1.00 (Ref.) 0.004 1.00 (Ref.) 0.234
Quintile 2 1.16 0.96–1.40   1.08 1.00–1.17   1.08 1.03–1.13   1.15 0.96–1.36   1.01 0.85–1.21  
Quintile 3 1.30 1.08–1.56   1.12 1.04–1.21   1.12 1.07–1.17   1.16 0.97–1.38   0.98 0.81–1.18  
Quintile 4 1.58 1.32–1.88   1.20 1.11–1.29   1.15 1.10–1.20   1.34 1.12–1.60   1.13 0.93–1.36  
Most deprived 1.41 1.16–1.71   1.39 1.28–1.50   1.22 1.17–1.28   1.41 1.16–1.71   1.20 0.98–1.47  
Strategic clinical network
N50 1.18 0.88–1.58 <0.001 1.11 0.98–1.27 <0.001 1.03 0.96–1.10 <0.001 1.27 0.96–1.70 0.015 1.07 0.80–1.45 0.004
N51 0.91 0.68–1.23   1.00 (Ref.)   1.00 (Ref.)   1.17 0.91–1.50   0.87 0.66–1.14  
N52 1.23 0.92–1.65   1.12 0.99–1.27   1.00 0.94–1.06   1.39 1.06–1.82   0.74 0.55–1.01  
N53 1.00 (Ref.)   1.07 0.95–1.19   0.93 0.88–0.98   1.00 (Ref.)   0.94 0.74–1.20  
N54 1.59 1.25–2.03   1.13 1.01–1.25   0.96 0.90–1.01   1.13 0.90–1.43   1.00 (Ref.)  
N55 1.02 0.78–1.33   1.06 0.94–1.19   0.93 0.87–0.99   1.19 0.93–1.52   0.88 0.67–1.15  
N56 1.14 0.88–1.47   0.96 0.86–1.07   0.98 0.92–1.04   0.99 0.77–1.27   0.72 0.56–0.94  
N57 0.96 0.73–1.26   1.08 0.96–1.21   0.98 0.92–1.05   0.98 0.76–1.25   1.09 0.86–1.37  
N58 0.84 0.64–1.10   1.01 0.90–1.13   1.11 1.04–1.19   1.14 0.89–1.47   0.91 0.70–1.17  
N59 0.89 0.62–1.27   0.85 0.72–1.00   1.00 0.91–1.10   0.73 0.49–1.07   0.45 0.26–0.78  
N60 1.82 1.38–2.41   1.07 0.94–1.23   0.98 0.91–1.06   0.86 0.65–1.15   0.98 0.73–1.31  
N61 0.82 0.64–1.05   0.86 0.77–0.97   0.85 0.80–0.90   0.96 0.74–1.23   1.03 0.80–1.33  
Recorded stage
Stage 1 ∼0.00 * <0.001 0.02 0.01–0.03 <0.001 0.08 0.07–0.08 <0.001 0.04 0.02–0.06 <0.001 ∼0.00 * <0.001
Stage 2 0.01 0.01–0.02   0.06 0.05–0.07   0.16 0.15–0.18   0.19 0.13–0.27   ∼0.00 *  
Stage 3 0.07 0.06–0.09   0.12 0.11–0.13   0.39 0.37–0.40   0.49 0.42–0.56   ∼0.00 *  
Stage 4 1.00 (Ref.)   1.00 (Ref.)   1.00 (Ref.)   1.00 (Ref.)   1.00 (Ref.)  
Stage NK 0.20 0.17–0.23   0.61 0.57–0.65   0.83 0.79–0.86   0.81 0.71–0.94   0.40 0.35–0.47  
Open in a new tab

Abbreviations: CI=confidence interval; EMRR=excess mortality rate ratio; NK=not known.

P-values indicate significance of likelihood ratio test on the inclusion of the variable in the model. *Non-convergence in model.

Interactions and robustness

Of the 38 possible pairwise interaction terms across the five cancer types, 19 were significant at a 95% level in a likelihood ratio test comparing the model with and without interaction terms. Of these five were between stage and SCN and due to geographic variation in excess mortality by unknown stage. Four were associated with small subcohorts and showed no clear pattern in the excess mortality. Four were significant overall but had no individual combination of joint variables that was significant. One was owing to high excess lung cancer mortality in the N58 network being concentrated in the most-deprived quintile. One interaction between sex and stage was because of colorectal cancer excess mortality being higher in women specifically for stage 3, and one interaction between sex and age was because of worse colorectal outcomes in older women compared with men. Finally, there were four significant interactions between age and stage (data shown in Supplementary Table 6) because of higher colorectal and ovarian cancer mortality in older persons with stage 3 cancer and worse lung cancer outcomes in stage 1 and stage 2 lung cancer in persons aged 80–99 and 90–99 years. The interaction was also significant for prostate cancer, but no interaction terms were individually significant (and thus this interaction is also counted above).

The effect of using life tables from 2009 was estimated to increase the reported survival by approximately 0.2% compared with an estimate of what would have resulted from using 2012 life tables. This estimate was produced by recalculating survival with 2006 life tables and assuming a linear change in background mortality from 2006 to 2012.

Discussion

The results presented here demonstrate the value of the substantial improvement in the completeness of staging data collected by the NCRS in England. Early-stage presentation is more likely in younger persons for ovarian and prostate cancers, and for screening age for colorectal and breast cancers. Early-stage presentation is (marginally) less likely in the more income-deprived. The analysis clarifies the expected patterns of survival, and it shows that age and stage have the greatest association on the absolute value of the 1-year survival and the adjusted excess mortality rate ratio for early mortality, whereas for sex, income deprivation and geographic area of residence the impact is smaller.

For sex, the fact that the rate ratios are close to unity implies that some of the difference in relative survival by sex is driven by age and stage case-mix, concordant with earlier work (Riaz et al, 2013). Excess mortality rate ratios between the least and most deprived of up to 1.4 are seen, and in colorectal cancer the associated difference in relative survival is 6.5%. This rate ratio is broadly in agreement with previously calculated mortality rate ratios of ∼1.1 per increment in income deprivation quintile (McPhail et al, 2013) but could also be influenced by variables outside the model, including comorbidity, differential uptake of potentially curative treatment (Peake, 2014) and the frequency of emergency presentation, all of which are higher in the more income-deprived.

Examination of the interaction between independent variables considered shows worse outcomes in stage 3 colorectal cancers in women. The relationship between age and stage in colorectal and ovarian cancers (with outcomes worse for stage 3 in older persons) and lung cancer (with outcomes worse for early stages in older persons) may indicate opportunities for re-evaluation of clinical pathways. Geographic variation in the mortality rate for unknown stage cancers is also observed, although this is likely owing to varying stage completeness.

Several SCNs show excess mortality rate ratios that are above unity and statistically significant at a 95% level. This may reflect variation not captured by the model, for example, owing to varying comorbidity, route of presentation or treatment, although, owing to the multiple testing performed, some may be simple random variations. There is significant scope for more work to describe this variation down to much smaller geographical and even health-care provider level, which is likely to be more able to help understand the reasons for such variation.

Major strengths of this study are the high stage completeness, between 80 and 90 percent, and that the data cover the whole population of England. There are four principal limitations of the study. First, the unavailability for this study of route to diagnosis, previously shown to affect short-term survival (McPhail et al, 2013), means that some of the excess mortality attributed to older age and higher stage might be a result of differences in route of presentation. However, McPhail et al (2013) also found age and stage to be the most predictive independent variables. Second, the study is limited to a single year of data, 2012, complicating the interpretation of the data in comparison with earlier studies. Additionally, during the processing of data from 2012 the registration function of the previous eight regional cancer registries merged to form the National Cancer Registration Service. Standardisation of practice can be expected in the future to improve stage completeness to a consistent level nationally, but some bias in completeness with geography still exists. Third, the model does not capture data on comorbidities. However, the influence of comorbidity on short-term mortality is lower than that of age and stage (McPhail et al, 2013), and thus this is unlikely to change the main conclusions of the study. Last, the outcome measured is the excess mortality in the year after diagnosis; although this is calculated by summing the excess mortality across four periods in the year, it does not attempt to characterise any non-proportionality of hazards in this period.

The Office for National Statistics publishes yearly overall cancer survival figures for a number of cancers, currently complete to tumours diagnosed up to 2011 (Solomon et al, 2013) and predicted for tumours diagnosed up to 2013 (Solomon et al, 2014). Direct comparison with these is complicated by differences in methodology, but for colon and breast (and also for oesophagus and stomach cancers – shown in Supplementary Online Material) cancers the agreement is good – ∼2% or less between years and generally 1% or less for a direct comparison of 2011. There is a notable difference in lung cancer, with overall relative survival reported here being larger (33.4 in men and 39.4 in women, 2012) than those reported by Office for National Statistics (ONS) (31.6 in men and 34.7 in women, 2011). However, ONS predictions for 2013 are larger again than figures reported here (36.1 in men, 42.2 in women, 2013, predicted). It is possible that the difference may be an artefact explicable by a change in practice in the recording of diagnosis date by the NCRS owing to better access to data from radiological systems and from the National Lung Cancer Audit (NLCA). However, there have been major improvements in the treatment rates for lung cancer, particularly in surgical resection rates, between 2005 and 2012, as demonstrated by the NLCA (Health and Social Care Information Centre, 2013). Khakwani et al (2013), using NLCA data, showed a significant fall in the hazard ratio of death in early-stage lung cancer between 2005 and 2010, and more recent preliminary data from the NLCA also demonstrates an improvement in overall median and one-year survival for lung cancer patients between 2010 and 2013 (MD Peake, 2014, personal communication), supporting the increase observed here.

Survival by stage has been previously published for the UK for cancers diagnosed in 2004–07 (Maringe et al, 2012, 2013; Walters et al, 2013a, 2013b). Again, direct comparison is complicated by differences in methodology and the differing definition of the tumour cohorts. However, it appears that breast and colon cancers exhibit the largest improvement in stage-specific survival for later stage cancers, whereas lung cancer has greater improvements for earlier-stage cancers. Ovarian cancer shows little change in stage-specific survival with the exception of unknown stage, which shows an improvement in all cancers compared. This increase in the survival of unknown cases is consistent with a reduction in the proportion of unknown cases that are of advanced stage.

Implications

The results presented here support the work underpinning campaigns promoting early diagnosis, with survival estimates shown to be better for the cancers diagnosed at earlier stage. For all cancer types examined, diagnosis before stage 4 substantially increases the 1-year survival. For lung and ovarian cancer, any shift to all lower stages at diagnosis brings substantial benefit. For these two latter cancer types, there is also scope for increasing the early-stage-specific survival both by the development of more effective treatments and by ensuring the universal application of best current practice to all suitable patients, in other words reducing the large variations in the standards of care that are known to exist (Health and Social Care Information Centre, 2013).

In conclusion, the completeness of stage at diagnosis will allow more accurate comparisons between England and other countries. It will also allow the frequency of early diagnosis to be investigated more comprehensively, to examine regional and local variations and to enable better assessment of the campaigns aimed at promoting the earlier diagnosis of cancer.

Acknowledgments

We acknowledge the hard work of the NCRS staff in collecting the data.

The authors declare no conflict of interest.

Footnotes

Supplementary Information accompanies this paper on British Journal of Cancer website (http://www.nature.com/bjc)

Supplementary Material

Supplementary Table 5
Click here for additional data file. (40KB, xls)
Supplementary Table 6
Click here for additional data file. (44KB, xls)
Supplementary Table 7
Click here for additional data file. (27.5KB, xls)

References

  1. Abdel-Rahman M, Stockton D, Rachet B, Hakulinen T, Coleman MP. What if cancer survival in Britain were the same as in Europe: how many deaths are avoidable. Br J Cancer. 2009;101:S115–S124. doi: 10.1038/sj.bjc.6605401. [DOI] [PMC free article] [PubMed] [Google Scholar]
  2. Cancer Research UK Cancer Survival Group 2006. Life tables for cancer survival analysis. Department of Non-Communicable Disease Epidemiology, London School of Hygiene & Tropical Medicine, UK. 2014. Available at http://www.lshtm.ac.uk/eph/ncde/cancersurvival/tools/ .
  3. Coleman MP, Forman D, Bryant H, Butler J, Rachet B, Maringe C, Nur U, Tracey E, Coory M, Hatcher J, McGahan CE, Turner D, Marrett L, Gjerstorff ML, Johannesen TB, Adolfsson J, Lambe M, Lawrence G, Meechan D, Morris EJ, Middleton R, Steward J, Richards MA, ICBP Module 1 Working Group Cancer survival in Australia, Canada, Denmark, Norway, Sweden, and the UK, 1995—2007 (the International Cancer Benchmarking Partnership): an analysis of population-based cancer registry data. Lancet. 2011;377:9760. doi: 10.1016/S0140-6736(10)62231-3. [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Communities and Local Government 2011. The English Indices of Deprivation 2010. Available at http://www.communities.gov.uk/publications/corporate/statistics/indices2010 .
  5. Corazziari I, Quinn M, Capocaccia R. Standard cancer patient population for age standardising survival ratios. Eur J Cancer. 2004;40:2307–2316. doi: 10.1016/j.ejca.2004.07.002. [DOI] [PubMed] [Google Scholar]
  6. De Angelis R, Sant M, Coleman MP, Francisci S, Baili P, Pierannunzio D, Trama A, Visser O, Brenner H, Ardanaz E, Bielska-Lasota M, Engholm G, Nennecke A, Siesling S, Berrino F, Capocaccia R, EUROCARE-5 Working Group Cancer survival in Europe 1999–2007 by country and age: results of EUROCARE—5-a population-based study. Lancet Oncol. 2014;15:23–34. doi: 10.1016/S1470-2045(13)70546-1. [DOI] [PubMed] [Google Scholar]
  7. Department of Health . Improving Outcomes: A Strategy for Cancer. Department of Health: London, UK; 2011. [Google Scholar]
  8. Dickman PW, Sloggett A, Hills M, Hakulinen T. Regression models for relative survival. Stat Med. 2004;23:51–64. doi: 10.1002/sim.1597. [DOI] [PubMed] [Google Scholar]
  9. Foot C, Harrison T.2011. How to improve cancer survival: Explaining England's relatively poor rates. The Kings Fund.
  10. Health and Social Care Information Centre National Lung Cancer Audit annual reports from 2007 to 2012. 2013.
  11. Holmberg L, Sandin F, Bray F, Richards M, Spicer J, Lambe M, Klint A, Peake M, Strand TE, Linklater K, Robinson D, Møller H. National comparisons of lung cancer survival in England, Norway and Sweden 2001-2004: differences occur early in follow-up. Thorax. 2010;65:436–441. doi: 10.1136/thx.2009.124222. [DOI] [PubMed] [Google Scholar]
  12. Khakwani A, Rich A, Powell H, Tata L, Stanley R, Baldwin D, Duffy J, Hubbard R. Lung cancer survival in England: trends in non-small-cell lung cancer survival over the duration of the National Lung Cancer Audit. Br J Cancer. 2013;109:2058–2065. doi: 10.1038/bjc.2013.572. [DOI] [PMC free article] [PubMed] [Google Scholar]
  13. Maringe C, Walters S, Butler J, Coleman MP, Hacker N, Hanna L, Mosgaard BJ, Nordin A, Rosen B, Engholm G, Gjerstorff ML, Hatcher J, Johannesen TB, McGahan CE, Meechan D, Middleton R, Tracey E, Turner D, Richards MA, Rachet B, ICBP Module 1 Working Group Stage at diagnosis and ovarian cancer survival: evidence from the International Cancer Benchmarking Partnership. Gynecol Oncol. 2012;127:75–82. doi: 10.1016/j.ygyno.2012.06.033. [DOI] [PubMed] [Google Scholar]
  14. Maringe C, Walters S, Rachet B, Butler J, Fields T, Finan P, Maxwell R, Nedrebø B, Påhlman L, Sjövall A, Spigelman A, Engholm G, Gavin A, Gjerstorff ML, Hatcher J, Johannesen TB, Morris E, McGahan CE, Tracey E, Turner D, Richards MA, Coleman MP, ICBP Module 1 Working Group Stage at diagnosis and colorectal cancer survival in six high-income countries: a population-based study of patients diagnosed during 2000-2007. Acta Oncol. 2013;52:919–932. doi: 10.3109/0284186X.2013.764008. [DOI] [PubMed] [Google Scholar]
  15. McPhail S, Elliss-Brookes L, Shelton J, Ives A, Greenslade M, Vernon S, Morris EJA, Richards M. Emergency presentation of cancer and short-term mortality. Br J Cancer. 2013;109:2027–2034. doi: 10.1038/bjc.2013.569. [DOI] [PMC free article] [PubMed] [Google Scholar]
  16. Peake MD. Deprivation, distance and death in lung cancer. Thorax. 2014;70:108–109. doi: 10.1136/thoraxjnl-2014-206153. [DOI] [PubMed] [Google Scholar]
  17. Riaz S, Linklater KM, Møller H, Lüchtenborg M.2013. Diverging trends in lung cancer survival between males and females 1999–2008. NCIN short report. Available at http://www.ncin.org.uk/view?rid=2070 .
  18. Richards M. EUROCARE-4 studies bring new data on cancer survival. Lancet Oncol. 2007;8:752–753. doi: 10.1016/S1470-2045(07)70247-4. [DOI] [PubMed] [Google Scholar]
  19. Richards M. The National Awareness and Early Diagnosis Initiative in England: assembling the evidence. Br J Cancer. 2009;101:S1–S4. doi: 10.1038/sj.bjc.6605382. [DOI] [PMC free article] [PubMed] [Google Scholar]
  20. Richards M. The size of the prize for earlier diagnosis of cancer in England. Br J Cancer. 2009;101:S125–S129. doi: 10.1038/sj.bjc.6605402. [DOI] [PMC free article] [PubMed] [Google Scholar]
  21. Sant M, Allemani C, Capocaccia R, Hakulinen T, Aareleid T, Coebergh JW, Coleman MP, Grosclaude P, Martinez C, Bell J, Youngson J, Berrino F, EUROCARE Working Group Stage at diagnosis is a key explanation of differences in breast cancer survival across Europe. Int J Cancer. 2003;106:416–422. doi: 10.1002/ijc.11226. [DOI] [PubMed] [Google Scholar]
  22. Sobin LH, Gospodarowicz MK, Wittekind Ch.(eds) (2009TNM Classification of Malignant Tumors7th ednWiley-Blackwell: Oxford, UK; ISBN 978-1-4443-3241-4:310. [Google Scholar]
  23. Solomon T, Rachet B, Drummond R, Rowlands S, Brown P, Bannister N, Gordon E, Coleman MP.2014Cancer survival in England: adults diagnosed 2008 to 2012, followed up to 2013 ONS Stat Bull 1–17. . http://www.ons.gov.uk/ons/dcp171778_382524.pdf .
  24. Solomon T, Rachet B, Whitehead S, Coleman MP.2013Cancer survival in England: patients diagnosed 2007–2011 and followed up to 2012 ONS Stat Bull 1–12. . http://www.ons.gov.uk/ons/rel/cancer-unit/cancer-survival/cancer-survival-in-england—patients-diagnosed-2007-2011-and-followed-up-to-2012/stb-cancer-survival-in-england—patients-diagnosed-2007-2011-and-followed-up-to-2012.html .
  25. StataCorp. Stata Statistical Software: Release 12. StataCorp LP: College Station, TX, USA; 2011. [Google Scholar]
  26. Thomson C, Forman D. Cancer survival in England and the influence of early diagnosis: what can we learn from recent EUROCARE results. Br J Cancer. 2009;101:S102–S109. doi: 10.1038/sj.bjc.6605399. [DOI] [PMC free article] [PubMed] [Google Scholar]
  27. Verdecchia A, Francisci S, Brenner H, Gatta G, Micheli A, Mangone L, Kunkler I. EUROCARE-4 Working Group. Recent cancer survival in Europe: a period analysis 2000–2002 of the EUROCARE-4 data. Lancet Oncol. 2007;8:784–796. doi: 10.1016/S1470-2045(07)70246-2. [DOI] [PubMed] [Google Scholar]
  28. Walters S, Maringe C, Butler J, Rachet B, Barrett-Lee P, Bergh J, Boyages J, Christiansen P, Lee M, Wärnberg F, Allemani C, Engholm G, Fornander T, Gjerstorff ML, Johannesen TB, Lawrence G, McGahan CE, Middleton R, Steward J, Tracey E, Turner D, Richards MA, Coleman MP, ICBP Module 1 Working Group Breast cancer survival and stage at diagnosis in Australia, Canada, Denmark, Norway, Sweden and the UK, 2000-2007: a population-based study. Br J Cancer. 2013;108:1195–1208. doi: 10.1038/bjc.2013.6. [DOI] [PMC free article] [PubMed] [Google Scholar]
  29. Walters S, Maringe M, Coleman P, Peake M, Butler J, Young N, Bergström S, Hanna L, Jakobsen E, Kölbeck K, Sundstrøm S, Engholm G, Gavin A, Gjerstorff ML, Hatcher J, Johannesen TB, Linklater KM, McGahan CE, Steward J, Tracey E, Turner D, Richards MA, Rachet B, ICBP Module 1 Working Group Lung cancer survival and stage at diagnosis in Australia, Canada, Denmark, Norway, Sweden and the United Kingdom: a population-based study, 2004-2007. Thorax. 2013;68:551–564. doi: 10.1136/thoraxjnl-2012-202297. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary Table 5
Click here for additional data file. (40KB, xls)
Supplementary Table 6
Click here for additional data file. (44KB, xls)
Supplementary Table 7
Click here for additional data file. (27.5KB, xls)

Articles from British Journal of Cancer are provided here courtesy of Cancer Research UK

RESOURCES