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Introduction • Statistics are increasingly prevalent in medical practice, and for those doing research, statistical issues are fundamental. It is extremely important therefore, to understand basic statistical ideas relating to research design and data analysis, and to be familiar with the most commonly used methods of analysis. • Although data analysis is certainly an important part of the statistical process, there is an equally vital role to be played in the design of the research project. Without a properly designed study, the subsequent analysis may be unsafe, and/or a complete waste of time and resources. • • • • • • • • • • • • Types of data Descriptive statistics Data distributions Comparative statistics Non-parametric tests Paired data Comparison of several means Comparing proportions Exploring the relationship between 2 variables Correlation Linear regression Survival analysis Proportion of total .15 .1 900 .05 0 0 100 400 1000 Platelet count 1500 Types of Data • Categorical – binary or dichotomous e.g. diabetic/non-diabetic, smoker/non-smoker – nominal e.g. AB/B/AB/O, short-sighted/longsighted/normal – ordered categorical (ordinal) e.g. stage 1/2/3/4, mild/moderate/severe • Discrete numerical - e.g. number of children 0/1/2/3/4/5+ • Continuous - e.g. Blood pressure, age • Other types of data – – – – – – ranks, e.g. preference between treatments percentages, e.g. % oxygen uptake rates or ratios, e.g. numbers of infant deaths/1000 scores, e.g. Apgar score for evaluating new-born babies visual analogue scales, e.g. perception of pain survival data – two components, outcome and time to outcome Descriptive Statistics • For continuous variables there are a number of useful descriptive statistics – Mean - equal to the sum of the observations divided by the number of observations, also known as the arithmetic mean – Median - the value that comes half-way when the data are ranked in order – Mode - the most common value observed – Standard Deviation - is a measure of the average deviation (or distance) of the observations from the mean – Standard Error of the mean - is measure of the uncertainty of a single sample mean as an estimate of the population mean Data Distributions • Frequency distribution – If there are more than about 20 observations, a useful first step in summarizing quantitative data is to form a frequency distribution. This is a table showing the number of observations at different values or within certain ranges. If this is then plotted as a bar diagram a frequency distribution is obtained. 20 Std. Dev = 11.43 Mean = 34.3 0 N = 1712.00 0 6. -6 .0 .0 65 - 62 .0 .0 61 - 58 .0 .0 57 - 54 .0 .0 53 - 50 .0 .0 49 - 46 .0 .0 45 - 42 .0 .0 41 - 38 .0 .0 37 - 34 .0 .0 33 - 30 .0 .0 29 - 26 .0 .0 25 - 22 .0 .0 21 - 18 .0 17 10 Frequency Histogram of patient ages for HD 80 70 60 50 40 30 PAGE The Normal Distribution • In practice it is found that a reasonable description of many variables is provided by the normal distribution (Gaussian distribution). The curve of the normal distribution is symmetrical about the mean and bell-shaped. The bell is tall and narrow for small standard deviations, and short and wide for large ones. Frequency paraprotein in myeloma 20 18 16 14 12 10 8 6 4 Std. Dev = 18.81 2 Mean = 33.0 0 N = 103.00 0.0 10.0 20.0 30.0 40.0 50.0 60.0 70.0 80.0 90.0 5.0 15.0 25.0 35.0 45.0 55.0 65.0 75.0 85.0 PARAP 20 18 16 14 12 10 8 6 4 Std. Dev = 18.81 2 Mean = 33.0 0 N = 103.00 0.0 10.0 5.0 PARAP 20.0 15.0 30.0 25.0 40.0 35.0 50.0 45.0 60.0 55.0 70.0 65.0 80.0 75.0 90.0 85.0 Duration of disease pre ASCT for HD 700 600 500 400 300 Frequency 200 Std. Dev = 3.90 100 Mean = 3.2 N = 1676.00 0 .0 32 .0 30 .0 28 .0 26 .0 24 .0 22 .0 20 .0 18 .0 16 .0 14 .0 12 0 . 10 0 8. 0 6. 0 4. 0 2. 0 0. Duration of disease (y) Descriptives DOD Mean 95% Confidence Interval for Mean 5% Trimmed Mean Median Variance Std. Deviation Minimum Maximum Range Interquartile Range Skewness Kurtosis Lower Bound Upper Bound Statistic 3.1813 2.9946 Std. Error 9.515E-02 3.3679 2.5920 1.8000 15.174 3.8954 .10 33.40 33.30 2.3000 3.115 12.507 .060 .119 Comparative statistics • When there are two or more sets of observations from a study there are two types of design that must be distinguished: independent or paired. The design will determine the method of statistical analysis • If the observations are from different groups of individuals, e.g. ages of males and females, or spectacle use in diabetics/non-diabetics, then the data is independent. The sample size may vary from group to group • If each set of observations is made on the same group of individuals, e.g. WBC count preand post- treatment, then the data is said to be paired. This indicates that the observations are on the same individuals rather than from independent samples, and so we have the same number of observations in each set of data Independent data • With independent continuous data, we are interested in the mean difference between the groups, but the variability between subjects becomes important. This is because the two sample t test (the most common test used), is based on the assumption that each set of observations is sampled from a population with a Normal Distribution, and that the variances of the two populations are the same. Non-parametric test • If the continuous data is not normally distributed, or the standard deviations are very different, a nonparametric alternative to the t test known as the Mann-Whitney test can be utilised (another derivation of the same test is due to Wilcoxon) 30 93 25 20 15 10 BET2MG 109 107 94 52 7 111 5 0 N= 4 31 67 19 1.00 2.00 3.00 4.00 MMSTAGE T-test Group Statistics BET2MG MMSTAGE 3.00 4.00 N 67 19 Mean 3.6006 7.5179 Std. Deviation 1.45738 5.14869 Std. Error Mean .17805 1.18119 Independent Samples Test Levene's Test for Equality of Variances F BET2MG Equal variances assumed Equal variances not assumed 11.739 Sig . .001 t-test for Eq uality of Means t df Sig . (2-tailed) Mean Difference Std. Error Difference 95% Confidence Interval of the Difference Lower Upper -5.559 84 .000 -3.9173 .70463 -5.31852 -2.51607 -3.279 18.825 .004 -3.9173 1.19453 -6.41906 -1.41553 Mann-Whitney Test Ranks BET2MG MMSTAGE 3.00 4.00 Total N 67 19 86 Mean Rank 36.78 67.18 Sum of Ranks 2464.50 1276.50 Test Statisticsa Mann-Whitney U Wilcoxon W Z Asymp. Sig. (2-tailed) BET2MG 186.500 2464.500 -4.685 <0.0001 a. Grouping Variable: MMSTAGE Group Statistics MMSTAGE 1.00 2.00 BET2MG N Mean 2.1050 2.7852 4 31 Std. Deviation .40673 .96692 Std. Error Mean .20337 .17366 Independent Samples Test Levene's Test for Equality of Variances F BET2MG Equal variances assumed Equal variances not assumed Sig . .964 t-test for Eq uality of Means t .333 df Sig . (2-tailed) Mean Difference Std. Error Difference 95% Confidence Interval of the Difference Lower Upper -1.377 33 .178 -.6802 .49411 -1.68544 .32512 -2.543 8.518 .033 -.6802 .26743 -1.29039 -.06993 Test Statisticsb Mann-Whitney U Wilcoxon W Z Asymp. Sig. (2-tailed) Exact Sig. [2*(1-tailed Sig .)] BET2MG 27.000 37.000 -1.816 .069 a .073 a. Not corrected for ties. b. Grouping Variable: MMSTAGE 60 3 577 50 444 43 7 40 416 83 327 30 NEUTS 20 10 0 N= TBIDOSE 141 122 12 14.4 Neutrophil engraftment following allogeneic SCT for CML Valid NEUTS TBIDOSE 12 14.4 N 141 122 Percent 88.1% 95.3% Cases Missing N Percent 19 11.9% 6 4.7% Total N 160 128 Percent 100.0% 100.0% Descriptives NEUTS TBIDOSE 12 14.4 Mean 95% Confidence Interval for Mean 5% Trimmed Mean Median Variance Std. Deviation Minimum Maximum Range Interquartile Range Skewness Kurtosis Mean 95% Confidence Interval for Mean 5% Trimmed Mean Median Variance Std. Deviation Minimum Maximum Range Interquartile Range Skewness Kurtosis Lower Bound Upper Bound Lower Bound Upper Bound Statistic 22.9787 21.8289 Std. Error .5816 24.1286 22.5816 22.0000 47.692 6.9060 11.00 56.00 45.00 9.0000 1.162 3.184 26.6148 25.5172 .204 .406 .5544 27.7123 26.1184 26.0000 37.495 6.1233 15.00 53.00 38.00 7.2500 1.453 4.157 .219 .435 50 50 40 40 30 30 20 20 10 10 0 0 10.0 NEUTS 15.0 20.0 25.0 30.0 35.0 40.0 45.0 50.0 55.0 15.0 NEUTS 20.0 25.0 30.0 35.0 40.0 45.0 50.0 55.0 200 3 327 87 416 371 444 294 66 43 190 462 561 100 135 302 62 PLATES 287 9 434 108 263 0 N= TBIDOSE 128 98 12 14.4 Platelet engraftment following allogeneic SCT for CML Valid PLATES TBIDOSE 12 14.4 N 128 98 Percent 80.0% 76.6% Cases Missing N Percent 32 20.0% 30 23.4% Total N 160 128 Percent 100.0% 100.0% Descriptives PLATES TBIDOSE 12 14.4 Mean 95% Confidence Interval for Mean 5% Trimmed Mean Median Variance Std. Deviation Minimum Maximum Range Interquartile Range Skewness Kurtosis Mean 95% Confidence Interval for Mean 5% Trimmed Mean Median Variance Std. Deviation Minimum Maximum Range Interquartile Range Skewness Kurtosis Lower Bound Upper Bound Lower Bound Upper Bound Statistic 32.7891 29.4857 Std. Error 1.6694 36.0924 30.5556 29.5000 356.703 18.8866 14.00 186.00 172.00 11.7500 5.244 37.479 42.8776 35.0417 .214 .425 3.9481 50.7134 37.1973 27.0000 1527.572 39.0842 14.00 185.00 171.00 18.0000 2.368 4.780 .244 .483 60 40 50 30 40 30 20 20 10 10 0 5.0 25.0 15.0 PLATES 45.0 35.0 65.0 55.0 85.0 75.0 105.0 95.0 125.0 115.0 145.0 135.0 165.0 155.0 185.0 175.0 195.0 0 10.0 30.0 20.0 PLATES 50.0 40.0 70.0 60.0 90.0 80.0 110.0 100.0 130.0 120.0 150.0 140.0 170.0 160.0 190.0 180.0 Group Statistics NEUTS PLATES TBIDOSE 12 14.4 12 14.4 N Mean 22.9787 26.6148 32.7891 42.8776 141 122 128 98 Std. Deviation 6.9060 6.1233 18.8866 39.0842 Std. Error Mean .5816 .5544 1.6694 3.9481 Independent Samples Test Levene's Test for Equality of Variances F NEUTS PLATES Equal variances assumed Equal variances not assumed Equal variances assumed Equal variances not assumed 2.291 28.139 Sig . .131 .000 t-test for Eq uality of Means t df Sig . (2-tailed) Mean Difference Std. Error Difference 95% Confidence Interval of the Difference Lower Upper -4.486 261 .000 -3.6360 .8105 -5.2320 -2.0401 -4.525 260.837 .000 -3.6360 .8035 -5.2182 -2.0539 -2.557 224 .011 -10.0885 3.9448 -17.8622 -2.3148 -2.354 131.572 .020 -10.0885 4.2865 -18.5679 -1.6091 Test Statistics Mann-Whitney U Wilcoxon W Z P-value (2-tailed) PLATES 6172.500 11023.500 -.204 0.83 NEUTS 5543.500 15554.500 -4.977 0.0006 Describing continuous data • If the data is normally distributed – Mean and standard deviation • If the data is skewed or non-normally distributed or is from a small sample (N<20) – Median and range Comparison of several means • Data sets comprising more than two groups are common, and their analysis often involves the comparison of the means for the component subgroups. It is obviously possible to compare each pair of groups using t tests, but this is not a good approach. It is far better to use a single analysis that enables us to look at all the data in one go, and the method of choice is called analysis of variance • If the data are not normally distributed or have different variances, a non-parametric equivalent to the analysis of variance can be used, and is known as the Kruskal-Wallis test Paired data • When we have more than one group of observations it is vital to distinguish the case where the data are paired from that where the groups are independent. Paired data arise when the same individuals are studied more than once, usually in different circumstances. Also, when we have two different groups of subjects who have been individually matched, for example in a matched pair case-control study, then we should treat the data as paired. • A one sample t test is used to examine the data. The value t is calculated from – t = sample mean - hypothesised mean standard error of sample mean • In a paired analysis where one set of observations are subtracted from the other set, the hypothesised mean is zero. Thus the calculation of the t statistic reduces to – t = sample mean / standard error of sample mean • The non-parametric equivalent to this test is the Wilcoxon matched pairs signed rank sum test A1 A2 A3 A5 A6 A8 A10 I1 I2 I5 Ratio AZU1/GAPDH Samples CD34 MNC 2273 0.0379 0.4328 3667 0.0007 0.1021 2943 0.0003 0.0007 2334 0.014 0.0226 1759 0.0696 0.5604 2164 0.0349 0.3249 3022a 0.159 0.2487 1503 1684 1615 0.6225 0.9253 0.0647 1.4268 0.2571 0.2516 Wilcoxon Signed Ranks Test Ranks N MNC - CD34 Neg ative Ranks Positive Ranks Ties Total 1a 9b 0c 10 Mean Rank 2.00 5.89 Sum of Ranks 2.00 53.00 a. MNC < CD34 b. MNC > CD34 c. MNC = CD34 Test Statisticsb Z Asymp. Sig. (2-tailed) MNC - CD34 -2.599a .009 a. Based on neg ative ranks. b. Wilcoxon Signed Ranks Test Telomere length in Dyskeratosis Congenita parent -4.7163 -4.7163 -4.7163 -3.8798 -1.4062 -5.1662 -2.2144 -4.439 -4.2654 -4.9991 -0.5679 -5.3408 -1.2779 -1.2779 -4.1954 -0.1936 0.1764 -1.0408 1.0755 0.1737 -2.1199 -2.3117 1.2593 0.5821 0.5821 1.3701 1.3701 -1.469 -1.469 child -6.6238 -5.9629 -6.1392 -0.6173 -2.2264 -5.4028 -3.6383 -2.0056 -6.7593 -3.8157 -2.5027 -6.4229 -5.1118 -3.9373 -5.9093 0.4262 -1.5093 2.4508 0.3898 1.4716 -0.4074 1.3426 1.6527 1.3701 -1.469 4.2772 -1.2765 -1.4892 0.8735 Paired Samples Statistics Pair 1 CHILD PARENT Mean -2.0335 -1.9032 N 29 29 Std. Deviation 3.13806 2.27896 Std. Error Mean .58272 .42319 Paired Samples Test Paired Differences Pair 1 CHILD - PARENT Mean -.1303 Std. Deviation 2.09654 Std. Error Mean .38932 95% Confidence Interval of the Difference Lower Upper -.9278 .6672 t -.335 df 28 Sig . (2-tailed) .740 Comparison of groups : continuous data • Paired on non-paired? • If non-paired and normally distributed with similar variances : T-test • If non-paired non-normally distributed or with non-similar variances or very small numbers : Mann-Whitney test • Paired data – paired t-test or Wilcoxon Signed Ranks Test Comparing Proportions • Qualitative or categorical data is best presented in the form of table, such that one variable defines the rows, and the categories for the other variable define the columns. Thus in a European study of ASCT for HD, patient gender was compared between the UK and Europe • The data are arranged in a contingency table • Individuals are assigned to the appropriate cell of the contingency table according to their values for the two variables COUNTRYG * PSEX Crosstabulation Count COUNTRYG Total europe uk 16 16 PSEX Female 610 100 710 Male 828 160 988 Total 1454 260 1714 COUNTRYG * PSEXG Crosstabulation PSEXG COUNTRYG europe uk Total Count % within COUNTRYG % within PSEXG Count % within COUNTRYG % within PSEXG Count % within COUNTRYG % within PSEXG 1.00 828 57.6% 83.8% 160 61.5% 16.2% 988 58.2% 100.0% 2.00 610 42.4% 85.9% 100 38.5% 14.1% 710 41.8% 100.0% Total 1438 100.0% 84.7% 260 100.0% 15.3% 1698 100.0% 100.0% Chi-squared test (2) • A chi-squared test (2) is used to test whether there is an association between the row variable and the column variable. When the table has only two rows or two columns this is equivalent to the comparison of proportions. • The first step in interpreting contingency table data is to calculate appropriate proportions or percentages. The chi-squared test compares the observed numbers in each of the four categories and compares them with the numbers expected if there were no difference between the distribution of patient gender • The greater the differences between the observed and expected numbers, the larger the value of 2 and the less likely it is that the difference is due to chance COUNTRYG * PSEXG Crosstabulation PSEXG COUNTRYG europe uk Total Count % within COUNTRYG % within PSEXG Count % within COUNTRYG % within PSEXG Count % within COUNTRYG % within PSEXG 1.00 828 57.6% 83.8% 160 61.5% 16.2% 988 58.2% 100.0% 2.00 610 42.4% 85.9% 100 38.5% 14.1% 710 41.8% 100.0% Total 1438 100.0% 84.7% 260 100.0% 15.3% 1698 100.0% 100.0% Chi-Square Tests Pearson Chi-Square Continuity Correctiona Likelihood Ratio Fisher's Exact Test Linear-by-Linear Association N of Valid Cases Value 1.418b 1.260 1.428 1.417 df 1 1 1 1 Asymp. Sig. (2-sided) .234 .262 .232 Exact Sig. (2-sided) Exact Sig. (1-sided) .246 .131 .234 1698 a. Computed only for a 2x2 table b. 0 cells (.0%) have expected count less than 5. The minimum expected count is 108.72. Fisher’s Exact Test • When the overall total of the table is less than 20, or if it is between 20 and 40 with the smallest of the four expected values is less than 5, then Fisher’s Exact Test should be used. Crosstab TRMV DISG 3.00 SURV .00 1.00 Total Count % within SURV % within TRMV Count % within SURV % within TRMV Count % within SURV % within TRMV .00 1.00 15 100.0% 88.2% 2 66.7% 11.8% 17 94.4% 100.0% 1 33.3% 100.0% 1 5.6% 100.0% Total 15 100.0% 83.3% 3 100.0% 16.7% 18 100.0% 100.0% Chi-Square Tests DISG 3.00 Pearson Chi-Square Continuity Correctiona Likelihood Ratio Fisher's Exact Test Linear-by-Linear Association N of Valid Cases Value 5.294b .847 3.905 5.000 df 1 1 1 1 Asymp. Sig. (2-sided) .021 .357 .048 Exact Sig. (2-sided) Exact Sig. (1-sided) .167 .167 .025 18 a. Computed only for a 2x2 table b. 3 cells (75.0%) have expected count less than 5. The minimum expected count is .17. • The chi-squared test can also be applied to larger tables, generally called r x c tables, where r denotes the number of rows in the table, and c the number of columns. • The standard chi-squared test for a 2 x c table is a general test to assess whether there are differences among the c proportions. When the categories in the columns have a natural order, however, a more sensitive test is to look for an increasing (or decreasing) trend in the proportions over the columns. This trend can be tested using the chi-squared test for trend. • In the table below the relation between frequency of Cesarean section and maternal foot size is presented Cesarean section Shoe Size <4 4 4.5 5 5.5 6 Total Yes 5 7 6 7 8 10 43 No 17 28 36 41 46 140 308 • The standard chi-squared test of this 2 x 6 table gives and a 2 value of 9.29, with 5 d.f., for which P=0.098. Analysis of the data for trend gives a 2trend = 8.02, with 1 d.f. (P=0.005). Thus there is strong evidence of a linear trend in the proportion of women giving birth by Cesarean section in relation to shoe size. This relation is not causal, but reflects that shoe size is a convenient indicator of small pelvic size Categorical data – comparing proportions • Studies where there are 2 groups and the total number of patients > 40 : Chi-squared test • Studies where there are 2 groups and the total number of patients < 40 or if more than 40 and a single cell has less than 5 : Fisher’s Exact Test • Studies where there are more than 2 groups but not ordered : - Chi-squared test • Studies where there are more than 2 groups which are ordered : - Chi-squared test for trend Exploring the relationship between two variables • Three possible purposes : – a.) assess association e.g. body weight and blood pressure – b.) prediction e.g. height and weight – c.) assess agreement e.g. blood pressure measurement Correlation • Method for investigating the linear association between two continuous variables • The association is measured by the correlation coefficient • A correlation between two variables shows that they are associated but does not necessarily imply a ‘cause and effect’ relationship • A t test is used to test whether the correlation coefficient obtained is significantly different from zero, or in other words whether the observed correlation could simply be due to chance • The significance level is a function of both the size of the correlation coefficient and the number of observations. A weak correlation may therefore be statistically significant if based on a large number of observations, while a strong correlation may fail to achieve significance if there are only a few observations Correlations BET2MG OPG CRP NTX Pearson Correlation Sig . (2-tailed) N Pearson Correlation Sig . (2-tailed) N Pearson Correlation Sig . (2-tailed) N Pearson Correlation Sig . (2-tailed) N BET2MG 1 . 121 -.393** .000 121 .620** .000 121 .395** .000 121 OPG -.393** .000 121 1 . 121 -.220* .015 121 -.465** .000 121 **. Correlation is significant at the 0.01 level (2-tailed). *. Correlation is significant at the 0.05 level (2-tailed). CRP .620** .000 121 -.220* .015 121 1 . 121 .152 .097 121 NTX .395** .000 121 -.465** .000 121 .152 .097 121 1 121 300 P=0.015 200 CRP 100 0 0 OPG 10 20 210 P=<0.0001 180 150 120 90 60 CRP 30 0 0 BET2MG 10 20 30 Problems with correlation analyses • Biological systems are multifactoral so a simple twoway correlation may not be a true reflection of what is being observed • Spurious correlations 110 100 90 80 70 60 50 40 30 2 FOOT SIZE 4 6 8 10 12 Assessing agreement • Neither correlation nor linear regression are appropriate • There may be a very high correlation, but one method gives a systematically higher/lower reading • Linear regression, the data is not independent • The only appropriate way is to subtract one observation from the other, and plot against an index variable Correlation between PCR and TAQman for measuring MRD PCR PCR Pearson Correlation 1.000 TAQ Sig. (2-tailed) N Pearson Correlation Sig. (2-tailed) N 107 .739 0.0006 107 TAQ 1.000 107 .7 .6 .5 .4 .3 .2 PCR .1 0.0 0.0 TAQ .1 .2 .3 .4 .5 .6 .7 .2 .1 0.0 -.1 -.2 DIFFER -.3 -.4 -.5 0 SAMPLE 20 40 60 80 100 120 Paired Samples Test Paired Differences PCR - TAQ 95% Confidence Interval of the Difference Std. Error Mean Std. Deviation Mean Lower Upper 2.830E-02 8.117E-02 7.847E-03 1.274E-02 4.386E-02 t 3.606 df 106 Sig. (2-tailed) 0.0002 Linear regression • Linear regression gives the equation of the straight line that describes how the y variable increases (or decreases) with an increase in the x variable. y is commonly called the dependent variable, and x the independent, or explanatory variable • A t test is used to test whether the gradient b differs significantly from a specified value (usually zero) • Assumptions – for any value of x, y must be normally distributed – the magnitude of the scatter of the points about the regression line is the same throughout the length of the line – the relation between the two variables should be linear 22 20 18 TLENGTH 16 14 12 0 AGE 10 20 30 40 50 60 70 22 20 18 16 14 12 0 AGE 10 20 30 40 50 60 70 Coefficientsa Model 1 (Constant) AGE Unstandardized Coefficients B Std. Error 17.893 .317 -.049 .010 a. Dependent Variable: TLENGTH Standardized Coefficients Beta -.462 t 56.390 -4.809 Sig . .000 .000 4 3 2 1 0 -1 -2 -3 -4 0 AGE 10 20 30 40 50 60 70 Practical application • Y = mx + c • Telomere length = age * -0.049 + 17.89 • Substituting in the above equation for ages of 30 and 60 • 16.42 = 30*-0.049 +17.89 • 14.95 = 60*-0.049 +17.89 22 20 18 16 14 12 0 AGE 10 20 30 40 50 60 70 Survival data • Has 2 components • The event of interest and the time to the event • Special statistical methods are required – it is not appropriate to use tests for categorical data Life Table Analysis • Survival data are usually summarised as survival or Kaplan-Meier curves • Based on a series of conditional probabilities • For example, the probability of a patient surviving 10 days after a transplant, is the probability of surviving nine days, multiplied by the probability of surviving the 10th day given that the patient survived the first nine days. Patient number 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Dead Alive 0 40 80 120 160 200 Days post BMT 240 280 320 Table 1. Life table for fifteen patients who received an allogeneic stem cell transplant Time (days) Status Number at risk Probability of survival Standard error 16* 0 15 1.00 26 1 14 0.93 0.069 66 1 13 0.86 0.094 69* 0 12 74 1 11 0.78 0.113 82* 0 10 88 1 9 0.69 0.129 89* 0 8 117* 0 7 133* 0 6 144* 0 5 172* 0 4 252* 0 3 291* 0 2 305* 0 1 Probability % 100 80 60 40 20 0 0 50 100 150 200 250 Days post BMT 300 350 Outcomes suitable for KaplanMeier analyses • Survival (event of interest is death, patients alive are censored) • Disease-free survival (events of interest are either death or disease relapse, patients alive and in remission are censored) • Primary graft failure • Acute graft versus host disease Overall and leukaemia-free survival for 111 patients with CML in CP allografted with stem cells from HLA-identical sibling donors 100 OS Probability (%) 80 67% 60 45% 40 LFS 20 0 0 1 2 3 Years post BMT 4 5 HH/ICSM May 2003 Probability of graft failure (%) Graft failure following BMT for 1stCP CML with a VUD 20 15 13.2 Gy (n=57) 10 9% 5 14.4 Gy (n=44) 0% 0 0 60 120 180 240 Days post BMT 300 360 ICSM/HH April 2003 Probability of CMV reactivation (%) CMV reactivation following BMT with a VUD effect of ganciclovir treatment 100 80 60 post infection treatment (n=72) 43% 40 35% 20 prophylactic treatment (n=49) 0 0 28 56 84 112 140 168 196 224 252 280 308 336 364 Days post BMT ICSM/HH May 2003 Use of computers for data collection/analysis • Decide what data needs collecting (for statistical purposes) and then try if appropriate design a form (this is best done in a database, eg Microsoft ACCESS) • Get the computer to do as much of the work as possible. ie calculation of ages, surface area etc • Think ahead to what format the spreadsheet/stats package requires the data to be in • For analysis purposes, its much easier to work with numbers and codes, as opposed to descriptions ie instead of male/female or m/f, use 1 or 2 • Use a ‘code’ to identify missing data, eg 999 or something ‘unlikely’ • Check the data before analysis, get ‘descriptive statistics’ • Use appropriate statistical methods • Statistical packages - SPSS, BMDP, STATA, Statgraphics, MINITAB, STATXACT, GENSTAT, SAS Presentation of results • Where possible give actual P values rather than ranges – ie P=0.041 rather than P<0.05 • If a P value is not significant give the actual value and not just NS – ie P=0.15 rather than P=NS • When presenting data it may be more useful to present confidence intervals rather than a P-value – ie lens A was more durable than lens B by 2.4 days (P=0.03), it might be more informative to write - lens A was more durable than lens B by 2.4 days (95%CI 0.3-4.5days) • It is not necessary to give test results – ie t=33.5, 28 dof, P=0.0001 • If a continuous variable is normally distributed present, as a description of the data, the mean and standard deviation, if not normally distributed, a median and range • Don’t quote more significant figures than necessary – ie mean patient age 34.2550 (std dev 11.4337), (std dev 11.4) will suffice 34.3 1.000 0.800 0.600 0.400 0.200 0.000 32DP210 xl-6 Cell Line xl-5 xl-4 xl-3 xl-2 xl-1 32D Adhesion to FN (A490 absorbance units) 1.200 .8 8 .6 .4 XL2 .2 0.0 N= GROUP 36 36 Writing the statistics section in a paper • If power calculations were used to calculate the sample sizes, details should be given – eg Based on samples sizes of x in each arm, we should have been able to detect a difference of y given 80% power at a significance level of 0.05. • State which statistical tests were used (reference obscure ones). – eg in order to investigate the differences between the groups, a t-test was used for continuous data, and a chisquared test for categorical data • If applicable, state whether standard deviations or standard errors are quoted • State whether p-values are from one or twotailed tests – eg all quoted p-values are two-tailed • Not necessary to quote which stats package was used Suggested Reading Material • Essentials of Medical Statistics – Betty Kirkwood • Practical Statistics for Medical Research – Doug Altman • Statistical Methods in Medical Research – Armitage and Berry Summary • If at all possible - consult a statistician before starting your study • Get a feel of your data by plotting results - don’t rely on descriptive statistics alone • Use appropriate statistical tests, not those that give the ‘best’ results