The function lgor_rd computes covariance between mean difference and log odds ratio. See mix.vcov for effect sizes of the same or different types.

md_lgor(r, n1c, n2c, n1t, n2t,
        n12c = min(n1c, n2c), n12t = min(n1t, n2t),
        s2c, s2t, f2c, f2t, sd1c, sd1t)

Arguments

r

Correlation coefficient of the two outcomes.

n1c

Number of participants reporting outcome 1 in the control group.

n2c

Number of participants reporting outcome 2 in the control group.

n1t

Number of participants reporting outcome 1 in the treatment group.

n2t

Number of participants reporting outcome 2 in the treatment group.

n12c

Number of participants reporting both outcome 1 and outcome 2 in the control group. By default, it is equal to the smaller number between n1c and n2c.

n12t

Number defined in a similar way as n12c for the treatment group.

s2c

Number of participants with event for outcome 2 (dichotomous) in the control group.

s2t

Defined in a similar way as s2c for the treatment group.

f2c

Number of participants without event for outcome 2 (dichotomous) in the control group.

f2t

Defined in a similar way as f2c for the treatment group.

sd1c

Sample standard deviation of outcome 1 for the control group.

sd1t

Defined in a similar way as sd1c for the treatment group.

Author

Min Lu

Value

lgorLog odds ratio for outcome 2.
vComputed covariance.

References

Ahn, S., Lu, M., Lefevor, G.T., Fedewa, A. & Celimli, S. (2016). Application of meta-analysis in sport and exercise science. In N. Ntoumanis, & N. Myers (Eds.), An Introduction to Intermediate and Advanced Statistical Analyses for Sport and Exercise Scientists (pp.233-253). Hoboken, NJ: John Wiley and Sons, Ltd.

Wei, Y., & Higgins, J. (2013). Estimating within study covariances in multivariate meta-analysis with multiple outcomes. Statistics in Medicine, 32(7), 119-1205.

Examples

## a simple example md_lgor(r = 0.71, n1c = 34, n2c = 35, n1t = 25, n2t = 32, s2c = 5, s2t = 8, f2c = 30, f2t = 24, sd1t = 0.4, sd1c = 8)
#> $lgor #> [1] 0.6931472 #> #> $v #> [1] 0.484266 #>
## calculate covariances for variable SBP and DD in Geeganage2010 data attach(Geeganage2010)
#> The following objects are masked from Geeganage2010 (pos = 3): #> #> MD_DBP, MD_SBP, nc_D, nc_DBP, nc_DD, nc_SBP, nt_D, nt_DBP, nt_DD, #> nt_SBP, OR_D, OR_DD, sc_D, sc_DD, sdc_DBP, sdc_SBP, sdt_DBP, #> sdt_SBP, SMD_DBP, SMD_SBP, st_D, st_DD, studyID
#> The following objects are masked from Geeganage2010 (pos = 4): #> #> MD_DBP, MD_SBP, nc_D, nc_DBP, nc_DD, nc_SBP, nt_D, nt_DBP, nt_DD, #> nt_SBP, OR_D, OR_DD, sc_D, sc_DD, sdc_DBP, sdc_SBP, sdt_DBP, #> sdt_SBP, SMD_DBP, SMD_SBP, st_D, st_DD, studyID
#> The following objects are masked from Geeganage2010 (pos = 5): #> #> MD_DBP, MD_SBP, nc_D, nc_DBP, nc_DD, nc_SBP, nt_D, nt_DBP, nt_DD, #> nt_SBP, OR_D, OR_DD, sc_D, sc_DD, sdc_DBP, sdc_SBP, sdt_DBP, #> sdt_SBP, SMD_DBP, SMD_SBP, st_D, st_DD, studyID
SBP_DD <- unlist(lapply(1:nrow(Geeganage2010), function(i){md_lgor(r = 0.71, n1c = nc_SBP[i], n2c = nc_DD[i], n1t = nt_SBP[i], n2t = nt_DD[i], sd1t = sdt_SBP[i], s2t = st_DD[i], sd1c = sdc_SBP[i], s2c = sc_DD[i], f2c = nc_DD[i] - sc_DD[i], f2t = nt_DD[i] - st_DD[i])$v})) SBP_DD
#> [1] 5.2513178 6.2654662 1.0052099 0.9848809 0.6028840 6.1345587 0.7115657 #> [8] 0.5185468 1.2726618 0.9592369 0.3712568 2.5232995 2.6107308 6.0917470 #> [15] 0.2320915 1.4941133 6.6681779
## the function mix.vcov() should be used for dataset