Find the constant for $int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x^2)(1-(kx)^4)}}} sim Cln(1-k)$

I encounter a problem for Elliptic integral, to find the exact $C$ for

$$int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x^2)(1-(kx)^4)}}} sim Cln(1-k)$$

as $kuparrow1;(0<k<1)$.

to establish such asymptotic behavior around $kuparrow1$ is nothing special, we have

$$begin{aligned}
int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x^2)(1-(kx)^4)}}}
& = int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x)(1+x)(1-kx)(1+kx)(1+(kx)^2)}}} \
& le int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x)(1-kx)}}} = frac{2operatorname{artanh}(sqrt{k})}{sqrt{k}}
end{aligned}$$

and

$$begin{aligned}
int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x^2)(1-(kx)^4)}}}
& ge frac1{2sqrt{2}} int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x)(1-kx)}}} \
& ge frac1{2sqrt{2}} int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-kx)^2}}} = -frac1{2sqrt{2}}frac{ln(1-k)}{k}
end{aligned}$$

notice

$$frac{operatorname{artanh}(sqrt{k})}{sqrt{k}} sim -frac1{2}frac{ln(1-k)}{k} text{ as } kuparrow1$$

What I know is the original integral as well belonging to Elliptic integral of the first kind, namely

$$int_{0}^{1} {frac{mathrm{d}x}{sqrt{(1-x^2)(1-(kx)^4)}}} = frac1{sqrt{1+k^2}}Kleft(frac{2k^2}{1+k^2}right)$$

as little knowledge I have for Elliptic integral, I can’t figure out what exactly $C$ is for such behavior, and I am wondering if there is a relatively fundamental way to find it.

thanks in advance for any suggestion.