As a self response and with the purpose of make a wiki to find this solution for those who in the future need a CRT implementation in javascript/typescript:

First think is to implement Modular Multiplicative Inverse, for this task what we try to find is an x such that:
`a*x % modulus = 1`

```
const modularMultiplicativeInverse = (a: bigint, modulus: bigint) => {
// Calculate current value of a mod modulus
const b = BigInt(a % modulus);
// We brute force the search for the smaller hipothesis, as we know that the number must exist between the current given modulus and 1
for (let hipothesis = 1n; hipothesis <= modulus; hipothesis++) {
if ((b * hipothesis) % modulus == 1n) return hipothesis;
}
// If we do not find it, we return 1
return 1n;
}
```

Then following the article and the sample code you gave:

```
const solveCRT = (remainders: bigint[], modules: bigint[]) => {
// Multiply all the modulus
const prod : bigint = modules.reduce((acc: bigint, val) => acc * val, 1n);
return modules.reduce((sum, mod, index) => {
// Find the modular multiplicative inverse and calculate the sum
// SUM( remainder * productOfAllModulus/modulus * MMI ) (mod productOfAllModulus)
const p = prod / mod;
return sum + (remainders[index] * modularMultiplicativeInverse(p, mod) * p);
}, 0n) % prod;
}
```

This way you use ES6 functions such as `reduce`

For this to work with bigints the array of remainders and modules should correspond to a ES2020's BigInt

E.g:

```
x mod 5 = 1
x mod 59 = 13
x mod 24 = 7
```

```
// Declare the problem and execute function
// You can not parse them to BigInt here, but TypeScript will complain of operations between int and bigint
const remainders : bigint[] = [1, 13, 7].map(BigInt)
const modules: bigint[] = [5, 59, 24].map(BigInt)
solveCRT(remainders, modules) // 6031
```