I think what you are trying to do could be done by:

```
lst = Tuples[{0, 1}, 4];
Table[Evaluate[Symbol["lst" <> ToString[i]]] = lst[[i]], {i, Length@lst}]
```

So that

```
lst1 == {0,0,0,0}
```

But this is not a useful way to manage vars in Mathematica.

**Edit**

I'll try to show you why having vars `lst1,lst2 ..`

is not useful, and is *against* the "Mathematica way".

Mathematica works better by applying functions to objects. For example, suppose you want to work with `EuclideanDistance`

. You have a point {1,2,3,4} in R^{4}, and you want to calculate the nearest point from your set to this point.

This is easily done by

```
eds = EuclideanDistance[{1, 2, 3, 4}, #] & /@ Tuples[{0, 1}, 4]
```

And the nearest point distance is simply:

```
min = Min[eds]
```

If you want to know which point/s are the nearest ones, you can do:

```
Select[lst, EuclideanDistance[{1, 2, 3, 4}, #] == min &]
```

Now, try to do that same things with your intended `lst1,lst2 ..`

asignments, and you will find it, although not impossible, very,very convoluted.

**Edit**

BTW, once you have

```
lst = Tuples[{0, 1}, 4];
```

You can access each element of the list just by typing

```
lst[[1]]
```

etc. In case you need to loop. But again, loops are NOT the Mathematica way. For example, if you want to get another list, with your elements normalized, don't loop and just do:

```
lstNorm = Norm /@ lst
```

Which is cleaner and quicker than

```
Do[st[i] = Norm@lst[[i]], {i, 1, 16}]
```

You will find that defining downvalues (like st[i]) above) is useful when solving equations, but besides that many operations that in other languages are done using arrays, in Mathematica are better carried out by using lists.

**Edit**

Answering your comment `actually I need each element of array lst to find the value of function such as f[x,y,z,k]=x-y+z+k`

. Such function may be

```
(#1 - #2 + #3 + #4) & @@@ lst
```

or

```
(#[[1]] - #[[2]] + #[[3]] + #[[4]]) & /@ lst
```

Out:

```
{0, 1, 1, 2, -1, 0, 0, 1, 1, 2, 2, 3, 0, 1, 1, 2}
```

HTH!