Typically, the least-significant bit is bit index 0 and the most-significant bit is bit index 7. Using this terminology, we can determine if bit index k is set by taking the bitwise-and with 1 shifted to the left by k. If the bitwise and is non-zero, then that means that index k has a 1; otherwise, index k has a 0. So:
This will correctly determine the value of bits at indices 0...7 of the byte, going from right-to-left (i.e. the least significant bit to the most significant bit, or equivalently from the 1s place to the 27 = 128 place).
Why it works
I figured I should add an explanation of why it works...
1<<0 is 1 = 0000 0001
1<<1 is 2 = 0000 0010
1<<2 is 4 = 0000 0100
As you can see, 1<<k is equivalent to 2k and contains a 1 at exactly the index we are interested and at no other location. Consequently, the bitwise and with 1<<k will either return 0 or 1<<k; it will be 0 if the bit at the index we are interested in is 0 (because 1 and 0 is 0, and all other bits in 1<<k are zero). If the bit we are interested in is 1, then we get a 1 and a 1 in that position, and a 0 and something else, everywhere else.