Research in the domain of quantum computation is mainly driven by their promising applications e.g., for factorization or database search. At the same time, physical developments for this emerging technology constantly lead to new constraints to be addressed by logic designers. The limited interaction distance between qubits, the elementary information storage in quantum circuits, is one of the most common restrictions, leading to the fact that, for many quantum architectures, computations can only be performed on adjacent (i.e., nearest neighbor) qubits. Motivated by that, optimization of quantum circuits with respect to this restriction has become an intensely considered research topic. In this paper, we briefly review existing approaches that have been proposed in the past for this purpose. We particularly consider that almost all existing solutions are of heuristic nature, i.e., do not guarantee an optimal solution. In order to address this, exact alternatives are introduced which make use of the deductive power of constraint solvers. By this, we are able to perform a qualitative evaluation of the performance of existing (heuristic) solutions for linear nearest neighbor quantum circuit optimization.