Initial-boundary value problems for parabolic equations in unbounded domains with respect
 to the spatial variables were studied by many authors. As is well known, to guarantee the
  uniqueness of the solution of the initial-boundary value problems for linear and some nonlinear parabolic    equations in unbounded domains we need some restrictions on solution's behavior as $|x|\to +\infty$ (for example,  solution's  growth restriction as $|x|\to +\infty$, or belonging of solution to some   functional spaces).
      Note that we need some restrictions on the data-in behavior as
$|x|\to +\infty$ to solvability of the initial-boundary value problems
for parabolic equations considered above.

  However, there are nonlinear parabolic equations for which
the corresponding initial-boundary value problems are unique solvable without
 any conditions at infinity.

  Nonlinear differential equations with variable exponents of the nonlinearity
 appear as mathematical models in various physical processes. In particular, these equations describe electroreological substance flows, image recovering processes, electric current in the conductor with  changing temperature field. Nonlinear differential
   equations with variable exponents of the nonlinearity were intensively studied in many works.
The corresponding generalizations of Lebesgue and Sobolev spaces
       were used in these investigations.

 In this paper we prove the unique solvability of the initial-boundary value problem
 without conditions at infinity for some of the higher-orders anisotropic parabolic equations
 with variable exponents of the nonlinearity. An a priori estimate of the generalized solutions of this problem was also obtained.

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