The Raman microscopy technique is used to characterize the temperature-induced evolution of the pore structures of a macroporous N-isopropylacrylamide (NIPA). The gel is synthesized using a suspension of 45 wt % toluene and 55 wt % pregel NIPA solution. The intensity of the band due to the CH2 bending vibration, centered at 1445 cm-1, is used to monitor the distribution of the polymer chain density in the lateral plane. It is found that the macroporous gel consists of water-rich areas, which can be interpreted as the pores, and polymer-rich areas. At room temperature, the average sizes of the pores and the width of polymer-rich areas are 75 µm and 20 µm, respectively. Both the pores and their surrounding polymer-rich areas have random geometry, as demonstrated by the Raman microimaging. With increased temperature the size of the pores decreases. This process is accompanied by a narrowing of the polymer-rich areas. At higher temperatures polymer chains bunch together and this process accelerates rapidly near the volume phase transition temperature (34 degreesC). Above 36 degreesC, the pore sizes become too small to be resolved using Raman microscopy.