Tris(pyrazolyl)methane chelators, L1–L3, containing one or two ether groups at different positions of the azole rings, were synthesized and fully characterized. These chelators enabled the synthesis of fac-[ 99m Tc(CO) 3 {HC[4-(ROCH 2 )pz] 3 }] + (R = Me (Tc1), Et (Tc2)) and fac-[ 99m Tc(CO) 3 {HC[3,5-(EtOCH 2 ) 2 pz] 3 }] + (Tc3) which were identified by HPLC in comparison with the rhenium counterparts. The evaluation of Tc1–Tc3 in CD-1 mice has shown that the number and/or nature of the ether groups greatly influence the biodistribution profile, pharmacokinetics and metabolic stability of these complexes. Tc1 and Tc2, bearing a unique ether substituent at the 4-position of the pyrazolyl ring, undergo metabolic transformation in vivo while Tc3 is not metabolized. The metabolization of Tc1 and Tc2 enhanced their rate of excretion but, most probably, also justify their negligible heart uptake in contrast with the high heart uptake of congener non-metabolizable complexes ( 99m Tc-DMEOP and 99m Tc-TMEOP), which have recently emerged as potential myocardial imaging agents.The attempts made to identify the metabolites of Tc1 and Tc2 have shown that the metabolization of these compounds must involve the ether functions with probable formation of carboxylic acid derivatives. A comparative study with the congener fac-[ 99m Tc(CO) 3 {[4-(MeOCH 2 )pz](CH 2 ) 2 NH(CH 2 ) 2 NH 2 }] + (Tc6) led us to confirm the formation of such type of metabolites. In fact, Tc6 is also metabolized in mice with formation of fac-[ 99m Tc(CO) 3 {[4-(HOCH 2 )pz](CH 2 ) 2 NH(CH 2 ) 2 NH 2 }] + (Tc7) and fac-[ 99m Tc(CO) 3 {[4-(HOOC)pz](CH 2 ) 2 NH(CH 2 ) 2 NH 2 }] + (Tc8), which were chemically identified by HPLC in comparison with the Re congeners (Re7 and Re8).