Aim of present study was to develop metoprolol matrix patches using different enhancers. Combination of two hydrophobic polymers, ethyl cellulose and eudragit RL 100 (8 : 2) were used for preparation of unilaminated matrix patch. 10% w/w of isopropyl myristate (IPM), dimethyl sulfoxide (DMSO), span (20 (S20), Tween 20 (T20) and eucalyptus oil as enhancers and 40% of dibutyl phthalate as plasticizer were used. Prepared patches were evaluated for physical appearance, weight uniformity and thickness. FTIR studies were performed to assess compatibility among ingredients and developed formulation. Dissolution and permeation studies were performed to compare effects of enhancers. Surface morphology after release was examined by scanning electron microscopy. Selected formulation was subjected to in vivo studies by randomized crossover design in rabbits (n = 6) for pharmacokinetic comparison with oral solution administration. Physical evaluation revealed that translucent, flexible, non brittle patches of uniform weight and thickness were prepared. Release from patches followed Higuchi model. Mechanism of release was Fickian. Formulation containing IPM showed that release was by anomalous transport. Highest permeation flux was observed for formulation containing IPM with 2-fold enhancement in permeation. Permeation flux for patches was in order of formulation with no enhancer > IPM > T20 > S20 > DMSO = eucalyptus oil. Plasma concentration from in vivo studies exhibited sustained plasma levels of metoprolol after transdermal patch application in comparison to oral solution administration. Pharmacokinetic analysis of in vivo data elucidated that half life was increased 8 times when compared to oral administration, due to controlled release of drug for longer period of time. These findings suggested that hydrophobic transdermal patches of highly water soluble drug metoprolol were successfully prepared with 10% of IPM for sustained systemic delivery for prolonged half life.