Presently, antimicrobial resistance is a major and worldwide concern due to high rate of mutation in microorganisms, widespread use, lack of efficacy of drugs, and low drug discovery rate. Considering the importance of N-heterocycles as antibiotics, perimidine derivatives 3(a–v) have been synthesized via cyclocondensation reaction of 1,8-diaminonaphthalene and aryl aldehydes. Further, the synthesized perimidines 3(a–v) were screened as potent antimicrobial agents via in-vitro, in-silico, ADME and MD simulation studies. All 22 derivatives 3(a–v) were studied against two-gram +ve (E. coli and P. aeruginosa), two-gram −ve (S. aureus and B. subtilis), and two fungal (A. niger and S. cerevisiae) strains using ciprofloxacin and fluconazole as reference drugs. The in-vitro study results showed that compounds 3e, 3h, 3l, and 3m were the most potent against S. aureus and 3(a–d), 3(g–i), and 3s were the most active against B. subtilis as compared to the standard. Furthermore, molecular docking studies were performed against Dihydrofolate reductase (PDB Id: 3SRW) from S. aureus, DNA gyrase (PDB Id: 4DUH) from E. coli, and ERG11 gene (PDB Id: 4LXJ). Compounds 3f, 3f/3m, and 3o were found to bind efficiently with the highest binding energy − 10.6, − 9.6, and − 11.3kcal/mol depicting the potential inhibitor of 3SRW, 4DUH, and 4LXJ receptor protein, respectively. The drug-likeness properties of compounds were studied using SwissADME program. To further validate these findings, molecular dynamics simulations were conducted to evaluate their binding stability. From simulation studies, it was observed that all the shortlisted compounds displayed stable binding within the active site of the selected proteins.Graphical abstract