American Journal of Advanced Drug Delivery Open Access

  • ISSN: 2321-547X
  • Journal h-index: 22
  • Journal CiteScore: 9.36
  • Journal Impact Factor: 5.76
  • Average acceptance to publication time (5-7 days)
  • Average article processing time (30-45 days) Less than 5 volumes 30 days
    8 - 9 volumes 40 days
    10 and more volumes 45 days
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Articles published in American Journal of Advanced Drug Delivery have been cited by esteemed scholars and scientists all around the world. American Journal of Advanced Drug Delivery has got h-index 22, which means every article in American Journal of Advanced Drug Delivery has got 22 average citations.

Following are the list of articles that have cited the articles published in American Journal of Advanced Drug Delivery.

  2021 2020 2019 2018 2017

Total published articles

31 18 25 9 14

Conference proceedings

0 0 61 0 0

Citations received as per Google Scholar, other indexing platforms and portals

253 232 219 180 151
Journal total citations count 1671
Journal impact factor 5.76
Journal 5 years impact factor 9.29
Journal cite score 9.36
Journal h-index 22
Important citations

Tan, D. K., Davis, D. A., Miller, D. A., Williams, R. O., & Nokhodchi, A. (2020). Innovations in Thermal Processing: Hot-Melt Extrusion and KinetiSol® Dispersing. AAPS PharmSciTech, 21(8), 1-20.

Suksaeree, J., & Maneewattanapinyo, P. (2020). Ionic Liquid Drug-based Polymeric Matrices for Transdermal Delivery of Lidocaine and Diclofenac. Journal of Polymers and the Environment, 28(10), 2771-2779.

Patil, S., Pandit, A., Gaikwad, G., Dandekar, P., & Jain, R. (2021). Exploring Microfluidic Platform Technique for Continuous Production of Pharmaceutical Microemulsions. Journal of Pharmaceutical Innovation, 16(3), 441-453.

Tambe, S., Jain, D., Agarwal, Y., & Amin, P. (2021). Hot-melt extrusion: highlighting recent advances in pharmaceutical applications. Journal of Drug Delivery Science and Technology, 102452.

Chauhan, G., Shaik, A. A., Kulkarni, N. S., & Gupta, V. (2020). The preparation of lipid-based drug delivery system using melt extrusion. Drug Discovery Today.

Tort, S., & Acartürk, F. (2020). Investigation of propolis and boron containing disinfectants and comparison with who-recommended formulation against COVID-19. Gazi Medical Journal, 532-536.

Qwist, P. K., Sander, C., Bostijn, N., Jessen, V., Rantanen, J., & De Beer, T. (2020). Continuous Manufacturing of a Polymer Stabilized Emulsion Monitored with Process Analytical Technology. AAPS PharmSciTech, 21, 1-11.

Mohammed, Y. B., Ali, S., Dareni, M. A. M., Alshehri, R. M., Aljarallah, R. A., & Alshahrani, W. J. (2019). Comparison of topical 1% diclofenac sodium gel and its performance with Marketed gel (Rofenac).

Dhaval, M., Sharma, S., Dudhat, K., & Chavda, J. (2020). Twin-Screw Extruder in Pharmaceutical Industry: History, Working Principle, Applications, and Marketed Products: An In-depth Review. Journal of Pharmaceutical Innovation, 1-25.

Bostijn, N., Van Renterghem, J., Dhondt, W., Vervaet, C., & De Beer, T. (2018). A continuous manufacturing concept for a pharmaceutical oral suspension. European Journal of Pharmaceutical Sciences, 123, 576-583.

Marreto, R. N., Cardoso, G., dos Santos Souza, B., Martin-Pastor, M., Cunha-Filho, M., Taveira, S. F., ... & Alvarez-Lorenzo, C. (2020). Hot melt-extrusion improves the properties of cyclodextrin-based poly (pseudo) rotaxanes for transdermal formulation. International Journal of Pharmaceutics, 586, 119510.

Thakkar, R., Ashour, E. A., Shukla, A., Wang, R., Chambliss, W. G., Bandari, S., ... & Repka, M. A. (2020). A comparison between lab-scale and hot-melt-extruder-based anti-inflammatory ointment manufacturing. AAPS PharmSciTech, 21(5), 1-14.

Bostijn, N., Van Renterghem, J., Vanbillemont, B., Dhondt, W., Vervaet, C., & De Beer, T. (2019). Continuous manufacturing of a pharmaceutical cream: Investigating continuous powder dispersing and residence time distribution (RTD). European Journal of Pharmaceutical Sciences, 132, 106-117.

Ren, Y., Mei, L., Zhou, L., & Guo, G. (2019). Recent perspectives in hot melt extrusion-based polymeric formulations for drug delivery: Applications and innovations. Aaps Pharmscitech, 20(3), 1-12.

Thakur, S. S., Solloway, J., Stikkelman, A., Seyfoddin, A., & Rupenthal, I. D. (2018). Phase transition of a microemulsion upon addition of cyclodextrin–applications in drug delivery. Pharmaceutical development and technology, 23(2), 167-175.

Szabó, E., Démuth, B., Galata, D. L., Vass, P., Hirsch, E., Csontos, I., ... & Nagy, Z. K. (2019). Continuous Formulation Approaches of Amorphous Solid Dispersions: Significance of Powder Flow Properties and Feeding Performance. Pharmaceutics, 11(12), 654.

Sarabu, S., Bandari, S., Kallakunta, V. R., Tiwari, R., Patil, H., & Repka, M. A. (2019). An update on the contribution of hot-melt extrusion technology to novel drug delivery in the twenty-first century: part II. Expert opinion on drug delivery, 16(6), 567-582.

Nasr, M., Karandikar, H., Abdel-Aziz, R. T., Moftah, N., & Paradkar, A. (2018). Novel nicotinamide skin-adhesive hot melt extrudates for treatment of acne. Expert opinion on drug delivery, 15(12), 1165-1173.

Thakkar, R., Thakkar, R., Pillai, A., Ashour, E. A., & Repka, M. A. (2020). Systematic screening of pharmaceutical polymers for hot melt extrusion processing: A comprehensive review. International journal of pharmaceutics, 576, 118989.

Ramya, M. G., Akki, R., & Kathirvel, S. (2018). Formulation and in Vitro Evaluation of Sustained Release Tableted Microspheres of Gemcitabine. International Journal of PharmTech Research, 11(3), 287-297.