[1] J. P. Sieb, W. KÖhler, “Benefits from Sustained-release Pyridostigmine Bromide in Myasthenia Gravis: Results of a Prospective Multicenter Open-label Trial” Clin Neurol Neurosurg 112, 781–784, 2010.
[2] R. A. Maselli, J. D. Henderson, J.Ng, D. Follette, G. Graves, B. W. Wilson, “Protection of Human Muscle Acetylcholinesterase from Soman by Pyridostigmine Bromide” Muscle Nerve 43, 591–595, 2011.
[3] Q. Y. Tan, M. L. Xu, J. Y. Wu, H. F. Yin, J. Q. Zhang, “Preparation and Characterization of Poly (lactic acid) Nanoparticles for Sustained Release of Pyridostigmine Bromide” Pharmazie 67 (4), 311-8, 2012.
[4] N. Hegazy, M. Demirel, Y. Yazan, “Preparation and in vitro evaluation of pyridostigmine bromide microparticles” Int J Pharm 242, 171–174, 2002.
[5] Y. Huang, T. Tsai, C. Cheng, T. Cham, “Formulation Design of a Highly Hygroscopic Drug (Pyridostigmine Bromide) for its Hygroscopic Character Improvement and Investigation of In vitro/In vivo Dissolution Properties” Drug Dev Ind Pharm 33, 403–416, 2007.
[6] N. Bolourchian, M. Rangchian, M. Foroutan, “Prolonged Release Matrix Tablet of Pyridostigmine Bromide: Formulation and Optimization Using Statistical Methods” Pak J Pharm Sci 25, 607-616, 2012.
[7] Q. Tan, R. Jiang, M. Xu, G. Liu, S. Li, J. Zhang, “Nanosized sustained-release pyridostigmine bromide microcapsules: process optimization and evaluation, of characteristics” Int J Nanomed 8, 737-745, 2013.
[8] S. Bagheri-Khoulenjani, H. Mirzadeh, M. Etrati-Khosroshahi, “Chitosan and Nanohydroxyapatite Roles in Physical and Chemical Characteristics of Gelatin/Chitosan/Nanohydroxyapatite Microspheres” Iran J Polym Sci Technol 23 (6), 487-498, 2011.
[9] S. Bagheri-Khoulenjani, S. M. Taghizadeh, H. Mirzadeh, “An Investigation on the Short-Term biodegradability of Chitosan with Various Moleculare Weight and Degree of Deacetylation” Carbohyd Polym 78, 773-778, 2009.
[10] L. Y. Jiang, Y. B. Li, X. J. Wang, L. Zhang, J. Q. Wen, M. Gong, “Preparation and Properties of Nano-hydroxy apatite/Chitosan/Carboxymethyl Cellulose Composite Scafoold” Carbohyd Polym 74, 680-684, 2008.
[11] F. Naimian, F. Khoylo, R. Beteshobabrud, “The Role of Solvent on Radiation Degradation and Antibacterial Activity of Chitosan Against Pectobacterium Carotovorum” Iran J Polym Sci Technol 23 (4), 305-310, 2010.
[12] H. Mirzadeh, F. Hormozi, M. A. Mohagheghi, N. Yaghobi, S. Amanpour, H. Ahmadi, “Preparation of Chitosan Derived from Shrimps Shell of Persian Gulf as a Blood Hemostasis Agent” Iran Polym J 11, 63-68, 2002.
[13] S. M. Taghizadeh, G. Davari, “Study on Mucoadhesion Properties of Xhitosan” Iran J Polym Sci Technol 20, 515-519, 2007.
[14] Y. Mohamadi, H. Mirzadeh, F. Moztarzadeh, M. Soleimani, E. Jabbari, “Osteogenic Differentiation of Mesenchymal Stem Cells on Novel Three-Dimentional Poly (L-Lactic Acid) / Chitosan / Gelatin/Beta-Tricalcium Phosphate Hybrid Scaffolds” Iran Polym J 16, 57-69, 2007.
[15] F. Afshar-Taromi, F.. Nayeb-Habib, S. Salahshoor-Kordestani, Z. Shariatinia, “A Novel Topical Biocompatible Tissue Adhesive Based on Chitosan-modified Urethane Pre-polymer” Iran Polym J 20 (8), 671-680, 2011.
[16] H.Yang, S. Hua, W. Wang, A. Wang, “Composite Hydrogel Beads Based on Chitosan and Laponite: Preparation, Swelling, and Drug Release Behaviour” Iran Polym J 20 (6), 479-490, 2011.
[17] F. Ganji, M. J. Abdekhodaie, A. Ramazany, “Gelation Time and Degradation Rate of Chitosan as a Thermosensitive Injectable Hydrogel” J Sol-Gel Sci Technol 42, 47-53, 2007.
[18] J. Wu, W. Wei, L. Wang, Z. Su, G. Ma, “A Thermosensitive Hydrogel Based on Quaternized Chitosan and Poly (ethylene glycol) for Nasal Drug Delivery System” Biomaterials 28, 2220–2232, 2007.
[19] E. Khodaverdi, M. Tafaghodi, F. Ganji, K. Abnoos, H. Naghizadeh, “In Vitro Insulin Release from Thermosensitive Chitosan Hydrogel” AAPS Pharm Sci Tech 13 (2), 460-466, 2012.
[20] H. Y. Zhou, Y. P. Zhang, W. F. Zhang, X. G. Chen, “Biocompatibility and Characteristics of Injectable Chitosan-based Thermosensitive Hydrogel for Drug Delivery” Carbohyd Polym 83 (4), 1643-1651, 2011.
[21] A. Chenite, C. Chaput, D. Wang, C. Combes, M. Buschmann, C. Hoemann, J. Leroux, B. Atkinson, F. Binette, A. Selmani, “Novel Injectable Neutral Solutions of Chitosan form Biodegradable Gels In Situ” Biomaterials 21, 2155–2161, 2000.
[22] A. Chenite, C. Chaput, C. H. Combes, A. Selmani, F. Jalal, “Temperature-controlled pH-Dependent Formation of Ionic Polysaccharide Gels” US Patent 6, 344, 488, 2002.
[23] M. Berradaa, A. Serreqia, F. Dabbarha, A. Owusub, A. Guptaa, S. Lehnert, “A Novel Non-toxic Camptothecin Formulation for Cancer Chemotherapy” Biomaterials 26, 2115–2120, 2005.
[24] S. Kempe, H. Metz, M. Bastrop, A. Hvilsom, R. Contri, R. Mäder, “Characterization of Thermosensitive Chitosan-based Hydrogels by Rheology and Electron Paramagnetic Resonance Spectroscopy” Eur J Pharm Biopharm 68, 26–33, 2008.
[25] J. Wu, Z. G. Su, G. H. Ma, “A Thermo- and pH-sensitive Hydrogel Composed of Quaternized Chitosan/glycerophosphate” Int J Pharm 315, 1-11, 2006.
[26] K. E. Crompton, R,J. Prankerd, D. M. Paganin, T. F. Scott, M, K. Horne, D. I. Finkelstein, K. A. Gross, J. S. Forsythe, “Morphology and gelation of thermosensitive chitosan hydrogels’ Biophysic Chemist 117, 47–53, 2005.
[27] E. Ruel-Garie´py, A. Chenite, C. Chaput, S. Guirguis, J. C. Leroux, “Characterization of thermosensitive chitosan gels for the sustained delivery of drugs” Int J Pharm 203, 89–98, 2000.
[28] J. Yan, L. Yang, G. Wang, Y. Xiao, B. Zhang, N. Qi, “Biocompatibility Evaluation of Chitosan-based Injectable Hydrogels for the Culturing Mice Mesenchymal Stem Cells In Vitro” J Biomater Appl 24, 625-637, 2010.
[29] A. Chenite, M. Buschmann, D. Wang, C. Chaput, N. Kandani, “Rheological characterization of thermogelling chitosan / glycerol-phosphate solutions” Carbohyd Polym 46, 39-47, 2001.
[30] G. Arora, K. Malik, I. Singh, S. Arora, V. Rana, “Formulation and evaluation of controlled release matrix mucoadhesive tablets of domperidone using Salvia plebeian gum” J Adv Pharm Technol Res 2 (3), 163–169, 2011.