{"id":17,"date":"2013-02-26T20:32:40","date_gmt":"2013-02-26T20:32:40","guid":{"rendered":"http:\/\/faculty.engineering.ucdavis.edu\/template\/?page_id=17"},"modified":"2016-08-26T23:23:09","modified_gmt":"2016-08-26T23:23:09","slug":"publications","status":"publish","type":"page","link":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"
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Journal Publications<\/strong><\/h2>\n

107.\u00a0J.B. Lin, S. Poh, A. Panitch.\u00a0Controlled release of anti-inflammatory peptides from reducible thermosensitive nanoparticles suppresses cartilage inflammation.<\/a>\u00a0Nanomedicine: Nanotechnology, Biology and Medicine. 2016<\/a><\/p>\n<\/div>\n

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106.\u00a0C. Peterson, C.M. Brophy, P.W. Noble, A. Panitch, C. Lander, A.D. Luber, G. Nicolson, B. Leaker, W. Bradford. \u00a0Phase 1 LPS Challenge Study Of The Safety, Tolerability, Pharmacokinetics (PK) And Pharmacodynamics Of Multi-Day Inhaled (IH) Dosing Of The MAPKAP Kinase II (MK2) Inhibitor, MMI-0100, In Subjects Who Smoke.<\/a>\u00a0Clinical Trials. 1(2) 2016: 3.\u00a0<\/a><\/p>\n

105.\u00a0S.V. Kushchayev, M.B. Giers, D. Hom Eng, N.L. Martirosyan, J.M. Eschbacher, M.M. Mortazavi, N.\u00a0Theodore, A. Panitch, M.C. Preul.\u00a0Hyaluronic acid scaffold has a neuroprotective effect in hemisection spinal cord injury.<\/a>\u00a0Journal of Neurosurgery: Spine. 2016: 1-11.\u00a0<\/a><\/p>\n

104.\u00a0S. Sharma, N. Vazquez-Portalatin, S. Calve, A. Panitch.\u00a0Biomimetic molecules lower catabolic expression and prevent chondroitin sulfate degradation in an osteoarthritic ex vivo model.<\/a>\u00a0ACS biomaterials science & engineering. 2(2): 2016:\u00a0241-250.<\/a><\/p>\n

103.\u00a0M. C. Preul, S. Kushchayev, D. Eng, M. Giers, N. Martirosyan, M. Mortazavi, N. Theodore, V. Sonntag, A. Panitch.\u00a0Hyaluronic Acid Hydrogel Reduces Scarring in Spinal Cord Injury.<\/a>\u00a0Journ. of Neurosurgery. \u00a0123(2) 2015:\u00a0A508-A508.<\/a><\/p>\n

102.\u00a0A.M. Kosinski, J.M. Pothen, A. Panitch, M.P. Sivasankar.\u00a0Dexamethasone Controlled Release on TGF-\u03b21 Treated Vocal Fold Fibroblasts,<\/a>\u00a0Annals of Otology, Rhinology, & Laryngology. 124 (7) 2015:\u00a0572-578.<\/a><\/p>\n

101.\u00a0Y.B. Shui, B.A. Filas, C.J. Siegfried, Q. Zhang, N. Ma, A. Panitch, D.C. Beebe.\u00a0Synthetic Proteoglycan Mimics Preserve Vitreous Structure and Functionin Vitro and in Vivo.<\/a>\u00a0Investigative Ophthalmology & Visual Science. 56(7) 2015:\u00a05109-5109.<\/a><\/p>\n

100.\u00a0A. Kole, J. Noblet, N. Ramchandani, J. Tune, A. Panitch, M. Sturek.\u00a0Collagen-binding Peptide Attenuates Catheter-Induced Coronary Vasospasm.<\/a>\u00a0The FASEB Journal. 29 (1 Supplement) 2015:\u00a0803.3.<\/a><\/p>\n

99.\u00a0A. Lawrence, X. Xu, M.D. Bible, S. Calve, C.P. Neu, A. Panitch.\u00a0Synthesis and characterization of a lubricin mimic 9mLub) to reduce friction and adhesion on the articular cartilage surface.\u00a0Biomaterials, 2015,<\/p>\n

98.\u00a0J. McMasters, A. Panitch.\u00a0Prevention of collagen induced platelet binding and activation by thermosensitive nanoparticles. The American Association of Pharmaceutical Scientists Journal, 2015<\/p>\n

97.\u00a0J.R. Wodicka, N.I. Onunkwo, A.J. Wooley, A. Panitch, K.J. Otto.\u00a0A cell penetrating peptide for inhibition of MAPKAP kinase 2-mediated inflammatory cytokine release following glial cell activation. World Journal of Neuroscience. 2015.\u00a0DOI: 10.4236\/wjns.2015.52012<\/p>\n

96.\u00a0R.S. Scott, A. Ramaswamy, K. Park, A. Panitch.\u00a0Decorin mimic promotes endothelial cell health in endothelial monolayers and endothelial-smooth muscle co-cultures.\u00a0Journal of Tissue Engineering and Regenerative Medicine, 2015.\u00a0DOI: 10.1002\/term.2035<\/p>\n

95.\u00a0N. Vazquez-Portalatin, G.J. Breur, A. Panitch, C.J. Goergen.\u00a0Accuracy of ultrasound-guided intra-articular injections in guinea pig knees.\u00a0Bone and Joint Research, 4(1), 2015:1-5.<\/p>\n

94.\u00a0A.M. Kosinski, M.P. Sivasankar, A. Panitch.\u00a0Varying RGD concentration and cell phenotype alters the expression of extracellular matrix genes in vocal fold fibrosis.\u00a0Journal of Biomedical Materials Research part A. 2015.\u00a0DOI: 10.1002\/jbm.a.35456<\/p>\n

93.\u00a0S. Poh, J.B. Lin, A. Panitch.\u00a0Release of Anti-inflammatory peptides from thermosensitive nanoparticles with degradable cross-links suppresses pro-inflammatory cytokine production.\u00a0Biomacromolecules, 16(4), 2015: 1191-1200.<\/p>\n

92.\u00a0M.F. Mohamed, M.I. Hamed, A. Panitch, M.N. Seleem.\u00a0Targeting methicillin-resistant Staphylococcus aureus with short salt-resistant synthetic peptides.<\/a>\u00a0Antimicrobial agents and chemotherapy. 58(7) 2014:\u00a04113-4122.<\/a><\/p>\n

91. R.A. Scott, A. Panitch.\u00a0PDGF-stimulated smooth muscle cell behavior inhibited by decorin mimic.<\/a>\u00a02014 40th Annual Northeast Bioengineering Conference (NEBEC). 2014: 1-2<\/a><\/p>\n

90.\u00a0K. Stuart, S. Sharma, A. Panitch.\u00a0Development of an aggrecan mimic to halt osteoarthritis progression.<\/a>\u00a0Osteoarthritis and CartilageOsteoarthritis and Cartilage. 22, 2014:\u00a0S473-S474<\/a><\/p>\n

89.\u00a0Q. Zhang, B. Filas, R. Roth, J. Heuser, N. Ma, S. Sharma, A. Panitch, D.C. Beebe, Y. Shui.\u00a0Preservation of the structure of enzymatically-degraded bovine vitreous using synthetic proteoglycan mimics.\u00a0Investigative Ophthalmology & visual science, 55(12), 2014: 8153-8162.<\/p>\n

88.\u00a0R. Scott, A. Panitch.\u00a0Macromolecular Approaches to Prevent Thrombosis and Intimal Hyperplasia Following Percutaneous Coronary Intervention.\u00a0Biomacromolecules, 2014<\/p>\n

87.\u00a0R. Scott, A. Panitch. Decorin Mimic Regulates Platelet-Derived Growth Factor and Interferon-\u03b3 Stimulation of Vascular Smooth Muscle Cell.\u00a0Biomacromolecules, 15(6), 2014:2090-2103.<\/p>\n

86.\u00a0J. Brugnano,\u00a0A. Panitch.\u00a0Matrix Stiffness affects endocytic uptake of MK2-inhibitor peptides.\u00a0PLoS One, 9(1), 2014: e84821.<\/p>\n

85. Y.B. Shui, B. Filas, Q. Zhang, S. Sharma, A. Panitch, D. Beebe.\u00a0Restoration of vitreous structure after degradation.<\/a>\u00a0Investigative Ophthalmology & Visual Science. 54(15) 2013:\u00a03152-3152.<\/a><\/p>\n

84.\u00a0R.L. Bartlett, S. Sharma, A. Panitch.\u00a0Cell-penetrating peptides released from thermosensitive nanoparticles suppress pro-inflammatory cytokine response by specifically targeting inflamed cartilage explants.<\/a>\u00a0Nanomedicine: Nanotechnology, Biology and Medicine. 9(3) 2013:\u00a0419-427.<\/a><\/p>\n

83.\u00a0D. Becker, C. Oakum, E. Reynolds, R. Cook, A. Kirkpatrick, P. Arensdorf, C. Lander, A. Panitch, C. Peterson.\u00a0Aerosol Performance of Spray Dried MMI-0100 from the Microdose Inhaler for Treatment of Pulmonary Fibrosis.<\/a>\u00a0Jour. of Aerosol Med. and Pulmonary Drug Delivery. 26(2) 2013:\u00a0A54-A54.<\/a><\/p>\n

82.\u00a0R. Vittal, A. Fisher, H. Gu, E.A. Mickler, A. Panitch, C. Lander, O.W. Cummings, G.E. Sandusky, D.S. Wilkes.\u00a0Peptide-mediated Inhibition of MK2 Ameliorates Bleomycin-Induced Pulmonary Fibrosis.<\/a>\u00a0American journal of respiratory cell and molecular biology. 2013.\u00a0<\/a><\/p>\n

81.\u00a0R.A. Scott, J.E. Paderi, M. Sturek, A. Panitch.\u00a0Decorin mimic inhibits vascular smooth muscle proliferation and migration.\u00a0PLoS One, 8(11), 2013: e82456.<\/p>\n

80.\u00a0J.L. Brugnano, J. McMasters, A. Panitch.\u00a0Characterization of Endocytic uptake of MK2-Inhibitor Peptides.\u00a0Journal of Peptide Science, 19(10), 2013:629-638.<\/p>\n

79.\u00a0S. Sharma, A. Lee, K. Choi, K. Kim, I. Youn, A. Panitch.\u00a0Biomimetic aggrecan reduces cartilage extracellular matrix from degradation and lowers catabolic activity in ex vivo and in vivo models. Macromolecular Bioscience, 13(9), 2013: 1228-1237.<\/p>\n

78.\u00a0R.A. Scott, A. Panitch.\u00a0Glycosaminoglycans in Biomedicine.\u00a0WIREs Nanomedince & Nanobiotechnology.\u00a05(4), 2013: 388-398.<\/p>\n

77.\u00a0R. Vittal, A. Fisher, H. Gu, E.A. Mickler, A. Panitch, C. Lander, O.W. Cummings, D.S. Wilkes, MAPKAPK2 inhibition with MMI-0100 protects against established bleomycin-induced pulmonary fibrosis in mice.\u00a0American Journal of Respiratory Cell and Molecular Biology, 49(1), 2013: 47-57.<\/p>\n

76.\u00a0R.A. Scott, K. Park, A. Panitch.\u00a0Water Soluble Polymer Films for Intravascular Drug Delivery of Antithrombotic Biomolecules.\u00a0European Journal of Pharmaceutics and Biopharmaceutics.\u00a02013.<\/p>\n

75.\u00a0S. Sharma, A. Panitch, C.P. Neu.\u00a0Incorporation of an Aggrecan Mimic Prevents Proteolytic Degradation of Anisotropic Cartilage Analogs. Acta Biomaterialia, 9(1), 2013: 4618-4625.<\/p>\n

74.\u00a0E.A. Mickler, A.J. Fisher, A. Panitch, C. Lander, O.W. Cummings, D.S. Wilkes, R. Vittal.\u00a0Inhibition Of Mk2 Activity Protects Against Bleomycin-Injured Pulmonary Fibrosis In Mice.\u00a0Am. J. Respir. Crit. Care Med. 185. 2012: 2012.<\/p>\n

73.\u00a0A. Kosinski, J. Brugnano, F. Knight, B. Seal, A. Panitch.\u00a0Synthesis and Characterization of a Poly(lactic-co-glycolic acid) Core + Poly(N-isopropylacrylamide) Shell Nanoparticle System.\u00a0Biomatter, 2(4), 2012: 195-201<\/p>\n

72.\u00a0R. Bartlett, S. Sharma, A. Panitch.\u00a0Cell penetrating peptides released from thermosensitive nanoparticles suppress pro-inflammatory cytokine response by specifically targeting inflamed cartilage explants.\u00a0Nanomedicine: Nanotechnology, Biology, and Medicine, 9(3), 2012: 419-427.<\/p>\n

71.\u00a0R. Bartlett,\u00a0A. Panitch.\u00a0Thermosensitive nanoparticles with pH triggered degradation and release of anti-inflammatory cell penetrating-peptides.\u00a0Biomacromolecules, 13(8), 2012: 2578-2584.<\/p>\n

70.\u00a0A. Hicks, M Caplan, A Panitch, J. Sweeney.\u00a0An Incubatable Direct Current Stimulation System for In Vitro Studies of Mammalian Cells.\u00a0Bioresearch Open Access.\u00a01(4), 2012: 199-203.<\/p>\n

69.\u00a0R.L. Bartlett II, M.R. Medow, A. Panitch, B. Seal.\u00a0Hemocompatible poly(NIPam-MBA-AMPS) colloidal nanoparticles as carriers of anti-inflammatory cell penetrating peptides. Biomacromolecules, 13(4), 2012: 1204-1211.<\/p>\n

68.\u00a0J.C. Bernhard,\u00a0A. Panitch.\u00a0Synthesis and Characterization of an Aggrecan Mimic.\u00a0Acta Biomaterialia.\u00a08(4), 2012: 1543-1550.<\/p>\n

67.\u00a0A. Muto, A. Panitch, N. Kim, K. Park, P. Komalavilas, C.M. Brophy, A. Dardik.\u00a0Inhibition of Mitogen Activated Protein Kinase Activated Protein Kinase II with MMI-0100 reduces intimal hyperplasia ex vivo and in vivo.\u00a0Vascular Pharmacology, 56(1-2), 2011: 47-55.<\/p>\n

66.\u00a0C.M. Rupert Perez, A. Panitch, J. Chmielewski.\u00a0A collagen peptide-based physical hydrogel for cell encapsulation.\u00a0Macromolecular Biosciences, 11(10), 2011: 1426-1431<\/p>\n

65.\u00a0K. O\u2019Shaughnessey, A. Panitch, J. Woodell-May.\u00a0Blood-derived anti-inflammatory protein solution blocks the effect of IL-1\u03b2 on human macrophages in vitro.\u00a0Inflammation Research, 60(10), 2011: 929-936.<\/p>\n

64.\u00a0K. Butterfield, A. Conovaloff, A. Panitch.\u00a0Development of affinity-based delivery of NGF from a chondroitin sulfate biomaterial.\u00a0Biomatter, 1(2), 2011: 174-181.<\/p>\n

63.\u00a0A. Conovaloff,\u00a0A. Panitch.\u00a0Characterization of a chondroitin sulfate hydrogel for nerve root regeneration.\u00a0Journal of Neural Engineering, 2011, 8 056003<\/p>\n

62.\u00a0A. Conovaloff,\u00a0A. Panitch.\u00a0Effects of a synthetic bioactive peptide on neurite growth and nerve growth factor release in chondroitin sulfate hydrogels.\u00a0Biomatter, 1(2), 2011: 165-173.<\/p>\n

61.\u00a0K. Stuart, J. Paderi, P.W. Snyder, L.\u00a0Freeman, A. Panitch.\u00a0Collagen-Binding Peptidoglycans Inhibit MMP Mediated Collagen Degradation and Reduce Dermal Scarring.<\/a>\u00a0PloS one. 6(7). 2011:\u00a0e22139.<\/a><\/p>\n

60.\u00a0V. Kishore, J.E. Paderi, S. Beaudoin, A. Panitch, O. Akkus.\u00a0Incorporation of a decorin biomimetic enhances the mechanical properties of electrochemically aligned collagen threads.\u00a0Acta Biomterialia, 7(6), 2011: 2428-2436.<\/p>\n

59.\u00a0J.L. Brugnano, B.K. Chan, B. L Seal, A. Panitch.\u00a0Cell-penetrating peptides can confer biological function: Regulation of inflammatory cytokines in human monocytes by MK2 inhibitor peptides.<\/a>\u00a0Journal of Controlled Release. 155(2), 2011:\u00a0128-133.<\/a><\/p>\n

58.\u00a0J.E. Paderi, K. Stuart, An. Ramaswamy, A. Panitch.\u00a0Directing collagen type I assembly: Mimicking the structural role of decorin.<\/a>\u00a0Amer. Chem. Soc. 241, 2011.<\/a><\/p>\n

57.\u00a0B.C. Ward, S. Kavalukas, J. Brugnano, A. Barbul, A. Panitch.\u00a0Peptide inhibitors of MK2 show promise for inhibition of abdominal adhesions.\u00a0J. Surg. Res. 169(1), 2011: e27-e36.<\/p>\n

56.\u00a0J.E. Paderi, K. Stuart, K. Park, M. Sturek, A. Panitch.\u00a0The inhibition of platelet adhesion and activation on collagen during balloon angioplasty by collagen-binding peptidoglycans.\u00a0Biomaterials, 32(10), 2011: 2516-2523.<\/p>\n

55.\u00a0C.M. Rupert Perez, A. Panitch, J. Chmielewski.\u00a0A collagen peptide-based physical hydrogel for cell encapsulation.\u00a0Macromolecular Biosciences, 11(10), 2011: 1426-1431<\/p>\n

54.\u00a0L. Joshi, M.M. Shah, C.R. Flynn, A. Panitch.\u00a0Plant-Produced Recombinant Therapeutics.<\/a>\u00a0Encyclopedia of Biotechnology in Agriculture and Food. 2011:\u00a0522-525<\/a><\/p>\n

53.\u00a0B.C. Ward,\u00a0A. Panitch.\u00a0Abdominal Adhesions: Current and Novel Therapies.\u00a0Journal of Surgical Research, 165(1), 2011: 91-111.<\/p>\n

52.\u00a0B. Beier, K. Musick, A. Matsumoto, A. Panitch, E. Nauman, P. Irazoqui.\u00a0Toward a continuous intravascular glucose monitoring system.<\/a>\u00a0Sensors. 11(1), 2010:\u00a0409-424.<\/a><\/p>\n

51.\u00a0L.B. Lopes, C. M. Brophy, C.R. Flynn, Z. Yi, B.P. Bowen, C. Smoke, B. Seal, A. Panitch, P. Komalavilas.\u00a0A novel cell permeant peptide inhibitor of MAPKAP kinase II inhibits intimal hyperplasia in a human saphenous vein organ culture model.\u00a0Journal of Vascular Surgery, 52(6), 2010: 1596-1607.<\/p>\n

50.\u00a0J. Brugnano, B.C. Ward,\u00a0A. Panitch.\u00a0Cell Penetrating Peptides Can Exert Biological Activity: A Review.\u00a0BioMolecular Concepts, 1(2), 2010: 109-116.<\/p>\n

49.\u00a0D.H. Eng, M. Caplan, M. Preul, A. Panitch.\u00a0Hyaluronan Scaffolds \u2013 A Balance between Backbone Functionalization and Bioactivity.\u00a0Acta Biomaterialia, 6(7), 2010: 2407-2414.<\/p>\n

48.\u00a0K.C. Butterfield, A. Conovaloff, A. Panitch.\u00a0Chondroitin sulfate-binding peptides block chondroitin 6-sulfate inhibition of cortical neurite growth.\u00a0Neuroscience Letters, 478(2), 2010: 82-87.<\/p>\n

47.\u00a0S. Chaterji, K. Park, A. Panitch.\u00a0Scaffold-free in vitro arterial mimetics: the importance of smooth muscle-endothelium contact.\u00a0Tissue Engineering, 16(6), 2010: 1901-1912.<\/p>\n

46.\u00a0K.C. Butterfield, M. Caplan,\u00a0A. Panitch.\u00a0Identification and Sequence Composition Characterization of Chondroitin Sulfate-Binding Peptides through Peptide Array Screening.\u00a0Biochemistry, 49(7), 2010 1549-1555.<\/p>\n

45.\u00a0L.B. Lopes, E.J. Furnish, P. Komalavilas, C.R. Flynn, P. Ashby, A. Hansen, D.P. Ly, G. P. Yang, M.T. Longaker, A. Panitch, C.M. Brophy.\u00a0Cell Permeant Peptide Analogues of the Small Heat Shock Protein, HSP20, Reduce TGF-\u03b21-Induced CTGF Expression in Keloid Fibroblasts. Investigative Dermatology, 129(3), 2009: 590-598.<\/p>\n

44.\u00a0A. Conovaloff, H-W. Wang, J. Cheng, A. Panitch.\u00a0Imaging Growth of Neurites in Conditioned Hydrogel by Coherent Anti-Stokes Raman Scattering Microscopy.\u00a0Organogenesis,\u00a05(4) 2009: 149-155.<\/p>\n

43.\u00a0B.C. Ward, B.L. Seal, C.M. Brophy, A. Panitch.\u00a0Design of a Bioactive Cell-Penetrating, Peptide: When a Transduction Domain Does More Than Transduce.\u00a0J. Peptide Sci. 15(10), 2009: 668-674 (NIHMSID 212825).<\/p>\n

42.\u00a0A. Ishwar, K.J. Jeong, A. Panitch, O. Akkus.\u00a0Raman Spectroscopic Investigation of GAG-Peptide Interactions.\u00a0Applied Spectroscopy, 63(6), 2009: 636-641.<\/p>\n

41.\u00a0L. Lopes, C. Flynn, P. Komalavilas, A. Panitch, C.M. Brophy, B.L. Seal.\u00a0Inhibition of HSP27 Phosphorylation by a Novel Cell-permeant MAPKAP Kinase 2 Inhibitor.\u00a0Biochemical and Biophysical Research Communications, 382(3), 2009: 535-539<\/p>\n

40.\u00a0J. Paderi, R. Sistiabudi, A. Ivanisevic, A. Panitch.\u00a0Collagen-Binding Peptidoglycans: A Biomimetic Approach to Modulate Collagen Fibrillogenesis for Tissue Engineering Applications.\u00a0Tissue Engineering, 15(10), 2009: 2991-2999.<\/p>\n

39.\u00a0K.J. Jeong,\u00a0A. Panitch.\u00a0The Interplay between Covalent and Physical Interactions within Environment Sensitive Hydrogel.\u00a0Biomacromolecules, 10(5), 2009: 1090-1099.<\/p>\n

38.\u00a0R. Sistiabudi, J. Paderi, A. Panitch, A. Ivanisevic.\u00a0Modification of Native Collagen with Cell-Adhesive Peptide to Promote RPE Cell Attachment on Bruch\u2019s Membrane. Biotechnology and Bioengineering, 102(6), 2008: 1723-1729.<\/p>\n

37.\u00a0K. Stuart,\u00a0A. Panitch.\u00a0Characterization of Gels Composed of Blends of Collagen I, Collagen III, and Chondroitin Sulfate.\u00a0Biomacromolecules, 10(1), 2008: 25-31.<\/p>\n

36.\u00a0K. Stuart,\u00a0A. Panitch.\u00a0Influence of Chondroitin Sulfate on Collagen Gel Structure and Mechanical Properties at Physiologically Relevant Levels.\u00a0Biopolymers 89(10), 2008: 841-851.<\/p>\n

35.\u00a0L.B. Lopes, E.J. Furnish, P. Komalavilas, C.R. Flynn, P. Ashby, A. Hansen, D.P. Ly, G.P. Yang, M.T. Longaker, A. Panitch, C.M. Brophy.\u00a0Cell Permeant Peptide Analogues of the Small Heat Shock Protein, HSP20, Reduce TGF-\u03b21-Induced CTGF Expression in Keloid Fibroblasts. Investigative Dermatology, 129(3), 2008: 590-598.<\/p>\n

34.\u00a0J.E. Paderi,\u00a0A. Panitch.\u00a0Design of a Synthetic Collagen-Binding Peptidoglycan that Modulates Collagen Fibrillogenesis.\u00a0Biomacromolecules, 9(9), 2008: 2562-2566.<\/p>\n

33.\u00a0K.J. Jeong, K. Butterfield,\u00a0A. Panitch.\u00a0A novel assay to probe heparin-peptide interactions using peptide stabilized gold nanoparticles.\u00a0Langmuir, 24(16), 2008: 8794-8800.<\/p>\n

32.\u00a0S. Padalkar, J. Zhao, K.Stuart, A. Panitch, J. Rickus, L. Stanciu.\u00a0Preparation of biomolecule gel matrices for electron microscopy.<\/a>\u00a0Ultramicroscopy, 108, 2008:\u00a0309-313.<\/a><\/p>\n

31.\u00a0P. Komalavilas, L..B. Lopes, C.R. Flynn, C. Smoke, B. Seal, A. Panitch, C.M. Brophy.\u00a0Reduction of heat shock protein 27 phosphorylation inhibits the development of intimal hyperplasia.<\/a>\u00a0The FASEB Journal, 22, 2008:\u00a0902.6-902.6.<\/a><\/p>\n

30.\u00a0L. B. Lopes, E. Furnish, P. Komalavilas, B. L. Seal, A. Panitch, M.V.L.B. Bentley, C.M. Brophy.\u00a0Enhanced skin penetration of P20 phosphopeptide using protein transduction domains. European Journal of Pharmaceutics and Biopharmaceutics, 68 (2), 2008: 441-445.<\/p>\n

29.\u00a0S. Padalkar, Y. Zhao, K. Stuart, A. Panitch, J. Rickus, L. Stanciu. Preparation of Biomolecule Gel Matrices for Electron Microscopy Ultramicroscopy.\u00a0108(4), 2007: 309-313.<\/p>\n

28.\u00a0E. Horn, M. Beaumont, A. Harvey, M. Preul,\u00a0A. Panitch. Influence of Cross-Linked Hyaluronan Hydrogels on Neurite Outgrowth and Recovery from Spinal Cord Injury. Journal of Neurosurgery-Spine, 6(2), 2007: 133-40<\/p>\n

27.\u00a0P. Stice, A. Gilletti, A. Panitch, J. Muthuswamy.\u00a0Thin microelectrodes reduce GFAp expression in the implant site in rodent somatosensory cortex. Journal of Neuroscience Methods, Journal of Neurological Engineering, 4, 2007: 42-53.<\/p>\n

26.\u00a0B. Seal,\u00a0A. Panitch.\u00a0Physical Matrices Stabilized by Enzymatically Sensitive Covalent Crosslinks.\u00a0Acta Biomaterialia, 2(3) 2006: 241-251.<\/p>\n

25.\u00a0B. Seal,\u00a0A. Panitch.\u00a0Viscoelastic Behavior of Environmentally Sensitive Biomimetic Polymer Matrices.\u00a0Macromolecules, 39(6), 2006: 2268-2274.<\/p>\n

24.\u00a0L.B. Lopes, C.M. Brophy, E. Furnish, C.R. Flynn, O. Sparks, P. Komalavilas, L. Joshi, A. Panitch, V.L.B. Bentley,\u00a0Comparative Study of the Skin Penetration of Protein Transduction Domains and a Conjugated Protein. Pharmaceutical Research, 22(5) 2005: 750-7.<\/p>\n

23.\u00a0C. Dreiza, C. Brophy, P. Komalavilas, M. Pallero, J. Murphy-Ullrich, E. Furnish, L. Joshi, M. von Rechenberg, J. Ho, B. Richardson, N. Xu, Y. Zhen, J.M. Peltier, A. Panitch. Transducible Heat Shock Protein 20 (HSP20) Phosphopeptide Alters Cytoskeletal Dynamics. FASEB J 19(2) 2005: 261-3.<\/p>\n

22.\u00a0B.A. Koeneman, K. Lee, A. Singh, J. He, G.B. Raupp, A. Panitch, D.G. Capco. An Ex Vivo Method for Evaluating the Biocompatibility of Neural Electrodes in Rat Brain Slice Cultures. Journal of Neuroscience Methods, 137(2) 2004: 257-263.<\/p>\n

21. D. J. Tessier, P. Komalavilas, B.\u00a0Liu, C.K. Kent, J.S. Thresher, C.M. Dreiza, A. Panitch, L. Joshi, E. Furnish, W. Stone, R. Fowl, C.M. Brophy. Transduction of peptide analogs of the small heat shock-related protein HSP20 inhibits intimal hyperplasia. Journal of Vascular Surgery, 40(1), 2004: 206-214.<\/p>\n

20.\u00a0L. Joshi, M.\u00a0M. Shah, C.R.\u00a0Flynn, A. Panitch.\u00a0Plant\u2010Produced Recombinant Therapeutics.<\/a>\u00a0Encyclopedia of Plant and Crop Science. 2004:\u00a0969-972.<\/a><\/p>\n

19.\u00a0L.Joshi, M.M. Shah, C. R. Flynn, A. Panitch.\u00a0Post\u2010Translational Modifications and Recombinant Therapeutic Proteins.<\/a>\u00a0Encyclopedia of Plant and Crop Science. 2004: 1- 4.<\/a><\/p>\n

18.\u00a0B. Seal,\u00a0A. Panitch. Physical Polymer Matrices Based on Affinity Interactions Between Peptides and Polysaccharides. Biomacromolecules, 4(6), 2003: 1572-1582.<\/p>\n

17.\u00a0P.J. Stice, A. Panitch, J. Muthuswamy.\u00a0Improved viability of chronic neural implants using thin microelectrodes.<\/a>\u00a0IEEE. 2, 2003: 1987-1989.<\/a><\/p>\n

16. C.R.\u00a0Flynn, P. Komalavilas, D. Tessier, J. Thresher, E.\u00a0Niederkofler, R.W. Nelson, A. Panitch, L. Joshi, C.M. Brophy. Transduction of biologically active motifs of the small heat shock related protein, HSP20, leads to relaxation of vascular smooth muscle. Faseb J, 17(10), 2003: 1358-60.<\/p>\n

15. D.\u00a0Tessier, P. Komalavilas, A. Panitch, L. Joshi, C.M. Brophy. The small heat shock protein, HSP20, is dynamically associated with the actin cross-linking protein, actinin. J Surg Res, 111(1), 2003: 152-157.<\/p>\n

14.\u00a0A. Panitch, B. Seal.\u00a0Biologically-based self-assembling hydrogels.<\/a>\u00a0Amen. Chem. Soc. 224,\u00a0U493-U493.<\/a><\/p>\n

13.\u00a0S. Halstenberg, A. Panitch, S. Rizzi, H. Hall, and J.A. Hubbell. Biologically Engineered Protein-graft-Poly(Ethylene Glycol) Hydrogels: A Cell-Adhesive and Plasmin-Degradable Biosynthetic Material for Tissue Repair.\u00a0Biomacromolecules, 3(4), 2002: 710-723.<\/p>\n

12.\u00a0B.L. Seal*, T. Otero*, and A. Panitch. Polymeric Biomaterials for Tissue and Organ Regeneration. Materials Science and Engineering R: Reports. 43(4-5), 2001: 147-230.<\/p>\n

11.\u00a0S. Sakiyama-Elbert, A. Panitch and J. A. Hubbell. Development of Growth Factor Fusion Proteins for Cell-Triggered Drug Delivery. FASEB J. 15(7), 2001: 1300-1302.<\/p>\n

10.\u00a0K. D.\u00a0Zio, E. Welsh, A. Panitch, S. Heilshorn, P. Nowatski, D. Tirrell.\u00a0New macromolecular architectures for control of cell and tissue behavior.<\/a>\u00a0Amer. Chem. Soc. 221, 2001:\u00a0U146-U146.<\/a><\/p>\n

9.\u00a0S.I. Helms Tillery, P.J. Rousche, K. Hausmann, D. Hall, M. Beaumont, A. Panitch, D.R. Kipke.\u00a0Nerve growth factor dependent changes in electrophysiology measured in a neurotrophic electrode.<\/a>\u00a0IEEE. 1, 2001:\u00a0741-744.<\/a><\/p>\n

8.\u00a0T. Tamura, T. Yamaoka, S. Kunki, A. Panitch and D. A. Tirrell. Effects of Temperature and Pressure on the Aggregational Properties of an Engineered Elastin Model Peptide in Aqueous Solution. Biomacromolecules. 1(4) 2000: 552-5.<\/p>\n

7.\u00a0S.Sakiyama-Elbert, A. Panitch, J. Hubbell.\u00a0Development of novel growth factor fusion proteins with exogenous crosslinking substrates for cellularly triggered delivery.<\/a>\u00a0Annals of Biomedical Engineering. 28,\u00a02000.<\/a><\/p>\n

6.\u00a0J. Williams, D. Pellinen, D. Pivin, M. Holecko, R. Vetter, P. Rousche, S. Massia, A. Panitch, D. Kipke.\u00a0Hybrid neural implants with integrated bioactive capability.<\/a>\u00a0Annals of Biomedical Engineering. 28, 2000.\u00a0<\/a><\/p>\n

5.\u00a0S.\u00a0Sakiyama-Elbert, A. Panitch, J.A. Hubbell.\u00a0Development of novel growth factor fusion proteins with exogenous immobilization domains for cellularly controlled drug delivery.<\/a>\u00a0Proceedings of the International Symposium on Controlled Release of Bioactive Materials. 27, 2000: 970-971.<\/a><\/p>\n

4.\u00a0A. Panitch, D.A.Tirrell.\u00a0Artificial Extracellular Matrix Proteins for Graft Design.<\/a>\u00a0RG Landes. 1, 1999:\u00a0577-581.<\/a><\/p>\n

3.\u00a0A. Panitch, T. Yamaoka, M. J. Fournier, T. L. Mason, D. A. Tirrell. Design and Biosynthesis of Elastin-Like Artificial Extracellular Matrix Proteins Containing Periodically Spaced Fibronectin CS5 Domains. Macromolecules. 32, 1999: 1701-1704.<\/p>\n

2.\u00a0A. Panitch, K. Matsuki, E. Cantor, S. J. Cooper, E. D. T. Atkins, M. J. Fournier, T. L. Mason and D. A. Tirrell.Poly(L-alanylglycine): \u2018Multigram-Scale Biosynthesis, Chrystallization, and Structural Analysis of Chain-Folded Lamella\u2019. Macromolecules. 30, 1997: 42-49.<\/p>\n

1.\u00a0A. Panitch, M. J. Fournier, T. L. Mason and D. A. Tirrell. Design and Assembly of Artificial Protein-Based Materials. Journal of Biological Chemistry. 18, 1994: 283.<\/p>\n<\/div>\n

\n

Patents<\/h2>\n<\/div>\n
\n

15.\u00a0J.E. Paderi, A. Panitch.\u00a0Collagen-targeted nanoparticles.<\/a>\u00a0U.S. Patent App. No.:\u00a014\/884,646. 2016.\u00a0<\/a><\/p>\n

14.\u00a0A. Panitch, B. Seal.\u00a0Cell-permeant peptide-based inhibitor of kinases.<\/a>\u00a0U.S. Patent No.:\u00a09,327,008. 2016.<\/a><\/p>\n

13.\u00a0A. Panitch, J.C. Bernhard, J.E. Paderi, S. Sharma.\u00a0Hyaluronic acid-binding synthetic peptidoglycans, preparation, and methods of use.<\/a>\u00a0U.S. Patent No.:\u00a09,217,016. 2015.<\/a><\/p>\n

12.\u00a0A. Panitch, J.E. Paderi, S.Sharma, K.A. Stuart, N. Marie Vazquez-Portalatin.\u00a0Extracellular matrix-binding synthetic peptidoglycans.<\/a>\u00a0U.S. Patent \u00a0No.:\u00a09,200,039. 2015.\u00a0<\/a><\/p>\n

11.\u00a0J.E. Paderi, A. Panitch.\u00a0Collagen-targeted nanoparticles.<\/a>\u00a0U.S. Patent No.:\u00a09173919. 2015.<\/a><\/p>\n

10.\u00a0A.\u00a0Panitch.\u00a0Polypeptide for treating or preventing adhesions.<\/a>\u00a0U.S. Patent No.:\u00a09034815. 2015.<\/a><\/p>\n

9.\u00a0A. Panitch, J.E. Paderi, K. Park, K. Stuart, S. Higbee.\u00a0Collagen-binding synthetic peptidoglycans, preparation, and methods of use.<\/a>\u00a0U.S. Patent No.:\u00a08,846,003. 2014.<\/a><\/p>\n

8.\u00a0J.E. Paderi, A. Panitch, K. Park, K. Stuart.\u00a0Collagen-binding synthetic peptidoglycans for use in vascular intervention.<\/a>\u00a0U.S. Patent App. No.:\u00a014\/474,832. 2014.<\/a><\/p>\n

7.\u00a0C. Brophy, A. Panitch, C. Parmiter, E. Furnish, P. Komalavilas.\u00a0Methods for promoting wound healing and\/or reducing scar formation.<\/a>\u00a0U.S. Patent No.:\u00a08,765,673. 2014.<\/a><\/p>\n

6.\u00a0A. Panitch, B. Seal, B. Ward.\u00a0Kinase inhibitors and uses thereof.<\/a>\u00a0U.S. Patent No.:\u00a08,741,849. 2014.<\/a><\/p>\n

5.\u00a0A. Panitch, B. Seal, B. Ward.\u00a0Polypeptide inhibitors of HSP27 kinase and uses therefor.<\/a>\u00a0<\/a>U.S. Patent\u00a0No.:\u00a08,536,303. 2013.<\/a><\/p>\n

4.\u00a0A. Panitch, B. Seal, J.L. Brugnano, R.L. Bartlett, S. Sharma, J. Mcmasters.\u00a0Compositions and methods for delivery of kinase inhibiting peptides.<\/a>\u00a0U.S. Patent App. No.:\u00a014\/383,701. 2013.\u00a0<\/a><\/p>\n

3.\u00a0J.E. Paderi, A. Panitch, K. Park, K. Stuart.\u00a0Collagen-binding synthetic peptidoglycans for use in vascular intervention.<\/a>\u00a0<\/a>U.S. Patent App. No.:\u00a013\/806,438. 2011.<\/a><\/p>\n

2.\u00a0C. Lander, A. Panitch, C. Brophy, B. Seal.\u00a0Methods for treating or preventing vascular graft failure.<\/a>\u00a0U.S. Patent App. No.:\u00a013\/700,087. 2011.<\/a><\/p>\n

1. C. Brophy, P. Komalavilas, A. Panitch, B. Seal.\u00a0Reagents and methods for smooth muscle therapies.<\/a>\u00a0U.S. Patent No.:\u00a07,135,453. 2006.<\/a><\/p>\n<\/div>\n","protected":false},"excerpt":{"rendered":"

Journal Publications 107.\u00a0J.B. Lin, S. Poh, A. Panitch.\u00a0Controlled release of anti-inflammatory peptides from reducible thermosensitive nanoparticles suppresses cartilage inflammation.\u00a0Nanomedicine: Nanotechnology, Biology and Medicine. 2016 106.\u00a0C. Peterson, C.M. Brophy, P.W. Noble, A. Panitch, C. Lander, A.D. Luber, G. Nicolson, B. Leaker, W. Bradford. \u00a0Phase 1 LPS Challenge Study Of The Safety, \u2026 Continue reading → <\/span><\/a><\/p>\n","protected":false},"author":3,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"open","template":"template-twocolumns-left.php","meta":{"inline_featured_image":false,"ngg_post_thumbnail":0,"footnotes":""},"class_list":["post-17","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/pages\/17","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/users\/3"}],"replies":[{"embeddable":true,"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/comments?post=17"}],"version-history":[{"count":8,"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/pages\/17\/revisions"}],"predecessor-version":[{"id":243,"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/pages\/17\/revisions\/243"}],"wp:attachment":[{"href":"https:\/\/faculty.engineering.ucdavis.edu\/panitch\/wp-json\/wp\/v2\/media?parent=17"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}