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Journal of Materials Science
Published in: Journal of Materials Science 15/2017

03-02-2017 | In Honor of Larry Hench

A guided walk through Larry Hench’s monumental discoveries

Authors: Maziar Montazerian, Edgar D. Zanotto

Published in: Journal of Materials Science | Issue 15/2017

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Abstract

Here we review and summarize the groundbreaking scientific researches of the late Professor Larry L. Hench, including several of his key discoveries in materials science and engineering. First, we provide a statistical overview of his exceptional scientific performance using Scopus, Web of Science, and other Web sites to extract statistical data on his scientific publications and patents. Professor Hench achieved an exceptionally high h-index of 77 (Scopus) for the field of materials science and engineering, which resulted from his 340 research papers, 210 conference papers, 41 patents, 24 books, 4 editorial notes, and 3 biographies starting in 1967. Then, we summarize and highlight his seminal articles, books, and patents in several research areas, such as bioactive glasses, optical gel glasses, biocomposites/coatings, glass–ceramics, biophotonics, advanced ceramics, semiconducting and ionic conducting glasses, glass corrosion, and nuclear waste disposal. Prof. Hench not only discovered the first man-made material to form a chemical bond with bone and initiated a whole new field—bioactive glasses and glass–ceramics—but also made several other important scientific discoveries. It is quite clear that he was one of the most influential materials scientists/engineers of all time! We hope that this review is not only useful for all persons interested in materials science and engineering but also encourages students and younger investigators to make use of this accumulated knowledge to design novel materials and discover new applications for glasses and ceramics.
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Gatti AM, Yamamuro T, Hench LL, Andersson OH (1993) In-vivo reactions in some bioactive glasses and glass-ceramics granules. Cells Mater 3(3):283–291
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Rehman I, Hench LL, Bonfield W (1993) Comparison of hydroxycarbonate apatite layers on bioactive glasses with human bone. In: Ducheyne P, Christiansen D (eds) 6th international symposium on ceramics in medicine, Philadelphia, PA, Nov 1993, bioceramics, vol 6, pp 123–128
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Hench LL, West JK (1993) The kinetics of bioactive ceramics. 6. Silica-water–amino acid interactions. In: Ducheyne P, Christiansen D (eds) 6th international symposium on ceramics in medicine, Philadelphia, PA, Nov 1993, bioceramics, vol 6, pp 35–40
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Filgueiras MRT, Latorre G, Hench LL (1993) Solution effects on the surface-reactions of 3 bioactive glass compositions. J Biomed Mater Res 27(12):1485–1493CrossRef
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Oonishi H, Kushitani S, Yasukawa E, Kawakami H, Nakata A, Koh S, Hench LL, Wilson J, Tsuji E, Sugihara T (1994) Bone growth into spaces between 45S5 Bioglass granules. In: Andersson OH, Happonen RP, YliUrpo A (eds) 7th international symposium on ceramics in medicine, Turku, Finland, 28–30 July 1994 bioceramics, vol 7, pp 139–144
100.
Rehman I, Smith R, Hench LL, Bonfield W (1994) FT-Raman spectroscopic analysis of natural bones and their comparison with bioactive glasses and hydroxyapatite. In: Andersson OH, Happonen RP, YliUrpo A (eds) 7th international symposium on ceramics in medicine. Turku, Finland, 28–30 July 1994 bioceramics, vol 7, pp 79–84
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Zhong JP, LaTorre GP, Hench LL (1994) The kinetics of bioactive ceramics. 7. Binding of collagen to hydroxyapatite and bioactive glass. In: Andersson OH, Happonen RP, YliUrpo A (eds) 7th international symposium on ceramics in medicine, Turku, Finland, 28–30 July 1994 bioceramics, vol 7, pp 61–66
102.
West JK, Hench LL (1994) AM-1 molecular-orbital calculations of silica-alanine-nitrogen interaction. J Biomed Mater Res 28(5):625–633CrossRef
103.
Rehman I, Hench LL, Bonfield W, Smith R (1994) Analysis of surface-layers on bioactive glasses. Biomaterials 15(10):865–870CrossRef
104.
Hench LL, West JK (1994) Inorganic pathways for biosynthesis—a molecular-orbital modeling approach. J Vac Sci Technol A Vac Surf Films 12(5):2962–2965CrossRef
105.
Pereira MM, Clark AE, Hench LL (1995) Effect of texture on the rate of hydroxyapatite formation on gel-silica surface. J Am Ceram Soc 78(9):2463–2468CrossRef
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Rehman I, Smith R, Hench LL, Bonfield W (1995) Structural evaluation of human and sheep bone and comparison with synthetic hydroxyapatite by FT-Raman spectroscopy. J Biomed Mater Res 29(10):1287–1294CrossRef
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Lobel KD, West JK, Hench LL (1996) Computational model for protein mediated biomineralization of the diatom frustules. Mar Biol 126(3):353–360CrossRef
109.
Lobel KD, Hench LL (1996) In-vitro protein interactions with a bioactive gel-glass. J Sol-Gel Sci Technol 7(1–2):69–76CrossRef
110.
Pereira MM, Hench LL (1996) Mechanisms of hydroxyapatite formation on porous gel-silica substrates. J Sol-Gel Sci Technol 7(1–2):59–68CrossRef
111.
Stanley HR, Hall MB, Clark AE, King CJ, Hench LL, Berte JJ (1997) Using 45S5 Bioglass cones as endosseous ridge maintenance implants to prevent alveolar ridge resorption: a 5-year evaluation. Int J Oral Maxillofac Implants 12(1):95–105
112.
Oonishi H, Kushitani S, Yasukawa E, Iwaki H, Hench LL, Wilson J, Tsuji EI, Sugihara T (1997) Particulate Bioglass compared with hydroxyapatite as a bone graft substitute. Clin Orthop Relat Res 334:316–325CrossRef
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Lobel KD, West JK, Hench LL (1997) Silicon in connective tissue: semi-empirical molecular orbital models. In: Sedel L, Rey C (eds) 10th international symposium on ceramics in medicine, Paris, France, 05–09 Oct 1997 bioceramics, vol 10, pp 557–560
114.
Latour RA, West JK, Hench LL, Trembley SD, Tian Y, Lickfield GC, Wheeler AP (1997) Adsorption of l-lysine onto silica glass: a synergistic approach combining molecular modeling with experimental analysis. In: Sedel L, Rey C (eds) 10th international symposium on ceramics in medicine, Paris, France, 05–09 Oct 1997 bioceramics, vol 10, pp 541–544
115.
Gatti AM, Hench LL, Monari E, Gonella F, Caccavale F (eds) Test of bioactivity in four different glasses. In: Sedel L, Rey C (eds) 10th international symposium on ceramics in medicine, Paris, France, 05–09 Oct 1997 bioceramics, vol 10, pp 287–290
116.
Fujishiro Y, Oonishi H, Hench LL (1997) Quantitative comparison of in vivo bone generation with particulate Bioglass® and hydroxyapatite as a bone graft substitute. In: Sedel L, Rey C (eds) 10th international symposium on ceramics in medicine, Paris, France, 05–09 Oct 1997 bioceramics, vol 10, pp 283–286
117.
Salinas AJ, Serret A, Vallet-Regi M, Hench LL (1997) Structure and solvation effects of PO4 3−, HPO4 2−, H2PO4− and H3PO4 from AM1 and PM3. In: Sedel L, Rey C (eds) 10th international symposium on ceramics in medicine, Paris, France, 05–09 Oct 1997 bioceramics, vol 10, pp 245–248
118.
Hench LL (1997) Theory of bioactivity: the potential for skeletal regeneration. Anales Quim Int Ed 93(1):S44–S48
119.
West JK, Brennan AB, Clark AE, Hench LL (1997) Molecular orbital models of ring expansion mechanisms in the silica-carbon monoxide system. J Biomed Mater Res 36(2):209–215CrossRef
120.
Hench LL (1997) Sol–gel materials for bioceramic applications. Curr Opin Solid State Mater Sci 2(5):604–610CrossRef
121.
Fujishiro Y, Hench LL, Oonishi H (1997) Quantitative rates of in vivo bone generation for Bioglass® and hydroxyapatite particles as bone graft substitute. J Mater Sci Mater Med 8(11):649–652CrossRef
122.
West JK, Latour R, Hench LL (1997) Molecular modeling study of adsorption of poly-l-lysine onto silica glass. J Biomed Mater Res 37(4):585–591CrossRef
123.
Thompson ID, Hench LL (1998) Mechanical properties of bioactive glasses, glass-ceramics and composites. Proc Inst Mech Eng Part H J Eng Med 212(H2):127–136CrossRef
124.
Hench LL, Wheeler DL, Greenspan DC (1998) Molecular control of bioactivity in sol–gel glasses. J Sol-Gel Sci Technol 13(1–3):245–250CrossRef
125.
Thompson I, Chan C, Robinson P, Revell P, Wilson J, Hench LL (1998) Evaluation of Bioglass® 45S5-Dextran as bone graft substitute. J Dent Res 77:989
126.
Lobel KD, Hench LL (1998) In vitro adsorption and activity of enzymes on reaction layers of bioactive glass substrates. J Biomed Mater Res 39(4):575–579CrossRef
127.
West JK, Brennan AB, Clark AE, Zamora M, Hench LL (1998) Cyclic anhydride ring opening reactions: theory and application. J Biomed Mater Res 41(1):8–17CrossRef
128.
Xynos ID, Hukkanen MVJ, Hench LL, Polak JM (1999) Bioglass 45S5 induces mineralisation in osteoblast cultures in vitro. J Pathol 187:38A–38A
129.
Oonishi H, Hench LL, Wilson J, Sugihara F, Tsuji E, Kushitani S, Iwaki H (1999) Comparative bone growth behavior in granules of bioceramic materials of various sizes. J Biomed Mater Res 44(1):31–43CrossRef
130.
Hench LL (1999) Bioactive glasses and glass-ceramics. In: Bioceramics. Materials science forum, vol 293, pp 37–63
131.
Coleman NJ, Hench LL (2000) A gel-derived mesoporous silica reference material for surface analysis by gas sorption—2. Durability and stability. Ceram Int 26(2):179–186CrossRef
132.
Coleman NJ, Hench LL (2000) A gel-derived mesoporous silica reference material for surface analysis by gas sorption—1. Textural features. Ceram Int 26(2):171–178CrossRef
133.
Sepulveda P, Jones JR, Hench LL (2000) Effect of particle size on Bioglass® dissolution. In: Giannini S, Moroni A (eds) 13th international symposium on ceramic in medicine/symposium on ceramic materials in orthopaedic surgery: clinical results in the year 2000, Bologna, Italy, 22–26 Nov 2000, bioceramics. Key engineering materials, vol 192, no 1, pp 629–633
134.
Cook R, Fielder E, Watson T, Robinson P, Hench LL (2000) Pore characterisation and interconnectivity studies on bioactive 58S sol–gel glass. In: Giannini S, Moroni A (eds) 13th international symposium on ceramic in medicine/symposium on ceramic materials in orthopaedic surgery: clinical results in the year 2000, Bologna, Italy, 22–26 Nov 2000, bioceramics. Key engineering materials, vol 192, no 1, pp 625–628
135.
Bellantone M, Hench LL (2000) Bioactive behaviour of sol–gel derived antibacterial bioactive glass. In: Giannini S, Moroni A (eds) 13th international symposium on ceramic in medicine/symposium on ceramic materials in orthopaedic surgery: clinical results in the year 2000, Bologna, Italy, 22–26 Nov 2000, bioceramics. Key engineering materials, vol 192, no 1, pp 617–620
136.
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Kinser DL, Hench LL (1967) Effect of thermal treatment upon dielectric properties and structure of a lithia-silica glass. Am Ceram Soc Bull 46(4):389
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Tuohig WD, Hench LL (1968) Neutron irradiation effects in thermally treated glasses. Am Ceram Soc Bull 47(4):398
378.
Gokurath CV, Freiman SW, Hench LL (1968) Analysis of thickness error in transmission microscopy of ceramics. Am Ceram Soc Bull 47(4):398
379.
Kinser DL, Hench LL (1969) Electrode polarization in alkali silicate glasses. J Am Ceram Soc 52(12):638–641CrossRef
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Kinser DL, Hench LL (1969) Polarization behavior in binary alkali-silicate glasses. Am Ceram Soc Bull 48(4):444
381.
Hench LL, Kinser DL (1969) Dielectric behavior of binary Li2O and Na2O-silicate glasses during initial stages of crystallization. Am Ceram Soc Bull 48(4):444
382.
Gokularathnam CV, Freiman SW, Dehoff RT, Hench LL (1969) Thickness error in quantitative transmission microscopy of ceramics. J Am Ceram Soc 52(6):327–331CrossRef
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Tuohig WD, Hench LL (1969) Neutron effects in thermally treated glasses. J Nucl Mater 31(1):86–92CrossRef
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Hench LL, Kinser DL, Freiman SW (1968) Structure and properties of thermally treated binary silicate glasses. Am Ceram Soc Bull 47(4):398
385.
Freiman SW, Gould RW, Hench LL (1968) A small angle x-ray scattering study of crystallization in glass. Am Ceram Soc Bull 47(4):398
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Freiman SW, Hench LL (1969) Further analysis of glass crystallization kinetics. J Am Ceram Soc 52(2):111–112CrossRef
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Freiman SW, Hench LL (1969) Mechanical behavior of partially crystallized Li2O–SiO2 glass-ceramics. Am Ceram Soc Bull 48(4):448
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389.
Hench LL, Frieman SW, Kinser DL (1971) Early stages of crystallisation in a Li2O–2SiO2 glass. Phys Chem Glasses 12(2):58–63
390.
Freiman SW, Hench LL (1972) Effect of crystallization on mechanical properties of Li2O–SiO2 glass-ceramics. J Am Ceram Soc 55(2):86–90CrossRef
391.
Hartwig BA, Hench LL (1972) Epitaxy of Poly-l-alanine on l-quartz and a glass-ceramic. J Biomed Mater Res 6(5):413–423CrossRef
392.
Ohuchi F, Clark DE, Hench LL (1979) Effect of crystallization on the auger-electron signal decay in an Li2O·2SiO2 glass and glass-ceramic. J Am Ceram Soc 62(9–10):500–503CrossRef
393.
Palmer RA, Lindberg WR, Hench LL (1979) Fatigue properties of Li2O·2SiO2 glass and glass-ceramic. J Am Ceram Soc 62(5–6):319–320CrossRef
394.
Barrett JM, Clark DE, Hench LL (1979) Durability and strength of Li2O–Al2O3–CaO–SiO2 glass-ceramics. Am Ceram Soc Bull 58(3):378
395.
Mccracken WJ, Clark DE, Hench LL (1982) Aqueous durability of lithium disilicate glass-ceramics. Am Ceram Soc Bull 61(11):1218–1223
396.
Chen XF, Hench LL, Greenspan D, Zhong J, Zhang X (1998) Investigation on phase separation, nucleation and crystallization in bioactive glass-ceramics containing fluorophlogopite and fluorapatite. Ceram Int 24(5):401–410CrossRef
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Rehman I, Karsh M, Hench LL, Bonfield W (2000) Analysis of apatite layers on glass-ceramic particulate using FTIR and FT-Raman spectroscopy. J Biomed Mater Res 50(2):97–100CrossRef
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Crovace MC, Souza MT, Chinaglia CR, Peitl O, Zanotto ED (2016) Biosilicate®—a multipurpose, highly bioactive glass-ceramic. In vitro, in vivo and clinical trials. J Non Cryst Solids 432A(15):90–110CrossRef
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Notingher I, Verrier S, Romanska H, Bishop AE, Polak JM, Hench LL (2002) In situ characterisation of living cells by Raman spectroscopy. Spectrosc Int J 16(2):43–51CrossRef
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Notingher I, Jones JR, Verrier S, Bisson I, Embanga P, Edwards P, Polak JM, Hench LL (2003) Application of FTIR and Raman spectroscopy to characterisation of bioactive materials and living cells. Spectrosc Int J 17(2–3):275–288CrossRef
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Notingher I, Verrier S, Haque S, Polak JM, Hench LL (2003) Spectroscopic study of human lung epithelial cells (A549) in culture: living cells versus dead cells. Biopolymers 72(4):230–240CrossRef
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Notingher I, Gough JE, Hench LL (2004) Study of osteoblasts mineralisation in vitro by Raman micro-spectroscopy. In: Barbosa MA, Monteiro FJ, Correia R et al (eds) 16th international symposium on ceramics in medicine, Porto, Portugal, 06–09 Nov 2003 bioceramics, vol 16. Key engineering materials, vol 254, no 2, pp 769–772
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Hench LL, Notingher I (2004) Nova Test: a biophotonics system for rapid in vitro toxicity testing. Am Ceram Soc Bull 83(2):9601–9603
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Hench LL, Notingher I (2004) A biophotonics system for rapid in vitro toxicity testing. Am Ceram Soc Bull 83(2):14–15
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Verrier S, Notingher I, Polak JM, Hench LL (2004) In situ monitoring of cell death using Raman microspectroscopy. Biopolymers 74(1–2):157–162CrossRef
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Notingher I, Bisson I, Bishop AE, Randle WL, Polak JMP, Hench LL (2004) In situ spectral monitoring of mRNA translation in embryonic stem cells during differentiation in vitro. Anal Chem 76(11):3185–3193CrossRef
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Notingher L, Bisson I, Polak JM, Hench LL (2004) In situ spectroscopic study of nucleic acids in differentiating embryonic stem cells. Vib Spectrosc 35(1–2):199–203CrossRef
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Notingher I, Jell G, Lohbauer U, Salih V, Hench LL (2004) In situ non-invasive spectral discrimination between bone cell phenotypes used in tissue engineering. J Cell Biochem 92(6):1180–1192CrossRef
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Owen CA, Notingher I, Jell G, Selvakumaran J, Stevens MM, Hench LL (2004) Raman spectroscopy as a tool for preliminary drug testing on human cells. J Pharm Pharmacol 56:S51–S52
417.
Notingher I, Selvakumaran J, Hench LL (2004) New detection system for toxic agents based on continuous spectroscopic monitoring of living cells. Biosens Bioelectron 20(4):780–789CrossRef
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Notingher I, Green C, Dyer C, Perkins E, Hopkins N, Lindsay C, Hench LL (2004) Discrimination between ricin and sulphur mustard toxicity in vitro using Raman spectroscopy. J R Soc Interface 1(1):79–90CrossRef
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Jones JR, Vats A, Notingher L, Gough JE, Tolley NS, Polak JM, Hench LL (2005) In situ monitoring of chondrocyte response to bioactive scaffolds using Raman spectroscopy. In: Li P, Zhang K, Colwell CW (eds) 17th international symposium on ceramics in medicine, New Orleans, LA, 08–12 Dec 2004, bioceramics, vol 17. Key engineering materials, vol 284–286, pp 623–626
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Notingher I, Jell G, Notingher PL, Bisson I, Polak JMP, Hench LL (2005) Raman spectroscopy: potential tool for in situ characterization of bone cell differentiation. In: Li P, Zhang K, Colwell CW (eds) 17th international symposium on ceramics in medicine, New Orleans, LA, 08–12 Dec 2004, bioceramics, vol 17. Key engineering materials, vol 284–286, pp 545–548
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Hench LL, Notingher I (2005) A bio-photonics system for rapid in vitro testing of cells and ceramics. In: Li P, Zhang K, Colwell CW (eds) 17th international symposium on ceramics in medicine, New Orleans, LA, 08–12 Dec 2004, bioceramics, vol 17. Key engineering materials, vol 284–286, pp 531–536
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Notingher L, Jell G, Notingher PL, Bisson I, Tsigkou O, Polak JM, Stevens MM, Hench LL (2005) Multivariate analysis of Raman spectra for in vitro non-invasive studies of living cells. J Mol Struct 744:179–185CrossRef
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Notingher I, Hench LL (2006) Raman microspectroscopy: a noninvasive tool for studies of individual living cells in vitro. Expert Rev Med Devices 3(2):215–234CrossRef
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Owen CA, Selvakumaran J, Notingher I, Jell G, Hench LL, Stevens MM (2006) In vitro toxicology evaluation of pharmaceuticals using Raman micro-spectroscopy. J Cell Biochem 99(1):178–186CrossRef
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Owen CA, Notingher I, Hill R, Stevens M, Hench LL (2006) Progress in Raman spectroscopy in the fields of tissue engineering, diagnostics and toxicological testing. J Mater Sci Mater Med 17(11):1019–1023CrossRef
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Jell G, Notingher I, Tsigkou O, Notingher P, Polak JM, Hench LL, Stevens MM (2008) Bioactive glass-induced osteoblast differentiation: a noninvasive spectroscopic study. J Biomed Mater Res Part A 86A(1):31–40CrossRef
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Hench LL, Notingher I (2004–2006) Eliciting of Raman signal from living cell or living cells, e.g. for detecting changes in cell phenotype, involves irradiating the cell with laser having specified wavelength, WO2004005871-A1; AU2003281292-A1; EP1520157-A1; JP2005532547-W; US2006115804-A1
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Fenn MB, Xanthopoulos P, Pyrgiotakis G, Grobmyer SR, Pardalos PM, Hench LL (2011) Raman spectroscopy for clinical oncology. Adv Opt Technol. Article ID 213783. doi:10.​1155/​2011/​213783
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Hench LL, Russell R (1968) Effect of Cr2O3 vaporization on sintering of MgO. Trans Br Ceram Soc 67(9):377–380
430.
Hench LL, Clark DE (1968) A theory of error minimization in X-ray spectrochemical sample preparation. Am Ceram Soc Bull 47(4):411
431.
Hench LL (1969) Characterization of ceramics—instrumental techniques. Am Ceram Soc Bull 48(8):824
432.
Johnson PF, Gehl SM, Hench LL (1974) Quantitative relations between microstructure and electrical properties of TiO2, UO2 AND Ta2O5. Am Ceram Soc Bull 53(4):347
433.
Clark DE, Hench LL, Bates SR (1974) Molybdenum metalizing on beryllia. Am Ceram Soc Bull 53(6):473–477
434.
Clark DE, Hench LL, Bates SR (1974) Molybdenum metalizing of BeO substrates. Am Ceram Soc Bull 53(4):337
435.
Hench LL, Cason BPJ, Housefie LG, Smith DG (1974) Controlled flocculation of wall tile glaze effluent. Am Ceram Soc Bull 53(12):860–864
436.
Scott GJ, Hench LL (1974) Effect of powder compact microstructure on reaction-kinetics. Am Ceram Soc Bull 53(4):315
437.
Bottcher JH, Hench LL (1974) Quantitative-analysis of glass phase effects on dielectric properties of dense alumina. Am Ceram Soc Bull 53(4):347
438.
Hench LL (1988) Ceramics and the challenge of change. Adv Ceram Mater 3(3):203–206CrossRef
439.
Ohuchi F, Vaidyanathan PN, Hench LL, Dutta S (1980) Auger-electron spectroscopy analysis of Y2O3-doped Si3N4 grain-boundary. Am Ceram Soc Bull 59(11):1162
440.
Vaidyanathan PN, Hench LL, Dutta S (1980) Grain-boundary phase in Y2O3-doped Si3N4. Am Ceram Soc Bull 59(11):1161
441.
Bernstein SA, Hench LL, Dutta S (1980) Use of x-ray-emission spectra in analysis of Si3N4 grain-boundaries. Am Ceram Soc Bull 59(11):1161–1162
442.
Hench LL, Freiman SW (1981) Investigation of the oxidation of hot-pressed Si3N4 with infrared reflection spectroscopy (IRRS). J Mater Sci 16(10):2767–2773. doi:10.​1007/​BF02402840 CrossRef
443.
Hench LL, Vaidyanathan PN, Dutta S (1982) Analysis of Si3N4 grain-boundary devitrification. Am Ceram Soc Bull 61(11):1195
444.
Guha JP, Hench LL (1982) Grain-boundary phases in hot-pressed silicon-nitride containing Y2O3 and CeO2 additives. Am Ceram Soc Bull 61(11):1195
445.
Mccracken WJ, Person WB, Hench LL (1985) Polarized infrared reflection spectroscopy of single-crystal lithia-silicates and quartz. J Mater Sci 20(11):3853–3864. doi:10.​1007/​BF00552373 CrossRef
446.
Lee BI, Hench LL (1986) Properties of partially densified SiC/SiO2 gel-matrix composites. Am Ceram Soc Bull 65(11):1477
447.
Lee BI, Hench LL (1987) Molecular composites of SiC/SiO2, SiC/Al2O3, and SiC/TiC. Am Ceram Soc Bull 66(10):1482–1485
448.
Lee BI, Hench LL (1987) Electrophoretic behavior and surface-reactions of sol–gel derived alumina. Colloids Surf 23(3):211–229CrossRef
449.
Chia T, Hench LL, Qin C, Hsieh CK (1990) Laser densification modelling, better ceramics through chemistry IV. In: Zelinski BJJ, Brinker CJ, Clark DE et al (eds) Materials research society symposium proceedings, vol 180, pp 819–824
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West JK, Mecholsky JJ, Hench LL (1999) The application of fractal and quantum geometry to brittle fracture. J Non Cryst Solids 260(1–2):99–108CrossRef
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Wu YQ, Choy KL, Hench LL (2004) Preparation of alpha-alumina platelets by laser scanning. J Am Ceram Soc 87(8):1606–1608CrossRef
452.
Wu YQ, Choy KL, Hench LL (2005) Laser densification of TiO2 films prepared by aerosol assisted vapour deposition. Appl Surf Sci 247(1–4):378–383CrossRef
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Wu YQ, Du J, Choy KL, Hench LL (2007) Laser densification of alumina powder beds generated using aerosol assisted spray deposition. J Eur Ceram Soc 27(16):4727–4735CrossRef
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Wu YQ, Du J, Choy KL, Hench LL (2007) Fabrication of titanium dioxide ceramics by laser sintering green layers prepared via aerosol assisted spray deposition. Mater Sci Eng A Struct Mater Prop Microstruct Process 454:148–155CrossRef
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Hench LL, Lee BL (1989) Crosslinking of polysilastyrene—by heating with dicumyl peroxide, US4804731-A
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Hench LL, Lee BI (1989) Lightweight composite of silicon carbide in silica—is formed by slurrying silicon carbide particulate in silica sol. casting into e.g. mat and gelling, ageing and drying, US4859525-A
457.
Hench LL, Karakoti A, Krishna MSB, Reid D, Seal S, Krishna MSB, Hench L, Krishna MS, Read D, Sil S, Reyd D, Moorthy SBH (2009–2015) Manufacture of functionalized aluminosilicate powder for producing structural material, involves functionalizing aluminosilicate powder with liquid reagent and drying powder, WO2009082442-A1; AU2008341102-A1; EP2222611-A1; CA2712575-A1; CN101977868-A; US2011112272-A1; MX2010006298-A1; KR2011069743-A; JP2011523392-W; IN201002042-P2; RU2010130262-A; HK1153998-A0; RU2485065-C2; SG162859-A1; SG162859-B; AU2008341102-B2; IL205996-A; JP5749931-B2; BR200822065-A2; JP2015143191-A
458.
Seal S, Reid DL, Hench LL (2012) Composition used for scavenging oil from oil–water mixture, comprises functionalized fly ash particles that include bulk portion having functionalized surfaces with reactive groups/materials having hydrophobic groups covalently bound to it, US2012006753-A1; US8318625-B2
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Seal S, Reid DL, Hench LL (2013) Forming functionalized fly ash particles useful e.g. for scavenging oil from oil–water mixture, comprises contacting fly ash particles with hydroxide compound, and reacting the obtained fly ash particles with organic alcohol or organic acid, US2013040803-A1; US8404609-B2
460.
Johnson PF, Nastasi RJ, Hench LL (1973) Ceramic electrodes for use in cortical environment. Am Ceram Soc Bull 52(4):432
461.
Johnson PF, Hench LL (1976) An in vitro model for evaluating neural stimulating electrodes. J Biomed Mater Res 10(6):907–928CrossRef
462.
Johnson PF, Bernstein JJ, Hunter G, Dawson WW, Hench LL (1977) An in vitro and in vivo analysis of anodized tantalum capacitive electrodes—corrosion response, physiology, and histology. J Biomed Mater Res 11(5):637–656CrossRef
463.
Bernstein JJ, Johnson PF, Hench LL, Hunter G, Dawson WW (1977) Cortical histopathology following stimulation with metallic and carbon electrodes. Brain Behav Evol 14(1–2):126–157
464.
Johnson PF, Hench LL (1977) An in vitro analysis of metal-electrodes for use in neural environment. Brain Behav Evol 14(1–2):23–45
465.
Hench LL, Jenkins DA (1967) AC conductivity of a glass semiconductor. Phys Status Solidi 20(1):327–330CrossRef
466.
Hench LL (1967) Compositional effects on AC conductivity of a semiconducting glass. Am Ceram Soc Bull 46(4):462
467.
Hench LL, Daughenbaugh GA (1968) Radiation effects in semiconducting glasses. J Nucl Mater 25(1):58–63CrossRef
468.
Kinser DL, Clark AE, Hench LL (1968) Effects of thermal treatment on electrical properties of a K2PO3–V2O5 semiconducting glass. Am Ceram Soc Bull 47(4):398
469.
Schaake HF, Marietta M, Hench LL (1969) Electron transport phenomena in transition metal oxide glasses. Am Ceram Soc Bull 48(4):442
470.
Murthy MK, Topping JA, Hench LL (1973) Structure of germanate glasses. Abstracts of Papers of the American Chemical Society AUG26, pp 24–24
471.
Gehl SM, Johnson PF, Hench LL (1974) Quantitative microscopy characterization of electronic ceramics. Am Ceram Soc Bull 53(4):347
472.
Abe Y, Shimakawa H, Hench LL (1982) Protonic conduction in alkaline-earth meta-phosphate glasses containing water. J Non Cryst Solids 51(3):357–365CrossRef
473.
Tehrani S, Hench LL, Vanvliet CM, Bosman G (1985) Observation of single-carrier space-charge-limited flow in nitrogen-doped alpha-silicon carbide. 2. Electrical noise. J Appl Phys 58(4):1571–1577CrossRef
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Tehrani S, Kim JS, Hench LL, Vanvliet CM, Bosman G (1985) Observation of single-carrier space-charge-limited flow in nitrogen-doped alpha-silicon carbide. 1. IV characteristics and impedance. J Appl Phys 58(4):1562–1570CrossRef
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Tehrani S, Bosman G, Hench LL, Vanvliet CM (1986) Observation of single carrier space-charge-limited flow in nitrogen-doped alpha-silicon carbide. 3. Computer calculations. J Appl Phys 60(7):2386–2395CrossRef
476.
Vanvliet CM, Bosman G, Hench LL (1988) New perspectives of silicon-carbide—an overview, with special emphasis on noise and space-charge-limited flow. Annu Rev Mater Sci 18:381–421CrossRef
477.
Luo MY, Bosman G, Vanderziel A, Hench LL (1988) Theory and experiments of 1/f noise in schottky-barrier diodes operating in the thermionic-emission mode. IEEE Trans Electron Devices 35(8):1351–1356CrossRef
478.
Abe Y, Hosono H, Ohta Y, Hench LL (1988) Protonic conduction in oxide glasses—simple relations between electrical-conductivity, activation-energy, and the O–H bonding state. Phys Rev B 38(14):10166–10169CrossRef
479.
Abe Y, Hosono H, Hikichi Y, Hench LL (1990) Protonic conduction in PbO–SiO2 glasses—A quantitative estimation. J Mater Sci Lett 9(12):1443–1444CrossRef
480.
Kotama M, Nakanishi K, Hosono H, Abe Y, Hench LL (1991) Evidence for protonic conduction in alkali-free phosphate-glasses. J Electrochem Soc 138(10):2928–2930CrossRef
481.
Abe Y, Hosono H, Akita O, Hench LL (1994) Protonic conduction in phosphate-glasses. J Electrochem Soc 141(6):L64–L65CrossRef
482.
Abe Y, Li GM, Nogami M, Kasuga T, Hench LL (1996) Superprotonic conductors of glassy zirconium phosphates. J Electrochem Soc 143(1):144–147CrossRef
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Abe Y, Hayashi M, Iwamoto T, Sumi H, Hench LL (2005) Superprotonic conducting phosphate glasses containing water. J Non Cryst Solids 351(24–26):2138–2141CrossRef
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Abe Y, Nishizaki S, Muroi T, Kato Y, Hench LL (2006) Conversion of gypsum into a superprotonic conductor. Mater Res Innovations 10(1):17–20CrossRef
485.
Hench LL (1969) Humidity effects in electronic substrates. Am Ceram Soc Bull 48(8):803
486.
Gokularathnam CV, Gould RW, Hench LL (1971) X-ray diffraction analysis of structural changes in glass. Am Ceram Soc Bull 50(4):414
487.
Clark DE, Hench LL (1972) Sample preparation variables in x-ray spectrochemical analysis. Am Ceram Soc Bull 51(4):370
488.
Sanders DM, Person WB, Hench LL (1972) New methods for studying glass corrosion kinetics. Appl Spectrosc 26(5):530–536CrossRef
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Sanders DM, Hench LL, Person WB (1972) structure of corroded binary silicate glass surfaces. Am Ceram Soc Bull 51(4):374
490.
Sanders DM, Hench LL (1972) Automated techniques for analysis of glass corrosion. Am Ceram Soc Bull 51(4):372
491.
Onoda GY, Dove DB, Hench LL (1973) Analysis of glass container coatings by auger-electron spectroscopy. Am Ceram Soc Bull 52(4):379
492.
Sanders DM, Hench LL (1973) Structural-analysis of silica-rich film formation on alkali-silicate glasses. Am Ceram Soc Bull 52(4):379
493.
Sanders DM, Hench LL (1973) Mechanisms of glass corrosion. J Am Ceram Soc 56(7):373–377CrossRef
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Hench LL, Clark AE, Dilmore MF, Ethridge EC (1973) Corrosion of multicomponent glasses. Am Ceram Soc Bull 52(9):704
495.
Sanders DM, Hench LL (1973) Surface-roughness and glass corrosion. Am Ceram Soc Bull 52(9):666–669
496.
Sanders DM, Hench LL (1973) Environmental effects on glass corrosion kinetics. Am Ceram Soc Bull 52(9):662
497.
Hench LL, Sanders DM, Dilmore MF, Ethridge EC (1973) Structural-analysis of corrosion processes of commercial glasses. Am Ceram Soc Bull 52(4):380
498.
Clark AE, Hench LL (1973) Effect of P5+, B3+ and F additions on corrosion of Na2O–CaO–SiO2 glasses. Am Ceram Soc Bull 52(4):379
499.
Sanders DM, Person WB, Hench LL (1974) Quantitative-analysis of glass structure with use of infrared reflection spectra. Appl Spectrosc 28(3):247–255CrossRef
500.
Ethridge EC, Hench LL (1974) Effects of compositional range on alkali-silicate glass corrosion kinetics. Am Ceram Soc Bull 53(4):349
501.
Dilmore MF, Hench LL (1974) Corrosion behavior of Li2O–Al2O3–SiO2 glasses. Am Ceram Soc Bull 53(4):349
502.
Clark DE, Hench LL, Acree WA (1975) Electron-microprobe analysis of Na2O–CaO–SiO2 glass. J Am Ceram Soc 58(11–1):531–532CrossRef
503.
Gokularathnam CV, Gould RW, Hench LL (1975) Effect of water on structure of vitreous silica. Phys Chem Glasses 16(1):13–16
504.
Hench LL (1975) Characterization of glass corrosion and durability. J Non Cryst Solids 19:27–39CrossRef
505.
Clark DE, Acree WA, Hench LL (1976) Electron-microprobe analysis of corroded soda-lime-silica glasses. J Am Ceram Soc 59(9–10):463–464CrossRef
506.
Clark DE, Dilmore MF, Ethridge EC, Hench LL (1976) Aqueous corrosion of soda-silica and soda-lime-silica glass. J Am Ceram Soc 59(1–2):62–65CrossRef
507.
Clark AE, Pantano CG, Hench LL (1976) Auger spectroscopic analysis of Bioglass corrosion films. J Am Ceram Soc 59(1–2):37–39CrossRef
508.
Pantano CG, Hench LL (1977) Cleaning borosilicate glass for biological application. J Test Eval 5(1):66–69CrossRef
509.
Hench LL (1977) Physical-chemistry of glass surfaces. J Non Cryst Solids 25(1–3):343–369CrossRef
510.
Clark DE, Ethridge EC, Dilmore MF, Hench LL (1977) Quantitative-analysis of corroded glass using infrared frequency-shifts. Glass Technol 18(4):121–124
511.
Ethridge EC, Hench LL (1977) Static corrosion of glass. Am Ceram Soc Bull 56(3):330
512.
Ethridge EC, Hench LL (1977) Mechanisms of glass corrosion. Am Ceram Soc Bull 56(3):330
513.
Dilmore MF, Hench LL (1977) Role of aluminum ions in glass durability. Am Ceram Soc Bull 56(3):330
514.
Dilmore MF, Hench LL (1977) Role of mixed-alkali effect on glass durability. Am Ceram Soc Bull 56(3):330
515.
Dilmore MF, Clark DE, Hench LL (1978) Chemical durability of Na2O–K2O–CaO–SiO2 glasses. J Am Ceram Soc 61(9–10):439–443CrossRef
516.
Hench LL, Clark DE (1978) Physical-chemistry of glass surfaces. J Non Cryst Solids 28(1):83–105CrossRef
517.
Dilmore MF, Clark DE, Hench LL (1978) Aqueous corrosion of lithia-alumina-silicate glasses. Am Ceram Soc Bull 57(11):1040–1044
518.
Palmer RA, Hench LL (1979) Nondestructive evaluation of surface flaws using infrared reflection spectroscopy. Am Ceram Soc Bull 58(3):384
519.
Ethridge EC, Clark DE, Hench LL (1979) Effects of glass-surface area to solution volume ratio on glass corrosion. Phys Chem Glasses 20(2):35–40
520.
Hench LL, Newton RG, Bernstein S (1979) Use of infrared reflection spectroscopy in analysis of durability of medieval glasses, with some comments on conservation procedures. Glass Technol 20(4):144–148
521.
Dilmore MF, Clark DE, Hench LL (1979) Corrosion behavior of lithia disilicate glass in aqueous-solutions of aluminum compounds. Am Ceram Soc Bull 58(11):1111
522.
Mccracken WJ, Clark DE, Hench LL (1979) Effects of solution pH on corrosion behavior of Li2O·2SiO2 glass-ceramics. Am Ceram Soc Bull 58(3):382
523.
Clark DE, Yenbower EL, Hench LL (1979) Corrosion behavior of a zinc-borosilicate simulated nuclear waste glass. Am Ceram Soc Bull 58(3):324
524.
Hench LL (1980) Control of glass surfaces. Am Ceram Soc Bull 59(8):864
525.
Chao Y, Clark D, Hench LL (1980) Weathering of Na2O·2SiO2 glass. Am Ceram Soc Bull 59(8):864
526.
Hench LL (1982) Glass surfaces—1982. J Phys 43(NC-9):625–636
527.
Hench LL, Clark DE (1982) Surface-analysis of glasses. CS symposium series, vol 199, pp 203–229
528.
Bendale RD, Hench LL (1995) Molecular-orbital models of strained tetrahedral edge shared active-sites on dehydroxylated silica—an AM1 and PM3 study. Surf Sci 338(1–3):322–328CrossRef
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West JK, Hench LL (1998) The effect of environment on silica fracture: vacuum, carbon monoxide, water and nitrogen. Philos Mag A Phys Condens Matter Struct Defects Mech Prop 77(1):85–113
530.
Hench LL, Smith D, Cason B, Housefie LG (1973) Controlled flocculation of tile glaze wastes. Am Ceram Soc Bull 52(4):418
531.
Hench LL, Clark DE, Yenbower EL (1979) Approach to long-term prediction of stability of nuclear waste forms. Am Ceram Soc Bull 58(3):319
532.
Hench LL (1980) Waste forms—methods of predicting long-term performance of glasses and other alternatives. Bull Am Phys Soc 25(4):499
533.
Hench AA, Hench LL (1983) Computer-analysis of nuclear waste glass composition effects on leaching. Nucl Chem Waste Manag 4(3):231–238CrossRef
534.
Werme LO, Hench LL, Nogues JL, Odelius H, Lodding A (1983) On the pH-dependence of leaching of nuclear waste glasses. J Nucl Mater 116(1):69–77CrossRef
535.
Hench LL, Clark DE, Campbell J (1984) High-level waste immobilization forms. Nucl Chem Waste Manag 5(2):149–173CrossRef
536.
Hench LL, Spilman DB, Buonaquisti AD (1984) Rutherford back scattering surface-analysis of nuclear waste glasses after one year burial in Stripa. Nucl Chem Waste Manag 5(1):75–85CrossRef
537.
Lodding A, Hench LL, Werme L (1984) Nuclear waste glass interfaces after one year burial in Stripa. 2. Glass bentonite. J Nucl Mater 125(3):280–286CrossRef
538.
Hench LL, Lodding A, Werme L (1984) Nuclear waste glass interfaces after one year burial in Stripa. 1. Glass glass. J Nucl Mater 125(3):273–279CrossRef
539.
Hench LL, Werme L, Lodding A (1984) Nuclear waste glass interfaces after one year burial in Stripa. 3. Glass granite. J Nucl Mater 126(3):226–233CrossRef
540.
Hench LL, Wilson MJR (1985) Nuclear waste glass interfaces after one year burial in Stripa. 4. Comparative surface profiles. J Nucl Mater 136(2–3):218–228CrossRef
541.
Maurer C, Clark DE, Hench LL, Grambow B (1985) Solubility effects on the corrosion of nuclear defense waste glasses. Nucl Chem Waste Manag 5(3):193–201CrossRef
542.
Zhu BF, Clark DE, Hench LL, Wicks GG (1986) Leaching behavior of nuclear waste glass heterogeneities. J Non Cryst Solids 80(1–3):324–334
543.
Hench LL (1986) International collaboration in nuclear waste solidification. Nucl Technol 73(2):188–198
544.
545.
Namboodri CG; Namboodri SL; Wicks GG; Lodding AR; Hench LL; Clark DE; Newton RG; Surface-analyses of SRS waste glass buried for up to 2 years in limestone in the united-kingdom. In: Wicks GG; Bickford DF; Bunnell LR (eds) 5th international symposium at the 93rd annual meeting of the American Ceramic Society: ceramics in nuclear and hazardous waste management, Cincinnati, OH, 28 Apr–02 May 1991, nuclear waste management IV. Ceramic transactions, vol 23, pp 653–662
546.
Hench LL (1975) Prosthetic implant materials. Annu Rev Mater Sci 5:279–300CrossRef
547.
Hench LL (1979) Future-developments and applications of biomaterials—overview. Biomater Med Devices Artif Organs 7(2):339–350CrossRef
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549.
Hench LL (1989) Bioceramics and the origin of life. J Biomed Mater Res 23(7):685–703CrossRef
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Hench LL (1993) Bioceramics—from concept to clinic. Am Ceram Soc Bull 72(4):93–98
552.
Hench LL (1994) Bioactive ceramics: theory and clinical applications. In: Andersson OH, Happonen RP, YliUrpo A (eds) 7th international symposium on ceramics in medicine, Turku, Finland, 28–30 July 1994, bioceramics, vol 7, pp 3–14
553.
Hench LL (1995) Inorganic biomaterials. In: Interrante LV, Caspar LA, Ellis AB (eds) Symposium on materials chemistry—an emerging discipline, at the 204th National Meeting of the American-Chemical-Society, Washington, DC, 23–28 Aug 1992, materials chemistry: an emerging discipline. Advances in chemistry series, vol 245, pp 523–547
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Hench LL (1995) Bioactive implants. Chem Ind 14:547–550
555.
Hench LL (1996) Life and death: the ultimate phase transformation. Thermochim Acta 280:1–13CrossRef
556.
Hench LL (1997) Introduction to biomaterials. Anales Quim 93(1):S3–S5
557.
Hench LL (1998) Bioceramics, a clinical success. Am Ceram Soc Bull 77(7):67–74
558.
Hench LL (1999) Role of inorganic and theoretical chemistry in ceramics: past, present, and future. Br Ceram Trans 98(5):246–250CrossRef
559.
Hench LL (1999) Medical materials for the next millennium. MRS Bull 24(5):13–19CrossRef
560.
Ratner BD, Hench LL (1999) Perspectives on biomaterials. Curr Opin Solid State Mater Sci 4(4):379–380CrossRef
561.
Hench LL (2000) The challenge of orthopaedic materials. Curr Orthop 14(1):7–15CrossRef
562.
Hench LL (2000) A genetic theory of bioactive materials. In: Giannini S, Moroni A (eds) 13th international symposium on ceramic in medicine/symposium on ceramic materials in orthopaedic surgery: clinical results in the year 2000, Bologna, Italy, 22–26 Nov 2000, bioceramics. Key engineering materials, vol 192, no 1, pp 575–580
563.
Hench LL, Polak JM, Xynos ID, Buttery LDK (2000) Bioactive materials to control cell cycle. Mater Res Innovations 3(6):313–323CrossRef
564.
Jones JR, Hench LL (2001) Materials perspective—Biomedical materials for new millennium: perspective on the future. Mater Sci Technol 17(8):891–900CrossRef
565.
Hench LL, Xynos ID, Edgar AJ, Buttery LDK, Polak JM (2002) A genetic basis for biomedical materials. In: McLean M (eds) Conference on materials science and engineering, Imperial College Science, Technology and Medicine, London, England, 14–15 May 2001, materials science and engineering: its nucleation and growth, pp 283–296
566.
Hench LL (2002) Ceramic engineering design: designing a bionic cat. In: Clark DE, Folz DC, McGee TD (eds) Workshop on designing with engineering ceramics, Cocoa Beach, FL, Jan 2001. Introduction to ceramic engineering design, pp 374–391
567.
Cleevely ST, Hench L (2002) Professor Larry Hench—making discoveries in the biomaterials field. Mater World 10(11):12
568.
Hench LL, Boccaccini AR, Day RM et al (2003) Third-generation gene-activating biomaterials. In: Chandra T, Torralba JM, Sakai T (eds) 4th international conference on processing and manufacturing of advanced materials, Univ. Carlos III Madrid, Madrid, Spain, 07–11 Jul 2003, Thermec’2003, PTS 1–5. Materials science forum, vol 426, no 4, pp 179–184
569.
Hench LL (2003) The role of ceramics in an age of biology. In: Sundar V, Rusin RP, Rutiser CA (eds) Symposium on bioceramics held at the 105th annual meeting of the American-Ceramic-Society, Nashville, TN, 27–30 Apr 2003 bioceramics: materials and applications IV. Ceramic transactions, vol 147, pp 3–12
570.
Hench LL (2003) Glass and genes: the 2001 W. E. S. turner memorial lecture. Glass Technol 44(1):1–10
571.
572.
Hench LL (2005) Challenges for bioceramics in the 21st century. Am Ceram Soc Bull 84(9):18–21
573.
Polak J, Hench L (2005) Gene therapy progress and prospects: in tissue engineering. Gene Ther 12(24):1725–1733CrossRef
574.
Karakoti AS, Hench LL, Seal S (2006) The potential toxicity of nanomaterials—the role of surfaces. JOM 58(7):77–82CrossRef
575.
Maroothynaden J, Hench LL (2006) The effect of micro-gravity and bioactive surfaces on the mineralization of bone. JOM 58(7):57–63CrossRef
576.
Hench LL, Thompson I (2010) Twenty-first century challenges for biomaterials. J R Soc Interface 7(4):S379–S391CrossRef
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Hench LL (2011) Glass and glass-ceramic technologies to transform the world. Int J Appl Glass Sci 2(3):162–176CrossRef
578.
Hench LL (2014) Bio-ceramics for the next 25 years: challenges and opportunities. In: Antoniac I, Cavalu S, Traistaru T (eds) 25th symposium and annual meeting of the international-society-for-ceramics-in-medicine (ISCM), Bucharest, Romania, 07–10 Nov 2013 bioceramics, vol 25. Key engineering materials, vol 587, pp 3–14
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Hench LL (2015) The future of bioactive ceramics. J Mater Sci Mater Med 26(2):86CrossRef
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Hench L, Mote D, Sorenson S, Martin R (1973) Researchers on research. Eng Educ 63(4):268–272
581.
Pennypacker HS, Hench LL (1997) Making behavioural technology transferable. Behav Anal 20(2):97–108
582.
Hench L, Wilson J (1985) The bionic kreidl. J Non Cryst Solids 73(1–3):R13–R16
583.
Simmons JH (2016) The professional life of Larry L. Hench—a true renaissance scientist/engineer. J Non Cryst Solids: JNCS 436:58–61CrossRef
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Bonfield W (2006) A tribute to Professor Larry Hench. J Mater Sci Mater Med 17(11):965–966CrossRef
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Schoen HJ, Greenspan DC (2016) In memoriam Larry L. Hench, Ph.D. 1938–2015. J Biomed Mater Res Part A 104(4):819–820CrossRef
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Hench LL (1967) His heart in ceramics. Am Ceram Soc Bull 46(5):A10
587.
Hench LL, Uhlmann DR (2000) Obituary—Professor W.D. Kingery. Ceram Int 26(8):797–799
588.
Hench LL, Uhlmann DR (2000) W. David Kingery—obituary. Ind Ceram 20(2):131
Metadata
Title
A guided walk through Larry Hench’s monumental discoveries
Authors
Maziar Montazerian
Edgar D. Zanotto
Publication date
03-02-2017
Publisher
Springer US
Published in
Journal of Materials Science / Issue 15/2017
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI
https://doi.org/10.1007/s10853-017-0804-4

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