Free access
Ann. For. Sci.
Volume 59, Number 5-6, July-October 2002
Proceedings of the Wood, Breeding, Biotechnology and Industrial Expectations Conference
Page(s) 563 - 575


  1. Amstrong J.P., Skaar C., de Zeeuw C., The effect of specific gravity on several mechanical properties of some woods, Wood Sci. Technol. 18 (1984) 137-146.
  2. Baradat P., Amélioration génétique des arbres forestiers, éléments méthodologiques, INRA, Bordeaux, 1989.
  3. Baradat P., Labbe T., Traitement statistique des essais de sélection, in: Opep. Un logiciel intégré pour l'amélioration des plantes pérennes, Anonymous, Cirad, Montpellier, 1995.
  4. Baradat P., Pastuszka P., Le pin maritime, in: Gallais A., Bannerot H. (Eds.), Amélioration des espèces végétales cultivées, INRA Éditions, Paris, 1992, pp. 695-709.
  5. Borralho N.M.G., Cotteril P.P., Kanowski P.J., Breeding objectives for pulp production of Eucalyptus globulus under different industrial cost structures, Can. J. For. Res. 23 (1993) 648-656.
  6. Burdon R.D., Low C.B., Genetic survey of Pinus radiata, N. Z. J. For. Sci. 22 (1992) 228-245.
  7. Chaffey N., Microfibril orientation in wood cells: new angles on an old topic, Trends Plant Sci., meeting report 5(9) (2000) 360-362.
  8. Chambers P.G.S., Borralho N.M.G., A simple model to examine the impact of changes in wood traits on the costs of thermomechanical pulping and high-brightness newsprint production with radiata pine, Can. J. For. Res. 29 (1999) 1615-1626.
  9. Chantre G., Bouvet A., Sens D., Robin E., Bongrand O., Modeling kraft fiber morphology and paper properties from forest data: the example of maritime pine thinnings logs, TAPPI 2000 Pulping; Process & Product Quality Conference Abstract Book Boston, 5-9 November 2000.
  10. Chantre G., Rozenberg P., Baonza V., Macchioni N., Le Turcq Q., Petit Conil M., Heois B., Genetic selection within Douglas fir (Pseudotsuga menziesii) in Europe for papermaking uses, Ann. For. Sci. 59 (2002) 583-593.
  11. Costa E Silva J., Wellendorf H., Pereira H., Clonal variation in wood quality and growth in young Sitka Spruce (Picea sitchensis (Bong.) Carr.): estimation of quantitative genetic parameters and index selection for improved pulpwood, Silvae Genet. 47 (1998) 20-33.
  12. Costa P., Durel C.E., Age trends in genetic control over height and diameter in Maritime pine, Can. J. For. Res. 26 (1996) 1209-1217.
  13. Cown D.J., Young G.D., Burdon R.D., Variation in wood characteristics of 20 year old half sib families of Pinus radiata, N. Z. J. For. Sci. 22 (1992) 63-76.
  14. Danjon F., Heritabilities and genetic correlations for estimated growth curve parameters in Maritime pine, Theor. Appl. Genet. 89 (1994) 911-921.
  15. Einspahr D.W., Goddard R.E., Gardner H.S., Slash pine, wood and fibre property heritability study, Silvae Genet. 13 (1964) 103-109.
  16. Evans R., Kibblewhite R.P., Lausberg M., Relationships between wood and pulp properties of twenty five 13-year-old radiata pine trees, 52nd APPITA annual general conference, CRC symposium fibres beyond 2000, 11-14 may 1998, Brisbane, Australia.
  17. Falconer D.S., Introduction to quantitative genetics, 2nd ed., Longman, London, UK, 1981.
  18. Guignard P., Contrôle génétique du développement de semis de pin Maritime (Pinus pinaster Ait.). Mise en évidence des effets maternels sur la croissance juvénile, Rapport de DEA Univ. Bordeaux II, INRA Bordeaux, 1983.
  19. Hannrup B., Cahalan C., Chantre G., Grabner M., Karlsson B., Le Bayon I., Müller U., Pereira H., Rodrigues J.C., Rosner S., Rozenberg P., Wilhelmsson L., Wimmer R., Genetic Parameters of wood properties in Picea Abies, in: Conference IUFRO Wood Breeding and Biotechnology, June 11-14, 2001, Bordeaux (unpublished).
  20. Hannrup B., Ekberg I., Persson A., Genetic correlations among wood, growth capacity and stem traits in Pinus sylvestris, Scand. J. For. Res. 15 (2000) 161-170.
  21. Hartley L., Nutrients and tracheid length in seedlings of Pinus radiata D. Don., Empire Forestry Rev. 39 (1969) 474-482.
  22. Hatton J.V., Cook J., Kraft pulps from second-growth Douglas fir relation-ships between wood fibre, pulp and handsheet properties, Tappi J. 75 (1992) 137-144.
  23. Hoffmeyer P., The Pylodin instrument as a non-destructive tester of the shock resistance of wood, in: Proceedings of the 4th symposium on non destructive testing of wood, Pullmann, Washington, USA, 1978, pp. 47-66.
  24. Horn R.A., Setterholm V.C., Fibre morphology and new crops, in: Janick J., Simon J.E. (Eds.), Advances in new crops, Timber Press, Portland, OR, 1990, pp. 270-275.
  25. Ivkovich M., Koshy M., Optimisation of multiple trait selection of Western Hemlock including Pulp and Paper Properties, Ann. For. Sci. 59 (2002) 577-582.
  26. Keller R., Caractéristiques du bois de pin maritime, variabilité et transmission héréditaire, Ann. For. Sci. 30 (1973) 63-81.
  27. Kibblewhite R.P., Evans R., Riddell M.J.C., Handsheet property prediction from kraft-fibre and wood tracheid properties in eleven radiata pine clones, 50th Annual General Conference, Auckland, 1996.
  28. Kibblewhite R.P., Bawden A.D., Radiata pine kraft fibre qualities. Toplogs, thinnings, slabwood, and a "genetic misfit", N. Z. J. For. Sci. 22 (1993) 96-110.
  29. Kibblewhite R.P., Uprichard J.M., Kraft pulps qualities of 11 radiata pine clones, PAPRO Report B164, in: Proceedings of the 49th Appita Annual General conference, Hobart, 1995.
  30. King J.N., Cartwright C., Hatton J., Yanchuk A.D., The potential of improving western hemlock pulp and paper quality, Can. J. For. Res. 28 (1998) 863-870.
  31. Kremer A., Déterminisme génétique de la croissance en hauteur du pin Maritime (Pinus pinaster Ait.), Ann. Sci. Forest. 38 (1981) 355-375.
  32. Larson P.R., Changes in chemical composition of wood cell walls associated with age in Pinus resinosa Ait., For. Prod. J. 16 (1966) 37-45.
  33. Larson P.R., Wood formation and the concept of wood quality, Yale Univ. Sch. For. Bull. 74, 1969.
  34. Lee S.J., Breeding strategy for Sitka spruce in Britain, in: Proc. Nord. Group for tree breeding, Edinburgh, Scotland, Oct. 1993, Forestry Commission, pp. 95-109.
  35. Lin C.Y., Index selection for genetic improvement of quantitative characters, Theor. Appl. Genet. 52 (1978) 49-56.
  36. Littleford T.W., Variation of strength properties within trees and between trees in a stand of rapid-growth douglas-fir, For. Prod. Lab. Can. Vancouver, Canada, 1961.
  37. Lowe W.J., Byram T.D., Bridgwater F.E., Selecting loblolly pine parents for seed orchards to minimize the cost of producing pulp, For. Sci. 45 (1999) 231-216.
  38. Megraw R.A., Wood quality factors in loblolly pine, TAPPI Press Atlanta, Georgia, 1985.
  39. Muneri A., Raymond C.A., Genetic parameters and genotype-by-environment interactions for basic density, Pilodyn penetration and stem diameter in Eucalyptus globulus, Forest Gen. 7 (2000) 317-328.
  40. Nepveu G., Étude génétique de quelques qualités du bois de pin maritime. Corrélations avec des caractères de croissance et d'aptitude à l'élagage, Document à distribution limitée, Station de Recherches sur la qualité du bois, 5 (1973).
  41. Nepveu G., La variabilité du bois, in: Le matériau bois, 2$^{\rm e}$ éd., ARBOLOR, Nancy, 1991.
  42. Nepveu G., L'amélioration de la qualité de la production forestière : le cas du pin Maritime, in: Intervention à la 3$^{\rm e}$ rencontre Recherche Formation Professionnels du bois et de la forêt, ENITA, Bordeaux, 13 déc. 1984.
  43. Newlin J.A., Wilson T.R.C., The relation of the shrinkage and strength properties of wood to its specific gravity, USDA Bull. 676 (1919) 35 p.
  44. Nyakuengama J.G., Evans R., Matheson C., Spencer D.J., Vinden P., Wood quality and quantitative genetics of Pinus radiata D. Don: fibre traits and wood quality, Appita J. 52 (1999) 348-350.
  45. Nyakuengama J.G., Matheson C., Spencer D.J., Evans R., Vinden P., Time trends in the genetic control of wood microstructure traits in Pinus radiata, Appita J. 50 (1997) 486-494.
  46. Nylinder P., Wood quality and fiber product, in: Proc. IUFRO-5 Meet., Vol. 2, Republic of South Africa, 1973, pp. 832-844.
  47. Page D.H., A method for determining the fibril angle in wood tracheids, J. Microscopy 90 (1969) 137.
  48. Panshin A.J., de Zeeuw C., Textbook of wood technology, McGraw-Hill book Co, New York, 1980.
  49. Polge H., Illy G., Héritabilité de la densité du bois et corrélations avec la croissance étudiées à l'aide de tests non destructifs sur plants de pins maritimes de quatre ans, Silvae Genet. 17 (1968) 173-181.
  50. Polge H., Établissement des courbes de variation de la densité du bois par exploration densitométriques de radiographies d'échantillons prélevés à la tarrière sur des arbres vivants, Ann. Sci. For. 23 (1966) 1-206.
  51. Rodrigues J., Pereira H., Jones G., Cahalan C., Chantre G., Rapid non destructive methods for assessment of wood chemical composition, in: Conference IUFRO Wood Breeding and Biotechnology, June 11-14, 2001, Bordeaux (unpublished).
  52. Rozenberg P., Cahalan C., Spruce and wood quality: genetic aspects (a review), Silvae Genet. 46 (1997) 270-279.
  53. Rozenberg P., Franc A., Bastien C., Cahalan C., Improving models of wood density by including genetic effect: a case study in douglas-fir, Ann. For. Sci. 58 (2001) 385-394.
  54. Rozenberg P., Franc A., Mamdy C., Launay J., Schermann N., Bastien J.C., Genetic control of stiffness of standing douglas-fir; from the standing stem to the standardised wood sample, relationships between modulus of elasticity and wood density parameters, Ann. For. Sci. 56 (1999) 145-154.
  55. Rydholm S.A., Pulping processes, Interscience Publishers, New York, 1965.
  56. Searle S.D., Linear models, New York, John Wiley, 1971.
  57. Siddiqui K.M., Relationships between cell wall morphology and chemical composition of earlywood and latewood in two coniferous species, Pakistan J. For. 26 (1976) 21-34.
  58. Sierra-Alvarez R., Tjeerdsma B.F., Organosolv pulping of wood from short rotation intensive plantations, Wood Fibre Sci. 27 (1995) 395-401.
  59. T273 pm-95, Wet zero-span tensile strength of pulp. Pulp Properties Committee of the Process and Product quality Division, Tappi Press, 1995.
  60. Van Buijtenen J.P., Einspahr D.W., Peckham J.R., Micropulping loblolly pine grafts selected for extreme wood specidic gravity, Silvae Genet. 17 (1968) 15-19.
  61. Von Byrd L., Ellwood E.L., Hitchings R.G., Barefoot A.C., Wood characteristics and kraft paper properties of four selected loblolly pines, For. Prod. J. 15 (1965) 313-320.
  62. Watson A.J., Hodder I.G., Relationship between fibre structure and handsheet properties in Pinus taeda L., Appita J. 8 (1954) 290-310.
  63. Wilson J.W., Wellwood R.W., Intra-incremental chemical properties of certain western canadian coniferous species, in: Coté W.A. (Ed.), Cellular Ultrastructure of Woody plants, Syracuse University Press, New York, 1965, pp. 551-559.
  64. Wu Y., Wilson J.W., Lignification within coniferous growth zones, Pulp Pap. Can. 68 (1967) 159-164.
  65. Zhang S.Y., Morgenstern E.K., Genetic variation and inheritance of wood density in black spruce (Picea mariana) and its relationship with growth: implications for tree breeding, Wood Sci. Technol. 30 (1995) 63-75.
  66. ZhiChun Z., GuangRong L., GuangLin H., BingXing C., YaoKe L., Genetic control of wood chemical composition and its implication for wood breeding of Masson pine, Scientia Silvae Sinicae 36 (2000) 110-115.
  67. Zobel B., Jett J., Genetics of wood production, Springer series in wood science, Springer-Verlag, 1995.
  68. Zobel B.J., Buijtenen J.P., Wood variation: its causes and control, Springer-Verlag, 1989.


Copyright INRA, EDP Sciences