BONE TISSUE ADAPTATION PROCESSES AS AN ELEMENT OF DISORDERS MINERAL AND BONE METABOLISM PATHOGENESIS IN CHRONIC KIDNEY DISEASE

THE AIM: to select adaptation mechanisms of bone structures reorganization which are involved in mineral and bone metabolism disorders in CKD following the own data and literature analysis. It is showed that one of the reasons for high sensitivity of bone tissue in particular and mineral metabolism in general to regulatory-metabolic shift in renal function disorder is the incorporation of osteocytes in lacunary-tubular system (LTS). This incorporation significantly limits cells nutrients delivery and metabolites removal. Therefore, during phylogeny in osteocytes formed a complex system of bone structures mechanical properties adaptive correction and LTS capacity which allows carrying out environmental parameters continuous optimization. As a result, osteocytes become one of the main mineral metabolism regulators of the body. Therefore, cells functioning adaptive shifts cause systemic effects associated also with mineral homeostasis parameters deviation outside the physiological limits. According to authors, it has become a clinical need to develop a non-invasive method for assessing the functional state of osteocytes. Proposed solutions to this problem using chronobiological method.

osteocytes, chronic kidney disease, mineral metabolism

1. Еременко ВМ, Волгина ГВ, Добронравов ВА и др. Национальные рекомендации по минеральным и костным нарушениям при хронической болезни почек. Нефрология и диализ 2011; 13(1):33-51

2. Russell LA. Osteoporosis and Osteomalacia. Rheum Dis Clin N Am 2010; 36(4):665-680.

3. Mac Way F, Lessard M, Lafage-Proust M-H. Pathophysiology of chronic kidney disease-mineral and bone disorder. Joint Bone Spine 2012; 79(6):544-549.

4. Ott SM. Bone histomorphometry in renal osteodystrophy. Seminars in Nephrology 2009; 29(2):122-132.

5. Lehmann G, Ott U, Stein G, Steiner T, Wolf G. Renal osteodystrophy after successful renal transplantation: a histomorphometric analysis in 57 patients. Transplant Proc 2007; 39(10):3153-3158.

6. McCarthy JT, Rule AD, Achenbach SJ et al. Use of renal function measurements for assessing fracture risk in postmenopausal women. Mayo Clin Proc 2008; 83(11):1231-1239.

7. Jamal SA, Swan VJD, Brown JP et al. Kidney function and rate of bone loss at the hip and spine: the canadian multicentre osteoporosis study. Am J Kidney Dis 2010; 55(2):291-299.

8. Mittal SK, Dash SC, Tiwari SC et al. Bone histology in patients with nephrotic syndrome and normal renal function. Kidney Int 1999; 55(5):1912-1919.

9. Gal-Moscovici A, Sprague SM. Bone health in chronic kidney disease-mineral and bone disease. Adv Chronic Kidney Dis 2007; 14(1):27-36.

10. Yoshida T, Stern PH. How vitamin D works on bone. Endocrinol Metab Clin N Am 2012; 41(3):557-569.

11. Talmage RV, Mobley HT. Calcium homeostasis: Reassessment of the actions of parathyroid hormone. Gen Comp Endocrinol 2008; 156(1): 1-8.

12. Frost HM. Seeking Genetic Causes of «Osteoporosis:» Insights of the Utah Paradigm of Skeletal Physiology. Bone 2001; 29(5):407-412.

13. Frost H.M. Muscle, bone, and the Utah paradigm: A 1999 overview. Med Sci Sports Exerc 2000; 32(5):911-917.

14. Skerry TM. One mechanostat or many? Modifications of the site-specific response of bone to mechanical loading by nature and nurture. J Musculoskelet Neuronal Interact 2006; 6(2):122-127.

15. Skerry TM. The response of bone to mechanical loading and disuse: Fundamental principles and influences on osteoblast/ osteocyte homeostasis. Arch Biochem Biophys 2008; 473(2):117-123.

16. Rhee X, Bivi N, Farrow E et al. Parathyroid hormone receptor signaling in osteocytes increases the expression of fibroblast growth factor-23 in vitro and in vivo. Bone 2011; 49(4), 636-643.

17. Bellido T, Saini V, Pajevic PD. Effects of PTH on osteocyte function. Bone 2013; 54(2), 250-257.

18. Wesseling-Perry K, Juppner H. The osteocyte in CKD: New concepts regarding the role of FGF23 in mineral metabolism and systemic complications. Bone 2013; 54(2):222-229.

19. Fukumoto S, Martin TJ. Bone as an endocrine organ. Trends Endocrinol Metab 2009; 20(5):230-236.

20. Аврунин АС, Корнилов НВ, Иоффе ИД. Механизмы костной ткани и регуляторно-метаболический профиль организма. Морфология 2001: 120(6):7-12

21. Корнилов НВ, Аврунин АС, Аболин АБ. Некоторые патогенетические аспекты взаимосвязи обмена и структуры костной ткани с диагностикой и лечением остеопороза. Мед акад журн 2004; 4(2):67-79

22. Gordon PL, Frassetto LA. Management of osteoporosis in CKD stages 3 to 5. Am J Kidney Dis 2010; 55(5):941 -956.

23. Вишневский КА, Земченков АЮ, Комашня АВ и др. Физические нагрузки во время сеанса гемодиализа: комплаентность и эффекты. Нефрология и диализ 2009; 11(4):302-309

24. Аврунин АС, Паршин ЛК, Аболин АБ. Взаимосвязь морфофункциональных изменений на разных уровнях иерархической организации кортикальной кости при старении. Морфология 2006; 129(3):22-29

25. Давыдовский И. В. Общая патология человека. Ме дицина, М, 1969; 602

26. Marenzana M, Shipley AM, Squitiero P et al. Bone as an ion exchange organ: Evidence for instantaneous cell-dependent calcium efflux from bone not due to resorption. Bone 2005; 37(4):545-554

27. Parfitt AM. Progress in endocrinology and metabolism. The actions of parathyroid hormone on bone: relation to bone remodeling and turnover, calcium homeostasis, and metabolic bone disease. Part I of IV Parts: mechanisms of calcium transfer between blood and bone and their cellular basis: morphological and kinetic approaches to bone turnover. Metabolism 1976; 25(7):809-844

28. Feng JQ, Ye L, Schiavi S. Do osteocytes contribute to phosphate homeostasis? Curr Opin Nephrol Hypertens 2009; 18(4):285-291

29. Adachi T, Aonuma X, Taira K et al. Asymmetric intercellular communication between bone cells: propagation of the calcium signaling. Biochem Biophys Res Commun 2009; 389(3):495-500

30. Bonewald LF. Osteocytes: A proposed multifunctional bone cell. J Musculoskel Neuron Interact 2002; 2(3):239-241

31. Bonewald LF. Generation and function of osteocyte dendritic processes. J Musculoskelet Neuron Interact 2005; 5(4):321-324

32. Bonewald LF. The Amazing osteocyte. J Bone Miner Res 2011; 26(2): 229-238

33. Martin RB. Toward a unifying theory of bone emodeling. Bone 2000; 26(1):1-6

34. Аврунин АС, Тихилов РМ, Аболин АБ, Щербак ИГ. Уровни организации минерального матрикса костной ткани и механизмы, определяющие параметры их формирования (аналитический обзор). Морфология 2005; 127(2):78 - 82

35. Okada S, Yoshida S, Ashrafi SH, Schraufnagel DE. The canalicular structure of compact bone in the rat at different ages. Microsc Microanal 2002; 8(2):104 - 115

36. Wang L, Ciani C, Doty SB, Fritton SP. Delineating bone’s interstitial fluid pathway in vivo. Bone 2004; 34(3):499 - 509

37. Tami AE, Nasser P, Verborgt O et al. The role of interstitial fluid flow in the remodeling response to fatigue loading. J Bone Miner Res 2002; 17(11):2030-2037

38. Tami AE, Schaffler MB, Knothe Tate ML. Probing the tissue to subcellular level structure underlying bone’s molecular sieving function. Biorheology 2003; 40(6):577-590

39. Cadena EA, Schweitzer MH. Variation in osteocytes morphology vs bone type in turtle shell and their exceptional preservation from the Jurassic to the present. Bone 2012; 51(3):614-620

40. Frost HM. Defining osteopenias and osteoporoses: another view (with insights from a New Paradigm). Bone 1997; 20(5):385-391

41. Аврунин АС, Тихилов РМ, Паршин ЛК, Мельников БЕ. Остеоциты и пути оптимизации механического гомеостаза скелета с позиций функциональной остеологии. Морфология 2012; 142(4):7-13

42. Takei X Ogoshi M, Inoue K. A ‘reverse’ phylogenetic approach for identification of novel osmoregulatory and cardiovascular hormones in vertebrates. Front Neuroendocrinol 2007; 28(4):143-160

43. Danks JA, D’Souza DG, Gunn HJ et al. Evolution of the parathyroid hormone family and skeletal formation pathways. Gen Comp Endocrinol 2011; 170(1):79-91

44. Rubinacci A, Covini M, Bisogni C et al. Bone as an ion exchange system: evidence for a link between mechanotransduction and metabolic needs. Am J Physiol Endocrinol Metab 2002; 282(4):E851-E864

45. Reilly GC, Knapp Stemmer A, Niederer P et al. Investigation of the morphology of the lacunocanalicular system of corti cal bone using atomic force microscopy. Ann Biomed Eng 2001; 29(12):1074-1081

46. Докторов АА, Денисов-Никольский ЮИ. Особенности рельефа минерализованной поверхности лакун и канальцев в пластинчатой кости. Бюл. экспер мед 1993; (1):61-65

47. Lloyd SAJ, Donahue HJ. Gap junctions and biophysical regulation of bone cells. Clinic Rev Bone Miner Metab 2010; 8(4):189-200

48. Zhang D, Cowin SC, Weinbaum S. Electrical signal transmission and gap junction regulation in a bone cell network: a cable model for an osteon. Ann Biomed Eng, 1997; 25(2):357-374

49. Knapp F, Reilly GC, Stemmer A et al. Development of preparation methods for and insights obtained from atomic force microscopy of fluid spaces in cortical bone. Scanning 2002; 24(1):25-33

50. Ciovacco WA, Goldberg CG, Taylor AF et al. The role of gap junctions in megakaryocyte-mediated osteoblast proliferation and differentiation. Bone 2009; 44(1): 80-88

51. Baud CA. Morphologie et structure inframicroscopique des osteocytes. Acta Anat (Basel) 1962; (51):209-225

52. Remagen W, Caesar R, Heuck F. Elektronenmikroskopische und mikroradiographische Befunde am Knochen der mit Dihydrotachysterin behandelten Rattel. Virchows Arch Abt A Path Anat 1968; 345(3):245-254

53. Remagen W, Hohling HJ, Hall TA. Electron microscopical and microprobe observations on the cell sheath of stimulated osteocytes. Calc Tiss Res 1969; 4(1):60-68

54. Sharma D, Ciani C, Marin PAR et al. Alterations in the osteocyte lacunar-canalicular microenvironment due to estrogen deficiency. Bone 2012; 51(3):488-497

55. Li W., You L., Schaffler M.B., Wang L. The dependency of solute diffusion on molecular weight and shape in intact bone. Bone 2009; 45(5):1017-1023

56. Hillsley V, Frangos JA. Review: bone tissue engineering: the role of interstitial fluid flow. Biotechnology and Bioengineering 1994; 43(7):573-581

57. Fernandez-Seara MA, Wehrli SL, Wehrli FW. Diffusion of exchangeable water in cortical bone studied by nuclear magnetic resonance. Biophys J 2002; 82(1)Pt 1:522-529

58. Knothe Tate ML, Niederer P, Knothe U. In vivo tracer transport through the lacunocanalicular system of rat bone in an environment devoid of mechanical loading. Bone 1998; 22(2):107-117

59. Yang W, Kalajzic I, Lu Y et al. In vitro and in vivo study on osteocyte-specific mechanical signaling pathways. J Musculoskel Neuron Interact 2004; 4(4):386 - 387

60. Ajubi NE, Klein-Nulend J, Nijweide PJ et al. Pulsating fluid flow increases prostaglandin production by cultured chicken osteocytes-A cytoskeleton-dependent process. Biochemical and biophysical research communications 1996; 225(1131): 62-68

61. Bretscher A, Edwards K, Fehon RG. ERM proteins and merlin: integrators at the cell cortex. Nat Rev Mol Cell Biol 2002; 3(8):586 - 599

62. Brighton CT, Fisher JRS, Levine SE. et al. The biochemical pathway mediating the proliferative response of bone cells to a mechanical stimulus. J Bone Joint Surg 1996; 78-A(9):1337-1347

63. Ishihara X Naruse YSK, Yamashiro T et al. In situ imaging of the autonomous intracellular Ca2+ oscillations of osteoblasts and osteocytes in bone. Bone 2012; 50(4):842-852

64. Lu XL, Huo B, Park M, Guo XE. Calcium response in osteocytic networks under steady and oscillatory fluid flow. Bone 2012; 51(3):466-473

65. Слуцкий ЛИ. Биохимия нормальной и патологически измененной костной ткани. Медицина, Л., 1969;375

66. Gouleta GC, Cooper DML, Coombe D, Zernicke RF. Influence of cortical canal architecture on lacunocanalicular pore pressure and fluid flow. Computer Methods Biomechanics Biomedical Engineering 2008; 11(4):379 - 387

67. Bershadsky AD, Balaban NQ, Geiger B. Adhesion-dependent cell mechanosensittvity. Annu Rev Cell Dev Biol 2003; 19:677-995

68. Mullender M., EI Haj A.J., Yang Y et al. Mechanotransduction of bone cells in vitro: mechanobiology of bone tissue. Med Biol Eng Comput 2004; 42(1):14-21

69. Tfelt-Hansen J, Brown EM. The calcium-sensing receptor in normal physiology and pathophysiology: a review. Critical Reviews in Clinical Laboratory Sciences 2005; 42(1):35-70

70. Аврунин АС, Паршин ЛК, Мельников БЕ. Критический анализ теории механостата. Часть II. Стабильность механо-метаболической среды скелета и гомеостатических параметров кальция организма. Травматология и ортопедия России 2013; 87(1):127-137

71. Orellana-Lezcano MF, Major PW, McNeil PL et al. Temporary loss of plasma membrane integrity in orthodontic tooth movement. Orthod Craniofac Res 2005; 8(2):106-113

72. Аврунин АС, Тихилов РМ. Остеоцитарное ремоделирование костной ткани: история вопроса, морфологические маркеры. Морфология 2011; 139(1):86-94 [Avrunin AS, Tihilov RM. Osteocitarnoe remodelirovanie kostnoj tkani: istorija voprosa, morfologicheskie markery. Morfologija 2011; 139(1):86-94]

73. Borle AB, Nichols N, Nichols G. Metabolic studies of bone in vitro I. Normal bone. J Biological Chemistry 1960; 235(4):1226-1210

74. Borle AB, Nichols N, Nichols G. Metabolic studies of bone in vitro. II. The metabolic patterns of accretion and resorption. J Biological Chemistry 1960; 235(4):1211-1214

75. Nichols G, Rogers P. Mechanisms for the transfer of calcium into and out of the skeleton. Pediatrics 1971; 47(1)Part II:211-228

76. Belanger LF. Osteocytic Osteolysis. Calcif Tissue Res 1969; Vol. 4(1):1-12

77. Alcobendas M, Baud CA, Castanet J. Structural changes of the periosteocytic area in vipera aspis (l.) (ophidia, viperidae) bone tissue in various physiological conditions. Calcif Tissue Int 1991; 49(1):53-57

78. Baud CA. Submicroscopic structure and functional aspects of the osteocyte. Clin Orthop Relat Res 1968; 56:227-236

79. Baud CA, Auil E. Osteocyte differential count in normal human alveolar bone. Acta anat (Basel) 1971; 78(3):321-327

80. Duriez J, Ghosez J-P, de Flautre B. La resorption ou lyse periosteocytaire єг son role possible dans la destruction du tissu osseux. La presse medicale 1965; 73(45):2581-2586

81. Jowsey J, Riggs BL. Mineral metabolism in osteocytes. Mayo Clinic Proceedings 1964; 39(7):480 - 484

82. Taylor TG, Belanger LF, The mechanism of bone resorption in laying hens. Calcif Tissue Res 1969; 4(2):162-173

83. Tazawa K, Hoshi K, Kawamoto S at al. Osteocytic osteolysis observed in rats to which parathyroid hormone was continuously administered. J Bone Miner Metab 2004; 22(6):524-529

84. Cowin SC. The significance of bone microstructure in mechanotransduction. J Biomech 2007; 40 Suppl 1:105 - 109.

85. Аврунин АС, Тихилов РМ, Шубняков ИИ и др. Критический анализ теории механостата. Часть I. Механизмы реорганизации архитектуры скелета. Травматология и ортопедия России 2012; 64(2):105-115

86. Schaffler MB, Burr DB. Stiffness of compact bone: Effects of porosity and density. J Biomech 1988; 21(1):13-16. Цит. по Martin RB

87. Martin RB. On the significance of remodeling space and activation rate changes in bone remodeling. Bone 1991; 12(6):391-400

88. O’Brien CA, Nakashima T, Takayanagi H. Osteocyte control of osteoclastogenesis. Bone 2013; 54(2):258-263

89. Emkey RD, Emkey GR. Calcium metabolism and correcting calcium deficiencies. Endocrinol Metab Clin North Am 2012; 41(3):527-556

90. Teti A, Zallone A. Do osteocytes contribute to bone mineral homeostasis? Osteocytic osteolysis revisited. Bone 2009; 44(1):11-16

91. Aubert J-P, Bronner F, Richelle LJ. Quantitation of calcium metabolism. Theory J Clinical Investigation 1963; 42(6):885 - 897

92. Tomlinson RWS, Wall M, Osbobn SB, Anderson J. Radiocalcium studies in normal subjects cab. Calcif Tissue Res 1967; 1(3):197 - 203

93. Bronner F, Lemaike R. Comparison of calcium kinetics in man and the rat. Calcif Tissue Res 1969; 3(3):238-248

94. Bronner F, Harris RS, Maletskos CJ, Benda CE. Studies in calcium metabolism. The fate of intravenously injected radiocalcium in human beings. J Clin Jnvest 1956; 35(1):78-88

95. Bronner F, Richellef LJ, Saville PD et al. Quantitation of calcium metabolism in postmenopausal osteoporosis and in scoliosis. J Clinical Investigation 1963; 42(6):898-905

96. Arnold JS, Jee WSS, Johnson K. Observations and quantitative radioautographic studies of calcium48 deposited in vivo in forming haveesian systems and old bone of rabbit. American J Anatomy 1956; 99(2):291 - 313

97. Аврунин АС, Паршин ЛК. Иерархическая организация механизмов обмена кальция между костью и кровью. Морфология 2013; 143(1):76-84

98. Burr DB, Martin RB. Errors in bone remodeling: toward a unified theory of metabolic bone disease. Am J Anat 1989; 186(2):186 - 216

99. Аврунин АС, Тихилов РМ, Шубняков ИИ. Медицинские и околомедицинские причины высокого внимания общества к проблеме потери костной массы. Анализ динамики и структуры публикаций по остеопорозу. Гений ортопедии 2009; (3):59-66

100. Staub JF, Tracqui P, Brezillon P et al. Calcium metabolism in the rat: a temporal self-organized model. Am J Physiol 1988; 254(1 Pt 2):134-149

101. Dempster D. W. Ремоделирование кости. В: Остеопороз. Этиология, диагностика, лечение. БИНОМ, НЕВСКИЙ ДИАЛЕКТ, СПб., 2000;85-108

102. Tanaka X, Nakayamada S, Okada Y. Osteoblasts and osteoclasts in bone remodeling and inflammation current drug targets. Curr Drug Targets Inflamm Allergy 2005; 4(3):325-328

103. Baron R. Molecular mechanisms of bone resorption. Acta Orthop Scand Suppl 1995; 66(266):66-70

104. Hollberg K, Marsell R, Norgard M et al. Osteoclast polarization is not required for degradation of bone matrix. in rachitic FGF23 transgenic mice. Bone 2008; 42(6): 1111-1121

105. Berger CEM, Rathod H, Gillespie JI et al. Scanning electrochemical microscopy at the surface of bone-resorbing osteoclasts: evidence for steady-state disposal and intracellular functional compartmentalization of calcium. J bone miner res 2001; 16(11):2092 - 2102

106. Anumula S, Magland J, Wehrlib SL et al. Multi-modality study of the compositional and mechanical implications of hypomineralization in a rabbit model of osteomalacia. Bone 2008; 42(2):405-413

107. Brown EM. The extracellula Ca2+-sensing receptor central mediator of systemic calcium homeostasis. Annu Rev Nutr 2000; 20:507-533

108. Belanger LF, Robichon J. Parathormone-induced osteolysis in dogs: a microradiographic and alpharadiographic survey. J Bone Joint Surg 1964; 46-A(5):1008-1012

109. Whitfield JF, Morley P, Willick GE. Parathyroid hormone, its fragments and their analogs for the treatment of osteoporosis. Treat Endocrinol. 2002; 1(3):175-190

110. Sun X, McLamore E, Kishore V et al. Mechanical stretch induced calcium efflux from bone matrix stimulates osteoblasts. Bone 2012; 50(3):581-591

111. Frost H.M. In vivo osteocyte death. J Bone Joint Surg Am 1960; 42-A(1):138-143

112. Carpentier VT, Wong J, Yeap Y et al. Increased proportion of hypermineralized osteocyte lacunae in osteoporotic and osteoarthritic human trabecular bone: Implications for bone remodeling. Bone 2012; 50(3), 688-694

113. Frost HM. Micropetrosis. J Bone Joint Surg Am 1960; 42-A(1):144-150

114. Skerry TM, Suva LJ. Investigation of the regulation of bone mass by mechanical loading: from quantitative cytochemistry to gene array. Cell Biochem Funct 2003; 21(3):223-229

115. Levey AS, Coresh J. Chronic kidney disease. Lancet 2012; 379(9811):165-180

116. Wu M, Fannin J, Rice KM et al. Effect of aging on cellular mechanotransduction. Ageing Res Rev 2011; 10(1):1-15

117. Turner CH., Takano Y, Owan I. Aging changes mechanical loading thresholds for bone formation in rats. J Bone Miner Res 1995; 10(10):1544-1549

118. Frost H. M. A unique histological feature of vitamin D resistant rickets observed in four cases. Acta Orthop Scand 1963; 33:220-226

119. Lane NE, Wei Yao, Balooch M et al. Glucocorticoid-treated mice have localized changes in trabecular bone material properties and osteocyte lacunar size that are not observed in placebo-treated or estrogen-deficient mice. J Bone Miner Res 2006; 21(3):466-476

120. Bushinsky DA. Acid-base imbalance and the skeleton. Eur J Nutr 2001; 40(5):238-244

121. Simon EE, Hamm LL. A basic approach to CKD. Kidney Int 2010; 77(7):567-569

122. Kraut JA, Madias NE. Consequences and therapy of the metabolic acidosis of chronic kidney disease. Pediatr Nephrol 2011, 26(1):19-28

123. Lemann J, Adams ND, Wilz DR, Brenes LG. Acid and mineral balances and bone in familial proximal renal tubular acidosis. Kidney Int 2000; 58(3):1267-1277

124. Данильченко С.Н. Структура и свойства апатитов кальция с точки зрения биоминералогии и биоматериаловедения (обзор). Вісник СумДУ. Серія фізика, математика, механіка 2007; (2):33-59

125. Krieger NS, Bushinsky DA, Frick KK. Cellular mechanisms of bone resorption induced by metabolic acidosis. Semin Dial 2003; 16(6):463-466

126. Bushinsky DA, Sessler NE, Glena RE, Featherstone JD. Proton-induced physicochemical calcium release from ceramic apatite disks. J Bone Miner Res. 1994; 9(2):213-220

127. Pereira RC, Jmppner H, Azucena-Serrano CE, et al. Patterns of FGF-23, DMP1, and MEPE expression in patients with chronic kidney disease. Bone 2009; 45(6):1161-1168

128. Isakova T, Wahl P, Vargas GS et al. Fibroblast growth factor 23 is elevated before parathyroid hormone and phosphate in chronic kidney disease. Kidney Int 2011; 79(12):1370-1378

129. Аврунин А.С., Леонтьева Н.В. Расчетное моделирование и возможность неинвазивной оценки параметров минерального обмена между костными структурами и циркулирующими жидкостями. Нефрология 2013; 17(6):80-89

130. Корнилов НВ, Аврунин АС, Синюкова ИВ, Каземирский ВЕ. Биоритмы обменных процессов в костной ткани и диагностическая ценность двойной фотонной рентгеновской абсорбциометрии. Вестн травматол и ортопед им. Н.Н. Приорова. 1999; (4):52-56

131. Аврунин АС, Корнилов НВ, Суханов АВ, Паршин ВА. Ремоделирование кортикального слоя большеберцовой кости после остеотомии бедренной на той же конечности. Морфология 1999; 116(6):48-54

132. Аврунин АС, Тихилов PM, Шубников ИИ, Емельянов ВГ. Неинвазивный клинический метод оценки остеоцитарного ремоделирования. Новые возможности двух энергетической рентгеновской абсорбциометрии. Ортопед, травматол и протезирование. 2008; (2):67-74