menaquinone-6 and Magnesium-Deficiency

It has been reported that the Mg-insufficient bone is fragile upon mechanical loading, despite its high bone mineral density, while vitamin K2 (MK-4: menatetrenone) improved the mechanical strength of Mg-insufficient bone. Therefore, we aimed to elucidate the ultrastructural properties of bone in rats with dietary Mg insufficiency with and without MK-4 supplementation. Morphological examinations including histochemistry, transmission electron microscopy, electron probe microanalysis (EPMA) and X-ray diffraction were conducted on the femora and tibiae of 4-week-old Wistar male rats fed with 1) a normal diet (control group, 0.09% Mg), 2) a Mg-insufficient diet (low Mg group, 0.006% Mg), or 3) a Mg-insufficient diet supplemented with MK-4 (MK-4 group, 0.006% Mg, 0.03% MK-4). MK-4 appeared to inhibit the osteoclastic bone resorption that is stimulated by Mg insufficiency. EPMA analysis, however, revealed an increased concentration of Ca paralleling Mg reduction in the low Mg group. Assessment by X-ray diffraction revealed an abundance of a particular synthetic form of hydroxyapatite in the low Mg group, while control bones featured a variety of mineralized crystals. In addition, Mg-deficient bones featured larger mineral crystals, i.e., crystal overgrowth. This crystalline aberration in Mg-insufficient bones induced collagen fibrils to mineralize easily, even in the absence of mineralized nodules, which therefore led to an early collapse of the fibrils. MK-4 prevented premature collagen mineralization by normalizing the association of collagen fibrils with mineralized nodules. Thus, MK-4 appears to rescue the impaired collagen mineralization caused by Mg insufficiency by promoting a re-association of the process of collagen mineralization with mineralized nodules.

Topics: Animals; Biomechanical Phenomena; Bone Resorption; Calcification, Physiologic; Calcium; Collagen; Disease Models, Animal; Electron Probe Microanalysis; Femur; Immunohistochemistry; Magnesium Deficiency; Male; Osteocalcin; Osteoclasts; Phosphorus; Rats; Rats, Wistar; Tibia; Vitamin K 2; X-Ray Diffraction

In this study, we compared the effects of vitamin K(2) menatetrenone on bone mechanical properties in rats fed a low-magnesium (Mg) diet. In addition, the mechanism of bone quality was examined using Fourier transform infrared imaging (FTIRI). Thirty 4-week-old male Wistar rats were divided into three groups: intact, low-Mg-control, and low-Mg-MK-4 groups. Rats in the low-Mg groups were given a diet containing 6 mg/100 g Mg (intact, 90 mg/100 g). After an 8-week-treatment, the cortical bone mineral content (CtBMC), outer perimeter, and endo perimeter of the femoral diaphysis in the low-Mg-control group were significantly higher, while the maximum load (ML) and elastic modulus (EM) were 81% and 50% of those in the intact group, respectively (respectively, P < 0.05). In the low-Mg-MK-4 group, ML and EM were significantly higher than in the low-Mg-control group (P < 0.05), with no differences in CtBMC. The mineral/matrix ratios for the periosteal and central regions in the low-Mg-control group were 162% and 120% of those in the intact group (both, P < 0.05), respectively. MK-4 significantly inhibited these increases (P < 0.05). We found that the mineral/matrix ratios for the periosteal region of the femoral diaphysis were negatively correlated with EM, suggesting that an increase in the mineral/matrix ratio may be involved in the reduction of EM and that MK-4 may improve EM by improving the mineral/matrix ratio.

Topics: Animals; Bone and Bones; Magnesium; Magnesium Deficiency; Male; Rats; Rats, Wistar; Spectroscopy, Fourier Transform Infrared; Vitamin K 2

Vitamin K2 is widely used for the treatment of osteoporosis in Japan. To understand the effects of vitamin K2 on bone mass and bone metabolism, we reviewed its effects on the development of osteopenia in rats, which characterizes models of osteoporosis. Vitamin K2 was found to attenuate the increase in bone resorption and/or maintain bone formation, reduce bone loss, protect against the loss of trabecular bone mass and its connectivity, and prevent the decrease in strength of the long bone in ovariectomized rats. However, combined treatment of bisphosphonates and vitamin K2 had an additive effect in preventing the deterioration of the trabecular bone architecture in ovariectomized rats, while the combined treatment of raloxifene and vitamin K2 improved the bone strength of the femoral neck. The use of vitamin K2 alone suppressed the increase in trabecular bone turnover and endocortical bone resorption, which attenuated the development of cancellous and cortical osteopenia in orchidectomized rats. In addition, vitamin K2 inhibited the decrease in bone formation in prednisolone-treated rats, thereby preventing cancellous and cortical osteopenia. In sciatic neurectomized rats, vitamin K2 suppressed endocortical bone resorption and stimulated bone formation, delaying the reduction of the trabecular thickness and retarding the development of cortical osteopenia. Vitamin K2 also prevented the acceleration of bone resorption and the reduction in bone formation in tail-suspended rats, which counteracted cancellous bone loss. Concomitant use of vitamin K2 with a bisphosphonate ameliorated the suppression of bone formation and more effectively prevented cancellous bone loss in tail-suspended rats. Vitamin K2 stimulated renal calcium reabsorption, retarded the increase in serum parathyroid hormone levels, and attenuated cortical bone loss primarily by suppressing bone resorption in calcium-deficient rats while maintaining the strength of the long bone in rats with magnesium deficiency. These findings suggest that vitamin K2 may not only stimulate bone formation, but may also suppress bone resorption. Thus, vitamin K2 could regulate bone metabolism in rats, which represented the various models of osteoporosis. However, the effects of vitamin K2 on bone mass and bone metabolism seem to be modest.

Topics: Animals; Bone and Bones; Bone Diseases, Metabolic; Bone Resorption; Calcium; Diphosphonates; Disease Models, Animal; Female; Homeostasis; Magnesium; Magnesium Deficiency; Male; Osteoporosis; Rats; Tibia; Tomography, X-Ray Computed; Vitamin K 2

In this study, we examined changes in bone parameters and bone strength in rats fed low-Mg diets (experiment 1) and the effects of vitamin K2 (MK-4, experiment 3) and alendronate (ALN, experiment 2) in this model. In experiment 1, 5-week-old male Wistar rats were fed three low-Mg diets (Mg 9, 6, 3 mg/100 g diet) for 4 weeks. Although the cortical bone mineral content (CtBMC) and cortical thickness (CtTh) of the femoral diaphysis in all low-Mg-diet groups were the same as or greater than those in the intact group (Mg: 90 mg/100 g diet), the maximum load and elastic modulus were significantly reduced in the 3-mg-Mg group. In experiment 2, 4-week-old Wistar rats were fed a 6-mg-Mg diet for 8 weeks, and the effect of ALN (2, 20, and 200 microg/kg twice a week) was evaluated. The administration of ALN at 200 microg/kg increased the cortical bone mineral content (CtBMC), CtTh, and maximum load, but had no effect on the elastic modulus, as compared with the low-Mg-control group. In experiment 3, the effect of MK-4 was evaluated under the same conditions as in experiment 2. The administration of MK-4 had no effect on CtBMC, CtTh, or bone components of the femoral diaphysis. However, MK-4 inhibited the decreases in maximum load and elastic modulus due to the low-Mg diet. Since there is no other experimental model in which there is a decrease in bone mechanical properties without a decrease in bone mineral content, the low-Mg diet model is considered to be an excellent model for examining bone quality. Our results from this model suggest that MK-4 and ALN affect bone mechanical properties by different mechanisms.

Topics: Alendronate; Alkaline Phosphatase; Animals; Body Weight; Bone and Bones; Bone Density; Calcitriol; Calcium; Elasticity; Femur; Hydroxyproline; Magnesium; Magnesium Deficiency; Male; Osteocalcin; Parathyroid Hormone; Rats; Rats, Wistar; Stress, Mechanical; Urine; Vitamin K 2

Two experiments were carried out using 7-week-old male Wistar rats. Exp. 1: Rats in the intact group were fed with normal diet (0.5% Ca, 0.09% Mg). Ca/Mg deficient rats were fed low Ca (0.01%) diets containing 0.003, 0.015 or 0.09% Mg for 4 weeks. After 4 weeks, the bone mineral density (BMD) and maximum load in the femur were decreased in Ca/Mg deficient rats, but this was not dependent on dietary Mg concentration. The elasticity, stiffness, and Mg concentration in the femur of these rats were also decreased and Ca deposition in the kidney were increased, compared to those of normal rats, which were related to Mg concentration in the diet. From these results, Mg may play an important role in qualitative changes in bone (i.e., reduced stiffness). Exp. 2: We investigated the effects of V.K2 on the changes in BMD and bone strength in femur induced by low Ca/Mg (0.01%/0.003%) diet for 8 weeks. Compared to the intact group, Ca and Mg levels in serum and femur and cortical thickness, cortical area, and maximum load of the femoral midshaft were decreased in the Ca/Mg-deficient group. In these rats, PTH in the serum and renal Ca concentration were increased. In V.K2-treated rats, these changes in the serum Ca, Mg and PTH levels and the renal Ca concentration were improved. V.K2 also improved the decrease in maximum load in spite of no influence on the cortical thickness, cortical area and Mg concentration in the femur. These findings suggest that V.K2 may affect the qualitative change in bone.

Topics: Animals; Bone and Bones; Bone Density; Calcium; Magnesium; Magnesium Deficiency; Male; Parathyroid Hormone; Rats; Rats, Wistar; Tensile Strength; Vitamin K 2