Open Access Online Scientific Journal

Research Article

J Med Discov (2020); 5(2):jmd20030; DOI:10.24262/jmd.5.2.20030; 
Received March 25th, 2020, Revised May 11st, 2020, Accepted May 20th, 2020, Published May 26th, 2020.

Role of vitamin K therapy in prevention of vascular calcification in hemodialysis patients

Osama A. Khamis1, Tarek Z. El Baz1, Nagwa Abd El-Ghaffar Mohammed2, Mohammed Ahmed Shazly3, Hazem Sayed Ahmed Ayoub1.

 

 

1Department of Internal Medicine; Faculty of Medicine, AL-Azhar University, Al – Mahameer Street، Gameat Al Azhar, Nasr City, Cairo, 11765,

Egypt.

2Department of Clinical and Chemical Pathology, National Research Center, El-Mohamady, Al Waili, Cairo, Egypt.

3Department of Radiology; Faculty of Medicine, AL-Azhar University, Al – Mahameer Street، Gameat Al Azhar, Nasr City, Cairo, 11765, Egypt.

 

* Correspondence: Osama A. Khamis, Nasr city, Cairo, 11765, Egypt. E-mail: okhamis2015@gmail.com

Abstract

Introduction: Matrix Gla protein (MGP) is a central calcification inhibitor of vascular wall. The biological activation of the calcification-inhibitory protein MGP can be achieved by simple administration of oral vitamin K.

Aim: The study was conducted to assess the effect of vitamin k supplementation on vascular calcification and to evaluate its effect on MGA in hemodialysis patients.

Materials and Methods: It was a prospective study carried out at Al-Azhar university hospital, from May 2015 to June 2016. Forty adult patients with end stage renal disease (ESRD) on regular hemodialysis sessions, thrice weekly, were enrolled in the study and were randomly assigned into two groups. Vitamin K group consisted of 20 patients were given oral vitamin K1 at 10 mg after each session of dialysis for a duration of one year. No-Vitamin K group included 20 patients didn’t receive vitamin K. All patients were subjected to the following: Matrix Gla protein (MGP), in addition to, plain digital abdominal x-ray and doppler ultrasound.

Results: After one-year of vitamin K supplementation, a significant increase in MGP levels in Vitamin K group (75.7±26 ng/mL) were noticed. There were no significant changes in CIMT and AACS in Vitamin K group after vitamin K supplementation in compared to their baseline levels, while the CIMT and AACS were significantly increased in No-Vitamin K group in compared to their baseline levels.

Conclusion: Vitamin K supplementation could not stop vascular calcifications but significantly attenuate their progression.

Keywords: CKD, Vascular calcification, Vitamin K supplementation

Introduction

Cardiovascular mortality risk is elevated 5-10-fold in ESKD compared to the general population [1]. An important risk factor for cardiovascular mortality in end stage kidney disease (ESKD) patients is vascular calcification (VC), which is an abnormal deposition of calcium salts in vascular tissue, including valves, blood vessels and the heart [2]. Vascular calcification is highly prevalent in ESKD and independently predictive of future cardiovascular events and mortality [3]. Vascular calcification is an active cell-mediated process involving vascular smooth muscle cells (VSMC) apoptosis and vesicle release, a shift in the balance of inhibitors and promoters of vascular calcification, and VSMC differentiation from a contractile to osteochondrogenic phenotype [4, 5]. Calcification can occur in both the intimal and medial layers of vasculature, but medial calcification is the major form in ESKD. Medial calcification increases large elastic artery stiffness and pulse-pressure, promotes left ventricular hypertrophy, reduces perfusion of the coronary arteries, and ultimately promotes increased cardiovascular mortality via increased risk of myocardial infarction and heart failure [3].

Matrix Gla protein (MGP) is a central calcification inhibitor. It is produced by vascular smooth muscle cells and requires vitamin K-dependent post-translational modification, namely gamma carboxylation, to be fully active [6]. Uncarboxylated MGP, formed because of vitamin K deficiency, is associated with cardiovascular diseases. It has become evident that a high prevalence of subclinical vitamin K deficiency exists in hemodialysis patients [7]. MGP is an extracellular matrix protein that accumulates near the borders of calcified plaques [8]. It is progressively expressed during osteoblastic differentiation of VSMC [9], and vascular pericytes [10]. Paradoxically, MGP-deficient mice have extensive arterial calcification, aortic dissection, and death at 6–8 weeks [11]. Conversely, MGP transgenic mice have reduced calcification as well as reduced atherosclerosis [12]. MGP requires vitamin K-dependent gamma-carboxylation. Inhibiting gamma-carboxylation of MGP by warfarin reduces its ability to inhibit matrix mineralization, possibly through inhibiting binding to potent osteogenic factor, bone morphogenetic protein [13]. This may account for the induction of vascular calcification by the vitamin K inhibitor, warfarin, in rodents [14]. The present study was conducted to assess the effect of vitamin k supplementation on vascular calcification and to evaluate its effect on MGA in hemodialysis patients.

Materials and Methods

The study was carried out for a period of one year from May 2015 to April 2016 at El-Hussein hospital of Al-Azhar University.  A total 40 clinically stable end stage kidney disease patients in addition to 20 healthy volunteers as a control group  were enrolled in this prospective study. All patients were dialyzed via arteriovenous fistula three times a week for four hours’ session using polysulfone low flux dialyzer 1.6 m2 surface area, with dialysate flow 500 ml/min and dialysate calcium concentration 1.25 mmol/l, using heparin as anticoagulant with tailored doses according to each case and bicarbonate based dialysate. The adequacy of dialysis was assessed using Kt/V formula (K is patient clearance, t dialysis time, V urea space) [15]. Patients older than 25 years who have maintained on regular hemodialysis for more than one year were included in the study. While, patients with history of thrombosis, inflammatory bowel disease, diabetes mellitus, liver dysfunction or coagulation disorders, in addition to patients received vitamin K antagonists were excluded.

The patients were randomly assigned into two groups. Vitamin K group consisted of 20 patients (11 males and 9 females, mean age was 52.1±7.52 years) received oral vitamin K (Phytomenadione 10 mg) after each session of dialysis for a duration of one year. No vitamin K group included 20 patients (7 males and 13 females, mean age was 48.3±9.33 years) didn’t receive vitamin K. All patients were subjected to the following: Hemoglobin level, serum creatinine, blood urea, serum phosphorus, total serum calcium, intact parathormone (iPTH), lipid profile and MGP. Serum MGP was determined using sandwich enzyme immunoassay supplied from The Life Science Company (2BScientific Ltd, Cherwell Innovation Centre, 77 Heyford Park, Upper Heyford, UK) [16]. In addition to, lateral abdominal x-radiography of the aorta to measure abdominal aorta calcification score (AACS) using a validated 24-point abdominal aortic calcification score [17] and doppler ultrasound for assessment of carotid intimal medial thickness (CIMT). All patients were informed about the content of the study and gave their written approvals before enrollment. All procedures were performed in accordance with the ethical standards of Al-Azhar University’s committee on human experiments.

Statistics

The statistical analysis was performed by using SPSS version 18.0 statistical software (SPSS Inc., Chicago, IL, USA). The results were indicated by mean ± standard deviation. Paired-samples t – test was used in comparing the results at baseline, after one year. Independent-samples test was used in comparing independent samples. For qualitative data, the number and percent distribution were calculated, chi square (χ2) was used as test of significance. Significant difference was p < 0.05.

Results

Characteristics of the study participants are shown in table 1,2. The level of MGP in ESKD patients was 50±10.8 ng/mL. This level was more than 2 times higher than that of a matched control group (23±3.9 ng/mL) without kidney disease. All ESKD patients had significantly higher PTH level (434±471 pg/ml), triglycerides level (172± 88 mg/dl), carotid intima media thickness (0.84±0.20 mm, 0.85± 0.21 mm for left and right CIMT respectively) and significantly lower HDL and hemoglobin level (9.9±2 g/dl) than that of a matched control group (table 1).

 

Table 1. Comparison between ESKD patients and control group

ESKD Control
Mean ±SD Mean ±SD
Age (year) 50.2 8.5 47 8 >0.05
Sex Male n/% 18/45% 22/55% >0.05
Female n/% 13/65% 7/35%
BMI (kg/m²) 27 5.5 25 3.8 >0.05
Calcium (mg/dl) 8.6 1 9 .6 >0.05
Phosphorus (mg/dl) 5.3 1.2 4.1 .5 <0.05
PTH (pg/ml) 434 471 24.7 9 <0.005
Cholesterol (mg/dl) 148 30 142 33 >0.05
LDL (mg/dl) 126 19 122 15 >0.05
HDL (mg/dl) 39 5.6 43.8 6.1 <0.05
Triglyceride (mg/dl) 172 88 128 45 <0.05
Blood urea (mg/dl) 152 41 24 5.9 <0.005
Creatinine (mg/dl) 11 2.5 .70 .12 <0.005
Haemoglobin g/dl 9.9 2 12.6 1.1 <0.005
MGP (pg/ml) 50 10.8 23 3.9 <0.005
Lt CIMT (mm) 0.84 0.20 0.59 0.12 <0.005
Rt CIMT (mm) 0.85 0.21 0.61 0.10 <0.005
ESKD: end stage kidney disease, BMI: body mass index, PTH: parathyroid hormone, LDL: low density lipoprotein, HDL: high density lipoprotein, AACS: abdominal aorta calcification score, Lt. CIMT: left carotid intima media thickness Rt.CIMT: right carotid intima media thickness, MGP: Matrix gla protein.

 

The baseline biochemical and radiological findings of the Vitamin K and No-Vitamin K groups were a like comparable and are shown in table (2). There was a significant increase in MGP levels in the Vitamin K group (75.7±26 ng/mL) after vitamin K supplementation compared to its baseline levels (51.49±12 ng/mL). On the contrary, the changes in CIMT and AACS were not statistically significant in vitamin K group in compared to their baseline levels table (3). Moreover, there were significant increase in AACS and CIMT in patients who did not receive vitamin K supplementation (table 3).

 

Table 2. Comparison between vitamin K group and No-vitamin K group at the start of the study

 

Parameters

Vitamin K group

(M±SD)

No-vitamin K group

(M±SD)

P value
Age/years 52 ± 7 48±9 >0.05
Sex Male n/% 11/55% >0.05
Female n/% 9/45% >0.05
BMI (kg/m²) 27.9±6 26±4.7 >0.05
Duration of hemodialysis (months) 75±41 87±46 >0.05
Calcium (mg/dl) 8.7 ±1.7 8.6 ±0.8 >0.05
Phosphorus (mg/dl) 5.4±1.4 5.2±0.9 >0.05
PTH (pg/ml) 507.95±627 360±227 >0.05
Cholesterol (mg/dl) 142±26.7 155±33 >0.05
LDL (mg/dl) 125 ±20 128±18 >0.05
HDL (mg/dl) 39±5.7 40±5.7 >0.05
Triglyceride (mg/dl) 156.8±82 187±93 >0.05
Blood urea (mg/dl) 162±42 142±38.5 >0.05
Creatinine (mg/dl) 11.6±3 10.4±1.8 >0.05
Haemoglobin g/dl 10±1.5 9.6±2.3 >0.05
AACS 5.9±2.5 5.95±2.4 >0.05
Lt. CIMT (mm) .81±0.20 .88±0.19 >0.05
Rt. CIMT (mm) .82±0.22 .88±0.2 >0.05
MGP (pg/ml) 51.49±12 48.56±8.7 >0.05
BMI: body mass index, PTH: parathyroid hormone, LDL: low density lipoprotein, HDL: high density lipoprotein, AACS: abdominal aorta calcification score, Lt. CIMT: left carotid intima media thickness Rt.CIMT: right carotid intima media thickness, MGP: Matrix gla protein.

 

The comparison between Vitamin K and No-Vitamin K groups after one year of vitamin K supplementation revealed that high significant increase of MGP (75.76±26 pg/dl) in Vitamin K group in compare to No-Vitamin K group (49.36±6 pg/dl) P <0.005. Moreover, there were significant increase in AACS and CIMT in No-Vitamin K in compare to Vitamin K group (table 4).

 

Table 3. Comparison between laboratory and radiological findings of studied groups at the start and after one year of vitamin K treatment

Parameters

Vitamin K group

 

(M±SD)

P value

No-vitamin K group

(M±SD

P value
BMI (kg/m²) At start 27.9±6 >0.05 26±4.7 >0.05
After 1 year 26.8±4.5 27.2±3.4
Calcium (mg/dl) At start 8.7 ±1.7 >0.05 8.6 ±.8 >0.05
After 1 year 8.7±0.9 8.4±0.7
Phosphorus (mg/dl) At start 5.4±1.4 >0.05 5.2±0.9 >0.05
After 1 year 5.3±1.3 5±1.7
PTH (pg/ml) At start 507.95±627 >0.05 360±227 >0.05
After 1 year 496.80±491 476.5±391
Cholesterol (mg/dl) At start 142±26.7 <0.05 155±33 >0.05
After 1 year 130±14 154±33
LDL (mg/dl) At start 125 ±20 >0.05 128±18.6 >0.05
After 1 year 131±21 136±17
HDL (mg/dl) At start 39±5.7 >0.05 40±5.7 >0.05
After 1 year 40±6 37.6±3.4
Triglyceride (mg/dl) At start 156.8±82 >0.05 187±93 >0.05
After 1 year 146±64 183±109
Blood urea (mg/dl) At start 162±42 >0.05 142±38.5 >0.05
After 1 year 154±26 150±23
Creatinine (mg/dl) At start 11.6±3 >0.05 10.4±1.8 >0.05
After 1 year 11.2±2 10.8±1.9
Haemoglobin g/dl At start 10±1.5 >0.05 9.6±2.3 >0.05
After 1 year 9.6±2 9.6±2
AACS At start 5.9±2.5 >0.05 5.95±2.4 <0.005
After 1 year 6±2.5 7.2±2.2
Lt. CIMT (mm) At start 0.81±0.2 >0.05 0.88±0.19 <0.005
After 1 year 0.82±0.22 1.08±0.18
Rt. CIMT (mm) At start 0.82±0.2 >0.05 .88±0.2 <0.005
After 1 year 0.81±0.26 1.03±0.17
MGP (pg/ml) At start 51.49±12 <0.05 48.56±8.7 >0.05
After 1 year 75.76±26 49.36±6
BMI: body mass index, PTH: parathyroid hormone, LDL: low density lipoprotein, HDL: high density lipoprotein, AACS: abdominal aorta calcification score, Lt. CIMT: left carotid intima media thickness Rt.CIMT: right carotid intima media thickness, MGP: Matrix gla protein.

 

MGP was directly correlated with serum phosphate, iPTH, blood urea, serum creatinine, cholesterol level, LDL and triglyceride level. In addition, MGP was inversely correlated with duration of hemodialysis, HDL, hemoglobin levels and AACS (table 5).

 

Table 4. comparison between vitamin K group and No-vitamin K group as regards laboratory and radiological findings after one year of vitamin K supplementation

Parameters

Vitamin K group

(Mean ± SD)

No-vitamin K group

(Mean ± SD)

P value
BMI (kg/m²) 26.8±4.5 27.2±4.3 >0.05
Calcium (mg/dl) 8.7±0.9 8.4±0.7 >0.05
Phosphorus (mg/dl) 5.3±1.3 5±1.7 >0.05
PTH (pg/ml) 496.8±491 476.2±391 >0.05
Cholesterol (mg/dl) 130±14 154±34 <0.05
LDL (mg/dl) 131±21 136±17 >0.05
HDL (mg/dl) 40±6 37.6±3.4 >0.05
Triglyceride (mg/dl) 146±64 183±109 >0.05
Blood urea (mg/dl) 154±26 150±23 >0.05
Creatinine (mg/dl) 11.2±2 10.8±1.9 >0.05
Haemoglobin g/dl 9.6±2 9.6±2 >0.05
AACS 6±2.5 7.2±2.2 >0.05
Lt. CIMT (mm) .82±0.22 1.08±0.18 <0.005
Rt. CIMT (mm) .81±0.26 1.03±0.17 <0.005
MGP (pg/ml) 75.76±26 49.36±6 <0.005
BMI: body mass index, PTH: parathyroid hormone, LDL: low density lipoprotein, HDL: high density lipoprotein, AACS: abdominal aorta calcification score, Lt. CIMT: left carotid intima media thickness Rt.CIMT: right carotid intima media thickness, MGP: Matrix gla protein.

 

Table 5. correlation between matrix gla protein and tested variables

MGP AACS Lt CIMT Rt CIMT
R P r P r P r P
Age (year) .083 .528 .209 .195 .124 .343 .057 .663
BMI (kg/m²) .117 .373 -.063 .700 -.017 .896 -.065 .620
Duration of hemodialysis -.393 .012 .580 .000 .218 .176 .305 .056
Serum calcium (mg/dl) -.221 .090 -.023 .888 -.254 .050 -.155 .236
Serum phosphorus (mg/dl) .322 .012 .306 .055 .530 .000 .509 .000
iPTH (pg/dl) .334 .009 .259 .106 .401 .001 .401 .001
Cholesterol (mg/dl) .256 .048 -.234 .146 -.021 .872 .094 .473
LDL (mg/dl) .308 .017 -.190 .241 .113 .388 .140 .286
HDL (mg/dl) -.394 .002 .048 .770 -.216 .097 -.187 .154
Triglyceride (mg/dl) .299 .020 -.086 .596 .344 .007 .266 .040
Blood urea (mg/dl) .688 .000 .053 .747 .436 .001 .360 .005
Serum creatinine (mg/dl) .775 .000 -.042 .796 .445 .000 .375 .003
Haemoglobin (g/dl) -.486 .000 -.085 .603 -.383 .003 -.359 .005
AACS -.606 .000 1 .595 .000 .586 .000
Lt CIMT(mm) .213 .102 .595 .000 1 .912 .000
Rt CIMT (mm) .212 .103 .586 .000 .912 .000 1
BMI: body mass index, PTH: parathyroid hormone, LDL: low density lipoprotein, HDL: high density lipoprotein, AACS: abdominal aorta calcification score, Lt. CIMT: left carotid intima media thickness Rt.CIMT: right carotid intima media thickness, MGP: Matrix gla protein.

Discussion

In this study, we demonstrate that MGP plasma levels markedly elevated in hemodialysis patients compared with subjects with normal renal function. The association between ESRD and elevated MGP has been established by previous studies [18-20]. Increased production or release of MGP may be related to the generally increased vascular damage observed in dialysis patients, and indeed, an accumulation of MGP in and around vascular calcifications has been documented [18] Moreover, decreased MGP renal clearance could be attributed to reduced kidney function. In healthy subjects, MGP is not found in urine, but MGP levels in renal veins are reported to be 13% lower than in renal arteries [21]. Thus, the kidneys excrete and metabolize MGP, and some degree of renal retention will occur in dialysis patients.

It was found that most hemodialysis patients show subclinical vitamin K deficiency, it is possible explanation may be the recommended diet for hemodialysis patients, low potassium diet (green leafy vegetables) also is low in vitamin K, and a diet low in phosphorus also is low in vitamin K content [22]. Observational clinical trials confirmed that low dietary intake of vitamin K was associated with cardiovascular risk and calcification. Also, Japanese survey among dialysis populations estimated this risk to be 11, fold higher compared with patients’ not receiving vitamin K antagonists on the other hand, it was also demonstrated that there is a frequent nutritional vitamin K deficiency in hemodialysis patients [23].In order to provide hope for those patients, nephrologists continue to try new treatment options. A promising direction in this field of research is the activation of vitamin K dependent matrix Gla protein (MGP). It is a clinically meaningful endpoint in slowing the progression or inducing the regression of cardiovascular calcifications in CKD [24]. Preventive action of vitamin K in vascular calcification has been proposed based on its role in activating MGP, a calcification inhibitor that is expressed in vascular tissue [25]. It was demonstrated that biological activation of the calcification-inhibitory protein MGP can be achieved by simple administration of oral vitamin K. It was shown that supplementation of vitamin K is most likely superior to efforts aiming at increasing the nutritional intake of vitamin K in dialysis patients [26].

In current study, hemodialysis patients who received oral vitamin k for one year have significant increase in the level of matrix gla protein (MGP) than hemodialysis patients who did not receive vitamin k. Similarly, many previous studies have demonstrated that daily supplementation of vitamin k led to a significant increase in MGP [27, 28]. The combination of vitamin K and D is more effective in increasing MGP and preventing blood vessel calcification [29-31]. In contrast, low circulating MGP concentrations were associated with more vascular calcification [32]. MGP indeed exerts its function by binding to crystal nuclei in hydroxyapaptite or by inhibiting bone morphogenetic protein-2 However, both mechanisms of action MGP has to be carboxylated [25]. Phosphorylation plays an important role in the secretion of MGP. The protein sequence of MGP includes 9 glutamate residues, 5 of which need to be carboxylated to yield bioactive MGP [33]. In humans, carboxylated MGP has been detected in intact healthy vessels, whereas uncarboxylated MGP accumulates at sites of vascular calcification [34]. It was demonstrated that undercarboxylated MGP is abundantly present in atherosclerotic intima and in media sclerosis, suggesting that local vitamin K deficiency and impaired protection attributable to poor MGP carboxylation [33]. Interestingly, a recent study has found a 10- fold increase in MGP gene expression after vitamin k supplementation was recorded in animals. Since vitamin k has no reported side effects, authors concluded that it seems a promising therapeutic agent for CKD patients [35].

Carotid intima-media thickness (CIMT) is increasingly used as a surrogate marker for atherosclerosis, and it was shown that CIMT is a strong predictor of future vascular events such as myocardial infarction and stroke [36]. The association between CIMT and cardiovascular disease (CVD) has been demonstrated in a predialysis CKD population. The CIMT has been found to be a strong predictor of cardiovascular or all-cause mortality [37]. Moreover, patients on chronic haemodialysis suffer from extensive vascular calcifications (VC). The presence of VC is directly related to increased cardiovascular morbidity and mortality in the dialysis population and progression of VC provides independent incremental prognostic information [38]. Abdominal aortic calcification has a high prevalence in hemodialysis patients. Abdominal aortic calcification score (AACS) is an easy method to detect abdominal aortic calcification [17].

In the current study, CIMT was higher among ESKD patients than normal population and all the patients had evidence of abdominal aortic calcification. After one year, patients received vitamin k supplementation showed insignificant increase the CIMT and AACS, associated with significant increasing MGP. In contrary, the insignificant change in the levels of MGP associated with significant progressive increase in CIMT and AACS in patients did not received vitamin K supplementation. Such a meaningful change in CIMT and AACS after a relatively short treatment is very surprising. Over the past decade, a large body of evidence has accumulated establishing that vitamin K is essential for vascular health. Vitamin K supplementation may be a simple means to prevent progression of VC in haemodialysis patients, a population characterized by severe functional vitamin K deficiency. Conversely, Vitamin K antagonists have garnered attention as they may potentially aggravate progression of VC in dialysis patients [39]. Kurnatowska et al., [40] reported an increase in CIMT was significantly lower in the vitamin K treated patients with renal failure. Gast et al., found that high dietary intake of vitamin k may protect against the development of coronary heart disease [41]. The combination of vitamin K and D is more effective in decrease progression of coronary artery calcification [30]. The decrease in progression of coronary artery calcification is associated with increasing MGP among the patients who have received vitamin K vitamin supplementation [29-31].

Dyslipidaemia is a common disorder in ESRD patients. In CKD patients, total and LDL cholesterol concentrations frequently remain comparable with that of the general population, whereas increases in the TG concentrations and decreases in the HDL cholesterol are often seen [42]. Similarly, in current study total cholesterol and LDL cholesterol concentrations remain comparable to controls, and increases in the TG concentrations and decreases in the HDL cholesterol are often seen in ESKD patients. Moreover, vitamin k supplementation for one year had decreased the level of cholesterol compared to those who did not receive vitamin k, similar result has been obtained by Kawashima et al., [43] found that daily doses of vitamin K decreased the plasma levels of total cholesterol in the vitamin K treated patients compared to hypercholesterolemic control group. In addition, American Journal of Nursing 1998 reported that Japanese clinicians gave vitamin K to patients who had chronic renal failure and were being treated with continuous ambulatory peritoneal dialysis. Total cholesterol and triglycerides were measured. After administration of vitamin K, total cholesterol concentrations were significantly lower than that before treatment. There were no significant changes in triglycerides during observation [44]. These results suggest that vitamin K may have a beneficial effect on total cholesterol concentrations. In the current study, MGP was directly correlated with serum phosphate, iPTH, blood urea, serum creatinine, cholesterol level, LDL and triglyceride level. In addition, MGP was inversely correlated with duration of hemodialysis, HDL, hemoglobin levels and AACS, and not related to age and body mass index (BMI). This were reported by previous studies [22, 32,45]. Up till now there is no treatment to reverse vascular calcification in ESKD patients. The current clinical practice should focus on prevention and retardation of its progression [46]. The main limitation of current study is the small number of examined patients resulting in weakening of the statistical power. A second, is the method we applied to evaluate the arterial calcifications. Classic radiography is a semi quantitative, not exactly accurate method. In addition to measurement of total MGP levels, we recommend measurement of gamma-carboxylated and uncarboxylated MGP forms. Despite this limitation, the results of the present study provide further evidence that vitamin k supplementation has a favorable effect on vascular calcifications.

Conclusion

Vitamin k supplementation could not stop aortic abdominal calcification and increasing in carotid intima media thickness, but significantly attenuate the progression of calcification, a longer treatment duration may prove significant amelioration of vascular calcification.

Conflict of interest

None

Acknowledgments

The authors thank Dr.  Ahmad Alaa, Prof.  Internal Medicine, Chief of Nephrology Unit, AlAzhar University, Cairo, Egypt, for his generous support. This research received no grant from any funding agency in the public, commercial or not-for-profit sectors.

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