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Determination of phylloquinone and menaquinones in food. Effect of food matrix on circulating vitamin K concentrations

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Leon J Schurgers at Maastricht University
Leon J Schurgers
Cees Vermeer at Maastricht University
Cees Vermeer
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Abstract and Figures

Fluctuations in international normalized ratio values are often ascribed to dietary changes in vitamin K intake. Here we present a database with vitamin K(1) and K(2) contents of a wide variety of food items. K(1) was mainly present in green vegetables and plant margarins, K(2) in meat, liver, butter, egg yolk, natto, cheese and curd cheese. To investigate the effect of the food matrix on vitamin K bioavailability, 6 healthy male volunteers consumed either a detergent-solubilized K(1) (3.5 micromol) or a meal consisting 400 g of spinach (3.5 micromol K(1)) and 200 g of natto (3.1 micromol K(2)). The absorption of pure K(1) was faster than that of food-bound K vitamins (serum peak values at 4 h vs. 6 h after ingestion). Moreover, circulating K(2) concentrations after the consumption of natto were about 10 times higher than those of K(1) after eating spinach. It is concluded that the contribution of K(2) vitamins (menaquinones) to the human vitamin K status is presently underestimated, and that their potential interference with oral anticoagulant treatment needs to be investigated.
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Original Paper
Haemostasis 2000;30:298–307
Determination of Phylloquinone and
Menaquinones in Food
Effect of Food Matrix on Circulating Vitamin K Concentrations
Leon J. Schurgers Cees Vermeer
Department of Biochemistry and Cardiovascular Research Institute, Maastricht University,
Maastricht, The Netherlands
Received: July 27, 2000
Accepted in revised form: September 27, 2000
Cees Vermeer, PhD
Department of Biochemistry, University of Maastricht
PO Box 616, NL–6200 MD Maastricht (The Netherlands)
Tel. +31 43 388 1682, Fax +31 43 388 4160
E-Mail c.vermeer@bioch.unimaas.nl
ABC
Fax +41 61 306 12 34
E-Mail karger@karger.ch
www.karger.com
© 2001 S. Karger AG, Basel
0301–0147/00/0306–0298$17.50/0
Accessible online at:
www.karger.com/journals/hae
Key Words
Phylloquinone W Menaquinone W Vitamin K W
Food composition W Bioavailability W
Anticoagulant, oral
Abstract
Fluctuations in international normalized ratio
values are often ascribed to dietary changes
in vitamin K intake. Here we present a data-
base with vitamin K1 and K2 contents of a
wide variety of food items. K1 was mainly
present in green vegetables and plant mar-
garins, K2 in meat, liver, butter, egg yolk, nat-
to, cheese and curd cheese. To investigate
the effect of the food matrix on vitamin K
bioavailability, 6 healthy male volunteers
consumed either a detergent-solubilized K1
(3.5 Ìmol) or a meal consisting 400 g of
spinach (3.5 Ìmol K1) and 200 g of natto
(3.1 Ìmol K2). The absorption of pure K1 was
faster than that of food-bound K vitamins (se-
rum peak values at 4 h vs. 6 h after ingestion).
Moreover, circulating K2 concentrations after
the consumption of natto were about 10
times higher than those of K1 after eating spi-
nach. It is concluded that the contribution of
K2 vitamins (menaquinones) to the human
vitamin K status is presently underestimated,
and that their potential interference with oral
anticoagulant treatment needs to be investi-
gated.
Copyright © 2001 S. Karger AG, Basel
Introduction
Vitamin K is an essential dietary micronu-
trient that facilitates the synthesis of specific
blood coagulation factors and of proteins in-
volved in bone metabolism and vascular biol-
ogy [1, 2]. It serves as a cofactor for the mem-
brane-bound microsomal enzyme Á-glutamyl-
carboxylase [3]. Dietary vitamin K is ab-
sorbed and transported in blood in its most
stable form, i.e. as a quinone. Vitamin K
occurs in two biologically active forms namely
phylloquinone (also known as vitamin K
1
)
Assessment of Menaquinones
Haemostasis 2000;30:298–307
299
and the menaquinones (known by their group
name vitamin K
2
) [2–4]. All K vitamins have
2-methyl-1,4-naphthoquinone (also known as
menadione) as a common ring structure, but
differ from each other in the length and satu-
ration degree of the polyisoprenoid side chain
attached to the 3-position. Phylloquinone is
produced by green plants, where it is tightly
associated with the thylakoid membranes of
the chloroplasts. It is a single compound con-
taining 4 isoprenoid residues (one of which is
unsaturated) in its aliphatic side chain. Mena-
quinones contain side chains of varying
length; they are designated as MK-n where n
denotes the number of isoprenoid residues, all
of which are unsaturated. Long chain mena-
quinones (MK-7 through MK-10) are exclu-
sively synthesized by bacteria [5, 6]. Mena-
dione is often added to fortified animal food
and must be converted in the liver into MK-4
before being active as a cofactor for Á-gluta-
mylcarboxylase [7, 8]. In addition, a number
of other tissues (notably pancreas, testis and
vessel wall) are capable of converting phyllo-
quinone into MK-4 [9, 10]. For these reasons
animal products (meat, dairy, eggs) may con-
tain relatively high concentrations of MK-4. It
is well known that the bacterial flora in the
colon produces large amounts of higher mena-
quinones (notably MK-10) [11], but since at
the site of synthesis absorption seems to be
unlikely, the question of whether and to which
extent the intestinal flora contributes to the
human vitamin K status is still unclear.
Warfarin and other 4-hydroxycoumarin
derivatives are antagonists of vitamin K ac-
tion and are effective antithrombotic agents
(the so-called oral anticoagulants). They block
the conversion of KO into K by inhibiting the
enzyme KO reductase, thus hampering the
recycling of vitamin K [12]. Under these con-
ditions there is a 1:1 stoichiometric relation
between KO formation and the number of
Gla residues synthesized. It is known that
25% of the patients on oral anticoagulant
treatment are not within their therapeutic
range because of fluctuating international
normalized ratio values [13]. Besides interfer-
ing drugs, age, poor compliance and concur-
rent diseases [14–18], unstable levels of anti-
coagulation are often ascribed to dietary in-
fluences, mainly fluctuating vitamin K intake
[19–23].
In absolute amounts K
1
forms well over
80% of the total amount of vitamin K in the
human diet, and most of our present knowl-
edge on vitamin K concerns K
1
. It is known,
however, that the absorption from green vege-
tables is poor and that only 10–15% of the
vitamin is bioavailable, whereas for K
2
vita-
mins this may be higher [24, 25]. Here we
present a database on both dietary forms of
vitamin K, phylloquinone and the menaqui-
nones in a wide range of foods available on
the Dutch market. Since the specimens select-
ed formed a representative sample from the
common Dutch foods the data presented here
can be used in nutritional studies in The
Netherlands. Furthermore, we compared the
efficacy of absorption of phylloquinone and
menaquinones as deduced from their serum
profiles following oral ingestion.
Materials and Methods
Materials
Phylloquinone was obtained form Sigma (St.
Louis, Mo., USA). The menaquinones (MK-4 through
MK-10) and 2,3-dihydrophylloquinone were kind gifts
from Hoffmann-La Roche (Basel, Switzerland). All
common foods were obtained at local supermarkets.
Konakion
®
(detergent-solubilized vitamin K
1
pharma-
ceutical product) was obtained from Hoffmann-La
Roche. For the nutrition experiment we used creamed
cooked spinach from Iglo Ola (Utrecht, The Nether-
lands), and natto, which was bought as a ready-to-use
product at a local oriental store. Silica Sep-Pak car-
tridges were purchased from Millipore (Milford,
Mass., USA). All other chemicals used were of the
highest analytical grade.
Age, years
300
Haemostasis 2000;30:298–307
Schurgers/Vermeer
Extraction of Food
The procedure for extraction and purification of
vitamin K from beverages and dairy produce (except
butter and cheese) was performed as described earlier
[25] using 2,3-dihydrophylloquinone as an internal
standard. Vegetables were bought as precooked deep-
frozen products. Cooked vegetables and raw fruits
were homogenized in a blender (Ultra Turrax; Janke &
Kunkel, Staufen, Germany), and processed as de-
scribed for cooked spinach [25]. Aliquots of 1 g of
cheese, butter or margarine were extracted with 4 ml of
2-propanol, 20 ng internal standard (MK-6 for marga-
rine, 2,3-dihydrophylloquinone for other products)
and 2 ml of distilled water. The mixture was homoge-
nized with a blender, warmed to a temperature of
60°C and extracted with 8 ml of hexane. Raw meat
and fish were cut into pieces, 1 g of which was supple-
mented with 2 ml of distilled water, 5 ng of internal
standard (2,3-dihydrophylloquinone) and 4 ml of etha-
nol. Homogenization took place with a blender at
room temperature, and 8 ml of hexane were used for
extraction. Bread was dried and ground to powder in
a mortar, 1-gram aliquots were supplemented with
5 ng internal standard (2,3-dihydrophylloquinone) and
4 ml of ethanol. After homogenization in a blender ex-
traction took place with 8 ml of hexane. In all cases, the
hexane phase was evaporated and redissolved in 2 ml
of hexane. After prepurification over silica Sep-Pak
cartridges the samples were ready to measure on
reversed-phase HPLC. All samples were measured in
duplicate.
Vitamin K Detection
Vitamin K was analyzed by HPLC using a C-18
reversed phase column and fluorometric detection af-
ter postcolumn electrochemical reduction as described
previously [25]. Phylloquinone and the menaquinones
were recorded in the same run. Because of the long
retention times for the long-chain menaquinones the
flow was increased from 0.5 to 1.0 ml/min at 11 min
after injection. The interday variation was 6–8%.
Human Volunteer Study
A panel of 6 male volunteers took part in this proto-
col. Their mean age was 33.5 years, and their body
mass index was 24.3 kg/m
2
(table 1). All participants
were apparently healthy, and their serum lipid profiles
were in the normal range. Neither medications nor
vitamin supplements (other than the experimental
supplements) were taken. The experimental protocol
started at 8 a.m. after an overnight fast. At that time
the participants received a breakfast containing either
a diet low in vitamin K, a similar diet with additional
Table 1.
Characteristics of the subjects
Mean SEM
33.5 2.57
Body mass index, kg/m
2
24.3 0.82
Triacylglycerol, mmol/l 0.87 0.14
Cholesterol, mmol/l 3.96 0.28
Vitamin K
Phylloquinone, nmol/l 1.48 0.19
Menaquinones, nmol/l n.d.
Mean values B SEM of 6 healthy male volunteers.
n.d. = Not detectable.
detergent-solubilized phylloquinone, or a diet contain-
ing 400 g of spinach and 200 g of natto. All diets con-
tained 30 g of fat. During the rest of the day partici-
pants were only allowed to have a lunch low in vitamin
K (toast, marmalade, bananas, apples), and to drink
orange juice and water ad libitum. After 6 p.m. and
during the rest of the experiment only consumption of
vitamin K-rich foods (spinach, broccoli, brussels
sprouts, kale, natto and cheese) was prohibited. Blood
samples were drawn by venipunctures at 0, 1, 2, 3, 4, 5,
6, 7, 8, 10, 11, 24, 48 and 72 h after start. Serum was
prepared and 1-ml aliquots were kept frozen at –80°C
until vitamin K determination. The study design was
approved by the local Medical Ethics Committee, and
informed consent was obtained from all subjects ac-
cording to the institutional guidelines.
Data Analysis
Serum vitamin K concentrations during 72 h after
oral ingestion were recorded at indicated intervals. At
each time point mean values B SE for the 6 partici-
pants were calculated and plotted as a function of time.
Blank values (no vitamin K ingested) were subtracted
throughout the study.
Results
Vitamin K Content of Various Nutrients
For the determination of dietary phyllo-
quinone and menaquinones we subdivided
common foods into six categories: meat, fish,
vegetables and fruits, dairy, oils and marga-
Assessment of Menaquinones
Haemostasis 2000;30:298–307
301
Table 2.
Mean of K vitamins (Ìg/100 g or Ìg/100 ml) in various foods
Type of food n K
1
MK-4
Meat
Beef 7 0.6 (0.6–0.7) 1.1 (0.7–1.3)
Chicken breast 7 8.9 (6.4–11.3)
Chicken leg 7 8.5 (5.8–10.5)
Pork steak 7 0.3 (0.2–0.4) 2.1 (1.7–2.4)
Pork liver 7 0.2 (0.1–0.3) 0.3 (0.3–0.4)
Minced meat 7 2.4 (2.2–2.5) 6.7 (6.5–6.7)
Salami 7 2.3 (2.1–2.5) 9.0 (8.2–10.1)
Luncheon meat 7 3.9 (3.8–4.2) 7.7 (7.4–9.1)
Hare leg 7 4.8 (4.5–5.3) 0.1 (0.0–0.2)
Deer back 7 2.0 (1.9–2.2) 0.7 (0.6–0.7)
Goose leg 5 4.1 (3.5–4.8) 31.0 (28.2–33.1)
Goose liver paste 5 10.9 (9.3–12.1) 369 (317–419 )
Duck breast 7 1.9 (1.7–2.2) 3.6 (3.3–3.9)
MK-5 MK-6 MK-7 MK-8 MK-9
––––
––––
––––
0.5 (0.4–0.7) 1.1 (0.9–1.2)
––––
––––
––––
––––
––––
––––
––––
––––
Fish
Prawn 7 0.1 (0.0–0.1)
Mackerel 7 2.2 (1.8–2.6) 0.4 (0.3–0.5)
Herring 7 0.1 (0.0–0.2)
Plaice 7 0.2 (0.1–0.3)
Eel 7 0.3 (0.2–0.5) 1.7 (1.4–2.1)
Salmon 7 0.1 (0.1–0.2) 0.5 (0.4–0.6)
Fruits and vegetables
Kale 4 817 (752–881)
Spinach 6 387 (299–429)
Broccoli 5 156 (139–189)
Green peas 4 36.0 (31.2–39.4)
Sauerkraut 7 25.1 (23.8–27.5) 0.4 (0.3–0.5)
Natto 5 34.7 (31.2–36.7)
Banana 4 0.3 (0.2–0.4)
Apple 4 3.0 (2.7–3.4)
Orange 4 0.1 (0.1–0.2)
+
––––
––––
––––
0.3 (0.2–0.3) 0.1 (0.0–0.1) 1.6 (1.3–1.8)
0.1 (0.0–0.2) 0.4 (0.2–0.6)
––––
––––
––––
––––
––––
0.8 (0.6–1.0) 1.5 (1.4–1.6) 0.2 (0.1–0.3) 0.8 (0.6–0.9) 1.1 (0.9–1.3)
7.5 (7.1–7.8) 13.8 (12.7–14.8) 998 (882–1,034) 84.1 (78.3–89.8)
––––
––––
302
Haemostasis 2000;30:298–307
Schurgers/Vermeer
Table 2
(continued)
Type of food n K
1
MK-4
Dairy produce
Whole milk 6 0.5 (0.4–0.6) 0.8 (0.7–0.9)
Skimmed milk 6
Buttermilk 6 0.2 (0.2–0.3)
Whole yoghurt 6 0.4 (0.3–0.5) 0.6 (0.5–0.7)
Skimmed yoghurt 6
Whipping cream 6 5.1 (4.9–5.5) 5.4 (5.2–5.6)
Chocolate 6 6.6 (6.4–6.7) 1.5 (1.4–1.6)
Hard cheeses 15 10.4 (9.4–12.1) 4.7 (4.2–6.6)
Soft cheeses 15 2.6 (2.4–2.9) 3.7 (3.3–3.9)
Curd cheese 12 0.3 (0.2–0.4) 0.4 (0.3–0.6)
Egg yolk 8 2.1 (1.9–2.3) 31.4 (29.1–33.5)
Egg albumen 8 0.9 (0.8–1.0)
MK-5 MK-6 MK-7 MK-8 MK-9
0.1 (0.0–0.1) ––––
––––
0.1 (0.1–0.2) 0.1 (0.0–0.2) 0.1 (0.1–0.3) 0.6 (0.5–0.6) 1.4 (1.2–1.6)
0.1 (0.0–0.2) 0.2 (0.2–0.3)
0.1 (0.0–0.2)
––––
––––
1.5 (1.3–1.7) 0.8 (0.6–1.0) 1.3 (1.1–1.5) 16.9 (14.9–18.2) 51.1 (45.3–54.9)
0.3 (0.2–0.4) 0.5 (0.6–0.7) 1.0 (0.9–1.1) 11.4 (10.7–12.2) 39.6 (35.1–42.7)
0.1 (0.0–0.2) 0.2 (0.1–0.3) 0.3 (0.2–0.5) 5.1 (4.8–5.4) 18.7 (18.1–19.2)
0.7 (0.6–0.8)
––––
Oils and margarines
Margarine 6 93.2 (85.6–98.3)
Butter 6 14.9 (13.2–15.9) 15.0 (13.5–15.9)
Corn oil 6 2.9 (2.7–3.1)
Sunflower oil 6 5.7 (5.5–5.9)
Olive oil 6 53.7 (49.9–57.2)
Bread
Rue bread 6 0.7 (0.5–0.9)
Wheaten bread 6 1.1 (1.0–1.2)
Sourdough bread 6 1.0 (0.9–1.1)
Buckwheat bread 6 3.0 (2.8–3.4)
Beverages
Tea 4 0.3 (0.2–0.4)
Coffee 4
Orange juice 4
All samples were assessed in duplicate. Values are mean values. Highest and lowest values are given in parentheses. Foods were bought from shops in
and around Maastricht. MK-10 was not detectable in any of the foods. N = Number of different samples tested; – = not detectable.
––––
––––
––––
––––
––––
––––
––––
––––
1.1 (1.0–1.2)
––––
––––
––––
Assessment of Menaquinones
Haemostasis 2000;30:298–307
303
Fig. 1.
Serum vitamin K following the oral intake of either Konakion or a meal containing
spinach and natto. The ingested Konakion contained 3.5 ÌM K
1
, the mixed meal contained
3.5 ÌM of K
1
and 3.1 ÌM of MK-7. Points represent mean values from 6 volunteers, error bars
represent SEM. [ = K
1
after Konakion; $ = K
1
after mixed meal; P = MK-7 after mixed
meal.
rines, bread, and beverages. At least three to
six different samples or brands were obtained
in various local supermarkets, and mean val-
ues for each product are given in table 2
together with their ranges for each product.
High amounts of K
1
were found in green leafy
vegetables, broccoli, sauerkraut and marga-
rines based on plant oils. Meat, fish, dairy
produce and eggs contained both K
1
and MK-
4 with relatively high MK-4 concentrations in
goose meat and liver, butter and egg yolk.
Long-chain menaquinones were mainly found
in curd cheese, hard (Dutch) and soft (French)
cheeses, probably derived from the bacterial
starter fermentation. Very rich in menaqui-
nones was the Japanese food natto, which
consists of fermented soy beans. No substan-
tial differences were found between free-range
products (eggs, chicken, meat) and those from
factory farms. The fact that fermented bever-
ages like beer and wines did not contain
detectable amounts of menaquinones is prob-
ably due to the fact that moulds do not synthe-
size menaquinones [26].
Bioavailability of K Vitamins from Food
To examine the blank values (serum vita-
min K at low vitamin K intake) 6 male volun-
teers received a vitamin K-poor breakfast
with blood sampling (up to 72 h) as indicated.
These blank values (data not shown) were
subtracted from those obtained after con-
trolled vitamin K intake. Based on the analy-
ses summarized in table 2 we have prepared
meals consisting of 400 g cooked spinach
(equivalent to 3.5 Ìmol of K
1
), 200 g natto
(3.1 Ìmol of MK-7), supplemented with corn
oil to a total fat content of 30 g. Postprandial
304
Haemostasis 2000;30:298–307
Schurgers/Vermeer
Fig. 2.
Serum vitamin K
1
and MK-7 following the separate intake of either spinach (3.5 ÌM
K
1
) or natto (3.1 ÌM MK-7). Points represent mean values from 6 volunteers, error bars
represent SEM. $ = K
1
; P = MK-7.
serum vitamin K concentrations are given in
figure 1. One week later the volunteers re-
ceived a vitamin K-poor breakfast supple-
mented with 3.5 Ìmol of Konakion. Peak val-
ues for serum vitamin K (both K
1
and MK-7)
were found at 6 h following the meal, and at
4 h after intake of the pure compound. The
very poor absorption from green vegetables
becomes clear by comparing the difference
between the curves for K
1
pure compound
and the similar amount of K
1
from spinach.
Remarkably, MK-7 from natto was absorbed
extremely well with peak values even higher
than those for detergent-solubilized K
1
. After
having reached their peak levels a rapid disap-
pearance of both K
1
and MK-7 was observed,
but MK-7 showed complex pharmacokinet-
ics, with slow disappearance during the sec-
ond part of the curve, while it remained
detectable for at least 72 h. The half-life times
for both K
1
and MK-7 between 6 and 8 h post-
prandially were about 1.5 h, whereas during
the later phases of MK-7 disappearance the
half-life time was about 50 h. To exclude
mutual interference of absorption (e.g. by
competition for the same binding protein),
the above experiment was repeated in a de-
sign in which spinach and natto were given in
two separate meals with a 1-week interval.
The serum curves are shown in figure 2 and
are comparable to those obtained after the
combined meal.
The above absorption curves were re-
peated for other foods: broccoli as source for
K
1
and curd cheese and egg yolk as sources for
higher menaquinones (MK-8 and MK-9) and
MK-4, respectively [Schurgers, unpubl. data].
In all cases it was found that K
1
absorption
from vegetables was very poor (5–10% with-
out concomitant fat intake and 10–15% if tak-
Assessment of Menaquinones
Haemostasis 2000;30:298–307
305
en together with 30 g fat), whereas menaqui-
none absorption from dairy produce and nat-
to was much better, probably almost com-
plete.
Discussion
In this paper we describe the phylloqui-
none and menaquinone content of various
foods available on the Dutch market. All K
vitamins were quantified in the same run
after a slight modification of our previously
reported procedure [25]. It was confirmed
that phylloquinone is mainly present in green
vegetables, margarins and some plant oils
such as olive oil. Since these data are similar
to those reported by others [27–29] we have
focussed on the menaquinones in food. MK-4
was present in nearly all animal products
(meat, dairy produce, eggs), but the fact that
there were no substantial differences between
game (hare, deer), free-range animals and
those from factory farms suggests that conver-
sion of menadione from fortified animal food
(used at factory farms) does not contribute
substantially to the total tissue MK-4 stores.
Rather, it seems that the major part of MK-4
in animal products originates from conver-
sion of K
1
as was also reported to occur in
rats [10]. Relatively high concentrations of
long-chain menaquinones were found in all
cheeses. As was suggested by Shearer [26],
they probably originate from bacteria present
in the starter cultures used to induce fermen-
tation. On the basis of food frequency ques-
tionnaires and the data in table 2 it has been
calculated that phylloquinone forms almost
90% of the total dietary vitamin K intake in
the Dutch population, whereas menaqui-
nones account for less than 12% [6]. Phyllo-
quinone, however, is tightly bound to the thy-
lakoid membranes of plant chloroplasts, and
the efficacy of its liberation therefrom in the
digestive tract is poor [24, 25]. This was con-
firmed in an experiment in which we com-
pared the serum concentration vitamin K
profiles after ingestion of similar amounts of
K
1
from spinach and from a detergent-solubi-
lized pharmaceutical product. To compare
the efficacy of absorption of phylloquinone
and menaquinone we have chosen a design in
which K
1
was obtained from spinach and
MK-7 from natto. In this way the molar con-
centrations of both K vitamers could be kept
similar. As is shown in figure 1, the postpran-
dial serum concentrations of MK-7 were
much higher than those of K
1
, with a peak
height difference of more than 10-fold. Both
absorption peaks occurred 2 h later than that
for the detergent-solubilized product. From
the curves obtained, it may be concluded that
the contribution of MK-7 from natto to the
total bioavailable pool of vitamin K is much
higher than estimated on the basis of intake.
Menaquinones from other sources (cheeses,
egg yolk) were absorbed with comparable effi-
cacy as was MK-7 [Schurgers, unpubl. data],
suggesting that the contribution of menaqui-
nones to the total human vitamin K status is
much higher than generally assumed, and
may equal that of K
1
.
Another remarkable difference between K
1
and menaquinones was that the former had a
disappearance curve with an apparent half-
life time of 1.5 h, whereas the long chain men-
aquinones (not MK-4) had more complex dis-
appearance curves with a very long half-life
time. Rapid clearance is consistent with the
previously reported uptake and transport of K
vitamins in chylomicrons, from where they
are cleared by the liver during the first 8 post-
prandial hours. The very long half-life times
of the higher menaquinones suggest that these
vitamers (and not K
1
and MK-4) are redis-
tributed by the liver and set free in the circula-
tion in low and high density lipoproteins. It is
well known that LDL may be present in the
306
Haemostasis 2000;30:298–307
Schurgers/Vermeer
circulation for several days. The long resi-
dence times of higher menaquinones in the
circulation implies that they are available for
extrahepatic tissue uptake for much longer
periods than is phylloquinone. Both because
of their high postprandial serum concentra-
tion and their slow clearance, the importance
of higher menaquinones for extrahepatic tis-
sues such as bone and arterial vessel wall may
be underestimated if only dietary intake is
regarded. Since vitamin K-dependent pro-
teins have been reported to be involved in the
regulation of calcium deposition in bone [30]
and in the prevention of arterial calcification
[31], intake of higher menaquinones may be
important for functions of vitamin K not
related with blood coagulation.
The high efficacy of menaquinone absorp-
tion may also have consequences for subjects
on oral anticoagulant treatment. In attempts
to identify potential causes of unstable anti-
coagulation, menaquinone intake has been ig-
nored thus far. Our data demonstrate that this
is not justified. Their efficient absorption
combined with long serum and tissue half-life
times [32] suggests that menaquinones from
curd and cheese may accumulate at repeated
intake and are a potential cause of distur-
bance of anticoagulant therapy. This is even
more so for subjects consuming natto. Al-
though in general natto is not eaten by Cauca-
sians, dietary habits may survive after migra-
tion of subjects from Asiatic countries so that
hematologists in western countries may be
confronted with this unsuspected source of
highly bioavailable vitamin K.
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... VK1 is a single compound present in photosynthetic organisms like green plants or vegetables [17,18] and constitutes approximately 75-90% of dietary sources of VK [19]. The content of VK in dietary sources is summarized in Table 1. ...
... The content of VK in dietary sources is summarized in Table 1. Generally, all edible green plants can be considered an impartment source of VK1, among which kale and spinach are the richest vegetable sources of VK1, and their VK1 content can reach 817 µg/100 g and 387 µg/100 g, respectively [19]. Additionally, certain vegetable oils are also dietary sources of VK1, with soybean oil, rapeseed oil, and olive oil containing an average of 173, 123, and 53.7 µg/100 g of VK1, respectively [19,20]. ...
... Generally, all edible green plants can be considered an impartment source of VK1, among which kale and spinach are the richest vegetable sources of VK1, and their VK1 content can reach 817 µg/100 g and 387 µg/100 g, respectively [19]. Additionally, certain vegetable oils are also dietary sources of VK1, with soybean oil, rapeseed oil, and olive oil containing an average of 173, 123, and 53.7 µg/100 g of VK1, respectively [19,20]. As the predominant form of VK, VK1 is used in food supplements and drugs indicated in VK deficiency. ...
The Potential of Vitamin K as a Regulatory Factor of Bone Metabolism—A Review
Article
Full-text available
  • Nov 2023
Vitamin K (VK), a fat-soluble vitamin, is essential for the clotting of blood because of its role in the production of clotting factors in the liver. Moreover, researchers continue to explore the role of VK as an emerging novel bioactive molecule with the potential function of improving bone health. This review focuses on the effects of VK on bone health and related mechanisms, covering VK research history, homologous analogs, dietary sources, bioavailability, recommended intake, and deficiency. The information summarized here could contribute to the basic and clinical research on VK as a natural dietary additive and drug candidate for bone health. Future research is needed to extend the dietary VK database and explore the pharmacological safety of VK and factors affecting VK bioavailability to provide more support for the bone health benefits of VK through more clinical trials.
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... The FFQ is composed of 54 food items that contain ≥5 µg of vitamin K/100 g of food or, despite having <5 µg of vitamin K/100 g of food, are commonly included in a Mediterranean diet (soft cheese, boiled chickpeas, pumpkin, bell pepper, mackerel, sardines, almonds, walnuts, and coffee) [29]. Data on the vitamin K content of foods were derived from previous research [12], as well as from both McCance and Widdowson's and the United States Department of Agriculture's food composition databases [30,31]. The detailed description of the FFQ and the methods used for its validation are presented elsewhere [32]. ...
Mediterranean Diet Favors Vitamin K Intake: A Descriptive Study in a Mediterranean Population
Article
Full-text available
  • Apr 2024
The Mediterranean diet (MD) is associated with improved longevity and the prevention and management of chronic inflammatory diseases (CIDs). Vitamin K, which is present in MD core components such as leafy green vegetables, is also known as a protective factor for CIDs. Estimates of vitamin K intake in Mediterranean settings are still scarce, and the association between MD and vitamin K intake is yet to be established. This study analyzed vitamin K intake and MD adherence in the Algarve region, in Portugal. We conducted a cross-sectional study in a nonrandom sample of adults using an online questionnaire which included a validated food-frequency questionnaire and a screener for MD adherence. A total of 238 participants were recruited (68% women and 32% men). Adherence to the MD was low (11%). Only 10% of the participants had vitamin K intake below the adequate intake. Adherence to the MD was positively correlated with vitamin K intake (r = 0.463; p < 0.001) and age (r = 0.223; p < 0.001). Our findings underscore the importance of promoting adherence to the MD for optimal vitamin K intake, and future research should focus on developing effective interventions to promote this dietary pattern, particularly among younger individuals and men.
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... In the female group of the main group and the test-article administration group of the recovery group, no statistically significant changes were observed compared with the negative control group. A statistically significant increase in the relative organ weight of the lung was observed in the male high-dose group of the recovery group compared with the negative control group (Tables 4,5). In the autopsy findings, one case of yellow spots on the skin of the left epididymis was observed in the male high-dose group of the main study. ...
Safety evaluation of vitamin K2 (menaquinone-7) via toxicological tests
Article
Full-text available
  • Mar 2024
This study aims to evaluate the safety of MK-7 produced by fermentation process using a Bacillus subtilis var. natto strain for human ingestion via acute oral toxicity, repeated dose 90-day oral toxicity, 28-day recovery test, and genotoxicity tests. The acute oral toxicity test results indicated that all subjects survived at the dose of 5000 mg/kg with no toxic effects. For the repeated dose 90-day oral toxicity test, MK-7 was administered to rats at 500, 1500, and 4500 mg/kg for 90 d. No abnormal findings were detected in clinical observations or in clinical pathological and histopathological examinations. The no-observed-adverse-effect level(NOAEL) was determined to be 4500 mg/kg/d, the maximum dose tested. For the evaluation of genotoxicity, reverse mutation, chromosomal aberration, and micronucleus tests were performed. In the reversion mutation test, vitamin K2 did not induce reversion in bacterial strains, and no chromosomal abnormality was observed in the chromosomal abnormality test using Chinese hamster lung cells. In the micronucleus test, micronuclei were not induced using ICR mouse bone marrow cells. All the toxicity test results suggest that vitamin K2 produced by fermentation processes using Bacillus subtilis var. natto induced no toxicological changes under the experimental conditions.
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... phylloquinone has a phytyl side chain with one double bond and is found exclusively in plants, especially green leafy vegetables. It accounts for 75-90% of dietary vitamin K intake [3], with high concentrations in kale, spinach, and leeks [15]. Vitamin K2 consists of various isoforms with varying amounts of isoprenoid units connected to the menaquinone 3-position isoprene side chain. ...
Revisiting the interconnection between lipids and vitamin K metabolism: insights from recent research and potential therapeutic implications: a review
Article
Full-text available
  • Jan 2024
  • NUTR METAB
Vitamin K is a lipophilic vitamin, whose absorption, transportation, and distribution are influenced by lipids. The plasma vitamin K level after supplementation is predominantly a lipid-driven effect and independent of existing vitamin K status. However, previous studies examining the efficacy of vitamin K supplementation often overlooked the influence of lipid levels on vitamin K absorption, resulting in inconsistent outcomes. Recent research discovered that impaired transportation of vitamin K2 within uremic high-density lipoproteins (HDL) in individuals with uremia might elucidate the lack of beneficial effects in preventing calcification observed in multiple trials involving menaquinone-7 (MK-7) supplementation among patients with chronic kidney disease. Clinical findings have shown that drugs used to regulate hyperlipidemia interact with the vitamin K antagonist warfarin, because cholesterol and vitamin K share common transport receptors, such as Niemann-Pick C1-like 1 (NPC1L1) and ATP-binding cassette protein G5/G8 (ABCG5/ABCG8), in enterocytes and hepatocytes. Additionally, cholesterol and vitamin K share a common biosynthetic intermediate called geranylgeranyl pyrophosphate (GGPP). It is important to note that statins, which hinder cholesterol synthesis, can also impede vitamin K conversion, ultimately impacting the functionality of vitamin K-dependent proteins. Furthermore, certain studies have indicated that vitamin K supplementation holds potential in managing hyperlipidemia, potentially opening a novel avenue for controlling hyperlipidemia using dietary vitamin K supplements. Therefore, attaining a more comprehensive understanding of the intricate interplay between vitamin K and lipids will yield valuable insights concerning the utilization of vitamin K and lipid regulation.
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... Various factors can impact vitamin K levels in CKD patients, with the primary culprits for its de ciency being food limitations, uremia-induced dysbiosis, and certain medications [18]. Additionally, the necessity to restrict dietary intake due to the high potassium content in many vitamin K-rich green vegetables contributes to its insu ciency [19]. In addition to dietary sources, vitamin K undergoes recycling through the "vitamin K cycle," which involves enzymes like vitamin K epoxide reductase, DT-diaphorase, and gglutamylcarboxylase. ...
Assessment of vitamin K2 status in children with chronic kidney diseases
Preprint
Full-text available
  • Oct 2023
Background : Vitamin K2 plays a crucial role in the formation of osteocalcin in bones, matrix GLa protein in cartilage, and the walls of blood vessels. we aimed to investigate vitamin K2 status in children with CKD G5D, without KRT and after renal transplantation, and its relation to bone turnover by measuring bone turnover marker (bone alkaline phosphatase- BAP). Methods: We enrolled 75 patients classified into 3 groups: group A; CKD without KRT, group B; CKD G5D and group C; renal transplant recipients. Another 25 healthy individuals were involved as a control group. Under carboxylated osteocalcin (uOC) (as a sensitive indicator of vitamin K level) and BAP were measured in fasting blood samples in all patients. 24-hour dietary recall was used to assess vitamin k, calcium, and phosphorus intake. Vitamin and mineral intake was calculated as a percent of target requirements of age and sex-matched healthy children. Results: uOC was found significantly higher in the patient groups in comparison to the control group (p <0.001). The highest level of uOC was detected in the HD group. In all groups except the HD group, robust negative correlations were observed between uOC and both eGFR and vitamin K (%) levels. There was a statistically significant difference in uOC (p < 0.001) between those with history of bone fractures (No.= 7) compared to those without fractures (No.= 93). By logistic regression analysis, increasing uOC was associated with an increased likelihood of exhibiting bone fractures (p = 0.012). Conclusion: elevated uOC levels were observed in children with CKD and demonstrated a correlation with eGFR. Additionally, they exhibited a notable association with heightened bone turnover status, as indicated by BAP levels.
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Natural and Plant-Derived Vitamins: A Comprehensive Review of Biochemistry, Pharmacology and Nutritional Benefits in Health and Disease
Chapter
  • May 2024
In this comprehensive review, we reflect of the historical perspectives in the discovery of vitamins about a century ago and summarize the neuroprotective, cardioprotective, and other benefits of vitamins in health and disease. We also focus on the clinical trials, optimal daily requirements, and basic research being done in evaluating the safety and efficacy of water-soluble and lipid-soluble vitamins. Since the human body cannot synthesize majority of vitamins, therefore, exogenous supplementation of vitamins is critical for health promotion and disease prevention. The water-soluble vitamins (B-types and C) are excreted quickly from the body and may not produce any detrimental effects when taken in relatively large doses. However, excessive intake and abuse of lipid-soluble vitamins (A, D, E, K) may produce adverse effects due to their deposition in adipose tissue and long half-lives. Internet, television, popular media, and home magazines generally promote all sorts of health benefits of single and multiple vitamins these days. Therefore, the global vitamin supplementation and nutraceuticals market has escalated immensely to a multibillion-dollar business worldwide.
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Vitamin K: Infection, Inflammation, and Auto-Immunity
Article
Full-text available
  • Feb 2024
Vitamin K (VK) comprises a group of substances with chlorophyll quinone bioactivity and exists in nature in the form of VK1 and VK2. As its initial recognition originated from the ability to promote blood coagulation, it is known as the coagulation vitamin. However, based on extensive research, VK has shown potential for the prevention and treatment of various diseases. Studies demonstrating the beneficial effects of VK on immunity, antioxidant capacity, intestinal microbiota regulation, epithelial development, and bone protection have drawn growing interest in recent years. This review article focuses on the mechanism of action of VK and its potential preventive and therapeutic effects on infections (eg, asthma, COVID-19), inflammation (eg, in type 2 diabetes mellitus, Alzheimer’s disease, Parkinson’s disease, cancer, aging, atherosclerosis) and autoimmune disorders (eg, inflammatory bowel disease, type 1 diabetes mellitus, multiple sclerosis, rheumatoid arthritis). In addition, VK-dependent proteins (VKDPs) are another crucial mechanism by which VK exerts anti-inflammatory and immunomodulatory effects. This review explores the potential role of VK in preventing aging, combating neurological abnormalities, and treating diseases such as cancer and diabetes. Although current research appoints VK as a therapeutic tool for practical clinical applications in infections, inflammation, and autoimmune diseases, future research is necessary to elucidate the mechanism of action in more detail and overcome current limitations.
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Tocopherol and phylloquinone biosynthesis in chloroplasts requires the phytol kinase VTE5 and the farnesol kinase FOLK
Article
  • Dec 2023
Chlorophyll degradation causes the release of phytol, which is converted into phytyl-diphosphate (phytyl-PP) by phytol kinase (VITAMIN E PATHWAY GENE5, VTE5) and phytyl-phosphate (phytyl-P) kinase (VTE6). The kinase pathway is important for tocopherol synthesis, as the Arabidopsis (Arabidopsis thaliana) vte5 mutant contains reduced levels of tocopherol. Arabidopsis harbors one paralog of VTE5, FOLK (farnesol kinase) involved in farnesol phosphorylation. Here, we demonstrate that VTE5 and FOLK harbor kinase activities for phytol, geranylgeraniol and farnesol with different specificities. While the tocopherol content of the folk mutant is unchanged, vte5-2 folk plants completely lack tocopherol. Tocopherol deficiency in vte5-2 plants can be complemented by overexpression of FOLK, indicating that FOLK is an authentic gene of tocopherol synthesis. The vte5-2 folk plants contain only ∼40% of wild-type amounts of phylloquinone, demonstrating that VTE5 and FOLK both contribute in part to phylloquinone synthesis. Tocotrienol and menaquinone-4 were produced in vte5-2 folk plants after supplementation with homogentisate or 1,4-dihydroxy-2-naphthoate, respectively, indicating that their synthesis is independent of the VTE5/FOLK pathway. These results show that phytyl moieties for tocopherol synthesis are completely, but for phylloquinone production only partially derived from geranylgeranyl-chlorophyll and phytol phosphorylation by VTE5 and FOLK.
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VITAMIN K: OVERVIEW AND ITS EFFECT ON HUMAN HEALTH BEYOND COAGULATION
Article
Full-text available
  • Jan 2022
The traditional understanding of Vitamin K is that it aids in blood coagulation. In more recent times, Vitamin K has taken on new functions. The review article will discuss the most recent research on Vitamin K's effect on Human bone, causing cancer due to the deficiency of Vitamin K, and its effect on newborn babies. This article has also discussed the reasons for taking Vitamin K and its adequate amount in children, males, and females.
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Comparison of Phylloquinone Bioavailability from Food Sources or a Supplement in Human Subjects
Article
  • Jun 1999
Phylloquinone (K) absorption was assessed in 22- to 30-y-old human subjects consuming a standard test meal [402 kcal (1682 kJ), 27% energy from fat]. The absorption of phylloquinone, measured over a 9-h period as the area under the curve (AUC), was higher (P < 0.01) after the consumption of a 500-μg phylloquinone tablet [27.55 ± 10.08 nmol/(L · h), n = 8] than after the ingestion of 495 μg phylloquinone as 150 g of raw spinach [4.79 ± 1.11 nmol/(L · h), n = 3]. Less phylloquinone (P < 0.05) was absorbed from 50 g of spinach (AUC = 2.49 ± 1.11 nmol/(L · h) than from 150 g of spinach. Absorption of phylloquinone from fresh spinach (165 μg K), fresh broccoli (184 μg K) and fresh romaine lettuce (179 μg K) did not differ. There was no difference in phylloquinone absorption from fresh or cooked broccoli or from fresh romaine lettuce consumed with a meal containing 30 or 45% energy as fat.
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Vitamin K1 (phylloquinone) content of edible oils: Effects of heating and light exposure
Article
  • Oct 1992
The vitamin K1 content of 10 commercially available vegetable oils was determined by reversed-phase high-performance liquid chromatography (HPLC). Prior to HPLC, crude lipid extracts were purified by solid-phase extraction on silica. Rapeseed and soybean oils were found to contain the greatest amounts of vitamin K1 (140-200 mug/100 g) followed by olive oil (55 mug/100 g). Almond, sunflower, safflower, walnut, and sesame oils contained between 6 and 15 mug/100 g, while peanut and corn oils provided less than 3 mug/100 g. Vitamin K1 was stable to processing mode, decreased slightly but significantly with heat, and was rapidly destroyed by both daylight and fluorescent light. Amber glass containers protected the oils from the destructive effects of light. Soybean and rapeseed oils are excellent sources of vitamin K1 and can provide greater than 100 % of the required dietary allowance for vitamin K when present in the diet at greater than 15 % of the caloric content.
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Vitamin K1 (Phylloquinone) Content of Foods: A Provisional Table
Article
  • Jun 1993
A provisional table on the vitamin K1 (phylloquinone) content of foods was compiled in response to the expressed need for tabulated data by the public and professionals in medicine, nutrition, dietetics, and research. Data for vitamin K1 content in foods were evaluated according to criteria set for the analytical method, sampling, and quality control, with a confidence code assigned to each accepted value for each food item. Given the large analytical variation associated with the chick bioassays, only data obtained from methods using HPLC (high-performance liquid chromatography) were used. An effort was made to include vitamin K values that were representative of foods in the retail market. There are few food composition data for this nutrient. The available data do indicate that leafy, green vegetables, and certain legumes and vegetable oils are good dietary sources of vitamin K1. The distribution of vitamin K1 in plants is not uniform, with higher concentrations of the vitamin found in the outer leaves as compared to concentrations in the pale, inner leaves. The peels of fruits and vegetables appear to have higher concentrations of the vitamin than do the fleshy portions. Recent investigations indicate that season, climate, growing location, and soil fertility are sources of natural variation in the vitamin K1 concentration of foods. The limited data on the vitamin K1 content of foods need to be expanded to include other commonly-consumed foods, including prepared foods. One approach would be an improved database for simple foods, which could then be used in the U.S. Department of Agriculture recipe file of the USDA Survey Nutrient Database to calculate the vitamin K1 content of multicomponent foods. Furthermore, investigation is required to differentiate natural variation from that attributable to analytical methodology and sample preparation, such as homogenization and cooking.
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Tissue distribution of K-vitamers under different nutritional regimens in rats
Article
  • Feb 1998
  • Biochim Biophys Acta
Two forms of vitamin K [phylloquinone (K1) and menaquinone-4 (MK-4)] were added to vitamin K-deficient rat food in varying amounts. These diets were given as the sole source of nutrition to rats for one week. The minimal dietary requirements (MDR) to attain maximal prothrombin synthesis were determined to be 0.6 and 6–10 μg/g of food for K1 and MK-4, respectively. The difference between both vitamers could be explained by the limited hepatic accumulation of MK-4. Next, vitamin K was offered to rats at concentrations ranging between 0.6 and 3000 μg/g of food, and the tissue distribution of vitamin K was investigated after one week of administration. Accumulation of K1 and MK-4 was found in all tissues investigated, but both the absolute tissue concentration and the ratio between K1 and MK-4 were tissue-dependent. Highest values were found in liver and in heart, but since the heart contains no γ-glutamylcarboxylase, the function of vitamin K in this tissue remains obscure. High tissue concentrations of MK-4 were also found in pancreas and testis after a diet containing K1 exclusively. The data indicate that this conversion is tissue-specific, but neither the reason nor its mechanism are known.
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Intestinal flora is not an intermediate in the phylloquinone-menaquinone-4 conversion in the rat
Article
  • Feb 1998
  • Biochim Biophys Acta
To elucidate the role of intestinal bacteria in the conversion of phylloquinone into menaquinone-4 (MK-4) we investigated the tissue distribution of vitamin K in germ-free rats. The rats were made vitamin K deficient by feeding a vitamin K-free diet for 13 days. In a subsequent period of 6 days, phylloquinone and menadione were supplied via the drinking water in concentrations of 10 and 50 μmol l−1. Menadione supplementation led to high levels of tissue MK-4, particularly in extrahepatic tissues like pancreas, aorta, fat and brain. Liver and serum were low in MK-4. Phylloquinone supplementation resulted in higher phylloquinone levels in all tissues when compared with vitamin K-deficient values. The main target organs were liver, heart and fat. Remarkably, tissue MK-4 levels were also higher after the phylloquinone supplementation. The MK-4 tissue distribution pattern after phylloquinone intake was comparable with that found after menadione intake. Our results demonstrate that the conversion of phylloquinone into MK-4 in extrahepatic tissues may occur in the absence of an intestinal bacterial population and is tissue specific. A specific function for extrahepatic MK-4 or a reason for this biochemical conversion of phylloquinone into MK-4 remains unclear thus far.
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Factors affecting the maintenance dose of warfarin
Article
  • Sep 1992
To identify the possible factors determining the dose of warfarin prescribed in patients receiving anticoagulant treatment. The computerised records of 2305 patients maintained on the drug in seven hospitals were amalgamated and classified into one of seven diagnostic groups. The associations with the dose of warfarin prescribed were investigated by univariate and multiple regression analysis. Differences between hospitals were studied with regard to the coagulometric method and the thromboplastin preparation used. The geometric mean dose of warfarin was 4.57 mg and 5% of patients were prescribed 10 mg or greater. There was a noticeable decrease in dose with increasing age, which averaged about 6 mg for patients aged 30 but 3.5 mg for those aged 80. Men required slightly more warfarin than women. Patients with heart disease or atrial fibrillation required lower doses of warfarin, while higher doses were required by patients with deep vein thrombosis. Significant differences in mean warfarin dose among the seven hospitals were evident. These differences could not be explained entirely by the use of different coagulometric methods or thromboplastins. Clinicians should be aware that older patients need reduced doses of warfarin. The considerable differences in doses of warfarin among hospitals indicates that further efforts to improve uniformity are required.
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Molecular and Cellular Biology of Blood Coagulation
Article
  • Apr 1992
This article has no abstract; the first 100 words appear below. BLOOD clotting is a host defense mechanism that, in parallel with the inflammatory and repair responses, helps protect the integrity of the vascular system after tissue injury. This system is normally quiescent but becomes active within seconds after injury. Cells (platelets, leukocytes, and endothelial cells) and the plasma blood-clotting proteins are critical in this reaction. The response to vascular injury culminates in the formation of a platelet plug, the generation of a fibrin clot, the deposition of white cells in the area of tissue injury, and the initiation of inflammation and repair. Molecular Basis of Blood Coagulation All the protein . . . Supported by grants (R37 HL38216, P01 HL42443, and R37 HL18834) from the National Institutes of Health. Source Information From the Center for Hemostasis and Thrombosis Research, Division of Hematology—Oncology, New England Medical Center, Boston, and the Departments of Medicine and Biochemistry, Tufts University School of Medicine, Boston. Address reprint requests to Dr. Bruce Furie at the Division of Hematology-Oncology, New England Medical Center, 750 Washington St., Boston, MA 02111.
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Comparative Metabolism of Phylloquinone and Menaquinone-9 in Rat Liver
Article
  • May 1992
The hepatic turnover of phylloquinone and menaquinone-9 (MK-9) and their relative efficacy in satisfying the dietary requirement for vitamin K were compared in male rats. Rats fed 1.1 mumol phylloquinone/kg diet had higher initial liver and serum vitamin K concentrations than rats fed an equimolar amount of MK-9. The initial rate of hepatic turnover of phylloquinone was two to three times as rapid as that of MK-9. After about 48 h of vitamin K restriction there were no significant differences in hepatic vitamin K concentration of rats fed phylloquinone or MK-9. Phylloquinone was much more effective than MK-9 in maintaining normal vitamin K status at low dietary concentrations (0.2 mumol/kg diet), whereas at high dietary concentrations (5.6 mumol/kg diet) they were equally effective.
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Vitamin K Metabolism and Nutriture
Article
  • Jul 1992
  • BLOOD REV
Vitamin K functions as a co-factor for the post-translational carboxylation of specific glutamate residues to gamma-carboxyglutamate (Gla) residues in several blood coagulation factors (II, VII, IX and X) and coagulation inhibitors (proteins C and S) in the liver; as well as a variety of extrahepatic proteins such as the bone protein osteocalcin. This review outlines some recent advances in our understanding of the metabolism of vitamin K and its role in human nutriture. The introduction of new methodologies to measure the low endogenous tissue concentrations of K vitamins and circulating plasma levels of des-gamma-carboxyprothrombin (PIVKA-II) have provided correspondingly more refined indices for the assessment of human vitamin K status. The assays for vitamin K have also been used to study the sources, intestinal absorption, plasma transport, storage and transplacental transfer of K vitamins and the importance of phylloquinone (vitamin K1) versus menaquinones (vitamins K2) to human needs. The ability to biochemically monitor subclinical vitamin K deficiency has reaffirmed the precarious vitamin K status of the newborn and led to an increased appreciation of the risk factors leading to haemorrhagic disease of the newborn and how this may be prevented. Biochemical studies are leading to an increased knowledge of the mode of action of traditional coumarin anticoagulants and how some unrelated compounds (e.g. antibiotics) may also antagonize vitamin K and cause bleeding. There is also an awareness of the possible deleterious effects of vitamin K antagonism or deficiency on non-hepatic Gla-proteins which may play some subtle role in calcium homeostasis.
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