Pregnancy Clinical Trial
Official title:
Phase IV Study of Oral Administration of Bovine Lactoferrin (bLf) to Prevent and Cure Iron Deficiency (ID) and Iron Deficiency Anemia (IDA) Until Delivery in Hereditary Thrombophilia (HT) Affected Pregnant Women
The purpose of this study is to determine whether bovine lactoferrin is effective in
preventing and curing iron deficiency and iron deficiency anemia in Hereditary Thrombophilia
affected women during pregnancy.
The proposed clinical trial is considered as PHASE IV because in Italy bLf is commercialized
by Grunenthal, as Lattoglobina® (capsules with 100 mg of bLf), to prevent and cure iron
deficiency and iron deficiency anemia in pregnant women.
In industrialized and developing countries, iron deficiency (ID) and iron deficiency anemia
(IDA) are highly prevalent in pregnant women. ID and IDA, in pregnant women as a consequence
of an increased iron requirement, due to enhanced blood volume and development of
fetal-placenta unit, represent a high risk for maternal and infant health: preterm delivery,
fetal growth retardation, low birth weight, and inferior neonatal health. However, the
degree of fetal ID is not always as severe as that in mother, being iron transfer from the
mother to the fetus regulated by the placenta. In particular, the placental
syncytiotrophoblast acquires ferric iron bound to maternal transferrin at the apical
membrane through transferrin receptors (TfR-1), which noticeably increase in pregnant women
suffering of ID and IDA. Recently, it has been suggested that most iron transfer to the
fetus, occurring after the 30th week of gestation, also involves placental expression of
hepcidin and ferroportin, two proteins known to modulate systemic iron homeostasis in
adults. As matter of fact, iron homeostasis is tightly regulated through iron absorption,
storage and transport. The absorption of nearly all dietary iron (1-2 mg daily), ensuring
iron supplies in the bone marrow, at second and third trimester of pregnancy increases until
to about 4 and 8 mg/day, respectively. The iron absorption takes place in the proximal
duodenum and includes the following steps: (i) reduction of iron from the ferric state (III)
to the ferrous state (II) by a ferrireductase (duodenal cytochrome B; (ii) apical uptake by
enterocytes followed by trans-cellular trafficking via divalent metal transporter 1; (iii)
storage into ferritin; and (iv) basolateral efflux by the iron transporter ferroportin.
Ferroportin, the only known cellular iron exporter from tissues into blood, has been found
in all cell types involved in iron export, including the enterocytes, hepatocytes, placental
cells and macrophages which require ferroportin to daily recycle 20 mg of iron from lysed
erythrocytes for erythropoiesis.
Another pivotal component of systemic iron homeostasis is hepcidin, a circulating peptide
hormone synthesized by hepatocytes in iron loading conditions and secreted in plasma and
urine. Hepcidin regulates the entry of iron into plasma through ferroportin. Hepcidin, by
binding to ferroportin, causes ferroportin phosphorylation, internalization and degradation
in lysosomes, thus hindering iron export and enhancing cytosolic iron storage in ferritin.
Iron homeostasis disorders appear to arise from hepcidin and/or ferroportin dysregulation.
Similarly to the regulation of maternal systemic iron homeostasis, fetal hepcidin controls
the transfer of maternal iron across the placenta to the fetus and the enhanced
placental-fetal iron transport is related to an increased expression of ferroportin on
placental basal fetal-facing membrane, consistent with unidirectional mother-fetus iron
transport. Even if the interaction of hepcidin with ferroportin can explain the regulation
of iron homeostasis at systemic level, the influence of iron metabolism on critical stage of
fetal development, is still unknown.
Regulation of hepcidin expression seems to occur at transcriptional level and its production
is increased by iron loading and inflammation and decreased by anemia and hypoxia.
Even if the molecular mechanisms of hepcidin regulation by iron, oxygen and anemia are still
unclear, it is known that Interleukin 6 (IL-6) induces transcription of the hepcidin gene in
hepatocytes. In inflammatory and infection disorders, cytokine induced hepcidin excess,
through ferroportin binding, contributes to development of anemia of inflammation,
characterized by ID and IDA despite adequate iron stores. When iron export is hindered, iron
is stored in host cells. However, inflammation may contribute to ID and IDA by
hepcidin-independent mechanism(s) as the down-regulation of ferroportin. Independently on
hepcidin synthesis, high levels of serum IL-6 seem to down-regulate ferroportin mRNA
expression, thus sequestering iron inside cells and blocking iron flow into plasma. The
inability to export iron leads to hypoferremia, decreased pool of serum transferrin-Fe(III)
and iron-limited erythropoiesis.
The recent discovery of hepcidin-ferroportin complex has greatly contributed to clarify the
enigmatic mechanism of systemic iron homeostasis. Notwithstanding, iron homeostasis
disorders, as ID and IDA, are still treated with oral administration of large quantity of
iron as fer¬rous sulfate due to its poor bio-availability. Ferrous sulfate oral
administration often fails to exert significant effects on ID and IDA, and frequently causes
many adverse effects, including gastrointestinal discomfort, nausea, vomiting, diarrhea, and
constipation.
Recently, a significant decrease of total serum iron and serum ferritin concentrations
related with an increase of serum IL-6 concentration has been observed in pregnant women and
in hemodialysis patients, orally treated with ferrous sulfate. Therefore, it can be
hypothesized that supplemented iron was not exported from cells to circulation, but it was
accumulated inside the cells, thereby increasing inflammatory status, similarly to that
reported in animals treated with ferrous sulfate.
The weight of evidences, which let to doubt on the efficacy and safety of ferrous sulfate
oral administration, has stimulated the research of more effective approaches to prevent ID
and toxicity associated with iron overload. The treatment of ID and IDA during pregnancy
should be entirely reconsidered taking into account not only the enhanced blood volume and
development of fetal-placenta unit, but also other factors, as IL-6, which, inducing
hepcidin up-regulation and ferroportin down-regulation, can play a pivotal role in iron
homeostasis disorders.
For this purpose, lactoferrin (Lf), a cationic iron-binding glycoprotein, able to chelate at
high affinity (KD w10/20 M) two ferric ions per molecule (30), is emerging as an important
regulator of systemic iron homeostasis, able to cure ID and IDA. Lf is synthesized by
exocrine glands and neutrophils in infection and inflammation sites. In humans, free iron
does not exceed 10-18 M to avoid precipitation, microbial growth and formation of reactive
oxygen species. Lf in tissues and secretions and transferrin in blood assure that iron was
bound and scarcely available as free-ion.
Even if several functions, dependent and independent on its iron binding ability, have been
attributed to Lf, our recent clinical trials have demonstrated that this natural compound
may represent an interesting approach in the therapy for ID and IDA in pregnant women. As
matter of fact, a milk derivative bovine lactoferrin (bLf) restores the physiological
transport of iron from tissues to circulation, thus curing ID and IDA. Moreover, differently
from ferrous sulfate, bLf oral administration exerts an anti-inflammatory effect by
decreasing serum IL-6 concentration in uncomplicated pregnancies.
The hypercoagulable state represents one of the physiological changes occurring during
pregnancy. The hereditary thrombophilia (HT), a genetic predisposition to inappropriately
form clots, significantly increases adverse outcomes including recurrent miscarriages,
intrauterine fetal death and growth retardation, preeclampsia and placental abruption. It is
well known that inflammation promotes coagulation and IL−6 high levels in plasma of HT
affecting pregnant women with severe preeclampsia have been found. Moreover, elevated
intra−amniotic IL−6 and IL−8 levels have been correlated to preterm birth.
Therefore, iron supplementation via oral administration of ferrous sulfate increasing serum
IL-6 levels in uncomplicated pregnancies, could be deleterious in HT affecting pregnant
women and could contribute to enhance iron overload in tissues, inflammation and cell
damages.
The bLf capability to prevent and cure ID and IDA together with its ability of decreasing
serum IL-6 concentration could be effective even in the treatment of ID and IDA in pregnant
women affected by HT.
In this clinical trial, pregnant women affected by hereditary thrombophilia (HT), suffering
of ID and IDA, receive an oral administration of bovine Lf (bLf) 100 mg/twice a day or
ferrous sulfate 520 mg/day. The number of red blood cells, the values of hemoglobin, total
serum iron, serum ferritin, haematocrit, serum Interleukin-6 (IL-6) and prohepcidin are
assayed before therapy, every 30 days until delivery.
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Allocation: Non-Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Treatment
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