Impact of Vitamin D Supplementation on Hepcidin Levels and Transfusion Requirements in Surgical and Septic Patients

Not Applicable

• Conditions: Systemic Inflammatory Response Syndrome; Surgical Injuries; Sepsis
• Interventions: Other: blood collection 3mL; Dietary Supplement: enteral supplementation with vitamin D

• Registration Number: NCT03001687
• Lead Sponsor: Iuliu Hatieganu University of Medicine and Pharmacy

Brief Summary

Acute inflammation induced by surgery and sepsis is complicated by the development of iron-restricted anemia due to the up-regulation of hepcidin. Excess hepcidin causes intracellular sequestration of iron, decreasing its availability for erythropoiesis. Hepcidin might be a potential target to reduce transfusion requirements in surgical and sepsis patients. Vitamin D supplementation might constitute a novel strategy to modulate the hepcidin-ferroportin-iron axis. Up to now, there are no data regarding the possibility that by using vitamin D supplementation in surgical and septic shock patients, the physicians could ameliorate anemia and, hence, reduce transfusion requirements. Aim: to conduct a randomised controlled trial to determine the impact of high-dose vitamin D enteral supplementation on serum hepcidin levels and transfusion requirements after major abdominal surgery and in septic shock patients.

Detailed Description

Patient blood management has become an important concept for the perioperative care of the surgical patients and in septic patients, aiming to improve outcomes. Hepcidin might be a potential target to reduce transfusion requirements after major abdominal surgery and in patients with sepsis. Major surgery and sepsis induce complex immune dysregulations, characterised by a pro-inflammatory state (the postoperative acute-phase reaction). Excess hepcidin values in acute inflammatory conditions might represent an exaggerated response that leads to iron-sequestration anemia, a functional iron deficiency anemia. Vitamin D supplementation might constitute a novel strategy to modulate the hepcidin-ferroportin-iron axis in surgery and sepsis-induced acute inflammation. Thus, vitamin D might impact hepcidin values and might reduce transfusion requirements.

I. Inflammation-induced regulation of the hepcidin-ferroportin-iron axis

Surgery and sepsis are associated with iron-restricted anemia. After major abdominal surgery and sepsis, a prototypical inflammatory syndrome, often complicated by the development of anemia, appears. Inflammatory cytokines (like interleukin 6) released during acute infection alter iron metabolism by inducing excess synthesis of hepcidin. Anemia after major abdominal surgery and sepsis may be the expression of impaired erythropoiesis as a result of hepcidin up-regulation. Hepcidin plays a role in the development of anemia, together with the inhibition of erythropoietin production, a decreased lifespan of erythrocytes, and a blunted erythropoietic response. Functional iron deficiency is increasingly recognised as a cause of anemia in the general surgical patient and in patients with sepsis.

Iron is a two-faced element. First, iron is essential for living as it is incorporated in the "breathing" molecule haemoglobin and in the mitochondrial respiratory chain. On the other hand, iron is detrimental due to the generation of oxidative stress and its availability for the growing of bacteria. Low serum iron level is considered detrimental as it leads to anemia and low tissue oxygen delivery. Iron deficiency and anemia are associated with poor outcomes in surgical and septic patients. Also, transfusion is associated with immune suppression and other adverse reactions. Thus, other approaches to the correction of anemia are advocated, even though not yet included in the clinical practice.

Hepcidin is the master regulator of iron metabolism and hence, a modulator of anemia in states of inflammation. Hepcidin is an acute phase protein synthetised in the liver and which acts as an hyposideremia inducing hormone. It binds to ferroportin (an iron exporter) and prevents the release of iron from the cells: prevents the absorption of dietary iron from enterocytes and prevents iron release from macrophages, where it is stored. Thus, the effect of hepcidin would be iron sequestration, lowering the serum iron concentrations. The beneficial result would be a low availability of iron for bacterial growth (thus, a direct antimicrobial effect) and less oxidative stress. The detrimental result is the limited possibility for the synthesis of new haemoglobin molecules and the occurrence of anemia. The up-regulation of hepcidin, as a pro-inflammatory biomarker, characterises both acute and chronic inflammatory conditions. The induction of hepcidin synthesis may be the cause for the iron-restricted erythropoiesis in the surgical population and in patients with sepsis. The induction of hepcidin synthesis may contribute to the development of anemia, which is detrimental for tissue oxygenation and might increase transfusion requirements and the aggravation of immune suppression after blood transfusion. In animal models of anemia due to inflammation, hepcidin knockout mice had milder anemia and faster recovery.

Excess values of the iron regulating hormone hepcidin causes intracellular sequestration of iron and might decrease the availability of iron for erythropoiesis, leading to the anemia frequently encountered in inflammatory conditions. Anemia is not only very frequent among critically ill patients, but is associated with increased transfusion rates and worse outcomes. Anemia may impair oxygen delivery to peripheral tissues and impose transfusion, which itself carries the risk of further immune suppression. Recent data has emphasised the need to restrict transfusions as much as possible, as transfusion is associated with increased morbidity and mortality. Instead, alternative methods to improve anemia and ameliorate tissue oxygen delivery might be beneficial.

II. Vitamin D down-regulates hepcidin expression

Vitamin D is a hormone promoting bone health, which also has a wide range of cellular activities including the differentiation of hematopoietic cells and down-regulation of inflammatory cytokines. Vitamin D has anti-inflammatory and immune-regulating properties and the maintenance of adequate vitamin D status may play a role in managing inflammation and immunity. Vitamin D supplementation in patients with chronic inflammatory conditions like chronic kidney disease improves the values of circulating markers of inflammation and immunity. Recently, it has been highlighted that in certain conditions, like chronic kidney disease, the administration of vitamin D reduces serum hepcidin values and transfusion requirements.

Up to now, there are no data regarding the possibility that by using vitamin D supplementation in surgical or septic shock patients, the physicians could target the hepcidin-ferroportin-iron axis to prevent the occurrence of anemia and, hence, reduce transfusion requirements. Oral vitamin D supplementation lowers hepcidin values and might increase erythropoiesis and decrease inflammation.

III. Vitamin D supplementation in the critically ill. Safety profile

The therapeutic potential of vitamin D is a topic of intense interest. A high prevalence of low vitamin D levels has been confirmed in patients who are critically ill. Vitamin D deficiency is associated with higher infection rates, 30-day mortality and in-hospital mortality in adult critically ill patients. During critical illness, vitamin D supplementation has a favorable safety profile and a possible mechanism of vitamin D supplementation in inducing bactericidal pleiotropic effects has been suggested. To improve vitamin D status, high-dose vitamin D is required in the critically ill, as they display a blunted response to supplementation. Recent evidence suggests that treatment of vitamin-D deficient critically ill patients may improve outcomes and mortality, possibly through enhancing innate immunity and the inhibition of proinflammatory cytokines. Further clinical trials to explore the effects of vitamin D supplementation on the up-regulation process of proinflammatory cytokines are needed.

Study Timeline

• Status Verified: 2016-12
• Study First Submitted: 2016-12-13
• Study First Submitted QC: 2016-12-20
• Study First Posted: 2016-12-23
• Study Start: 2017-01
• Last Update Submitted: 2017-02-03
• Last Update Posted: 2017-02-06
• Primary Completion: 2017-06
• Study Completion: 2017-12

Recruitment & Eligibility

• Status: UNKNOWN
• Sex: All
• Target Recruitment: 40

Inclusion Criteria

• sepsis and septic shock patients
• patients with major abdominal surgery

Exclusion Criteria

• chronic inflammatory conditions (chronic kidney disease, hematologic, and rheumatic/autoimmune disease)
• morbid obesity (BMI over 40kg/m2)
• pregnancy and lactation
• hypercalcemia (total calcium> 10.6mg/dL, serum ionized calcium>5.4mg/dL)
• tuberculosis, sarcoidosis
• nephrolithiasis
• recent history of vitamin D supplementation or erythropoietin

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
vitamin D -	blood collection 3mL	Patients in "vitamin D -" group do not receive enteral supplementation with vitamin D and represent the control group, blood collection 3mL is performed in the first 24 hours after admission and one week later for serum hepcidin measurement
vitamin D +	enteral supplementation with vitamin D	Patients in the "vitamin D" group will receive enteral supplementation with vitamin D, blood collection 3mL is performed in the first 24 hours after admission and one week later for serum hepcidin measurement
vitamin D +	blood collection 3mL	Patients in the "vitamin D" group will receive enteral supplementation with vitamin D, blood collection 3mL is performed in the first 24 hours after admission and one week later for serum hepcidin measurement

Primary Outcome Measures

Name	Time	Method
Hepcidin concentration (ng/mL)	one week after intervention	Hepcidin serum concentrations measured one week after the intervention

Secondary Outcome Measures

Name	Time	Method
Number of Packed red cells	two weeks after intervention	The number of transfused packed red cells in the first two weeks after the intervention

Trial Locations

Locations (1)

Iuliu Hatieganu University of Medicine and Pharmacy Cluj-Napoca; 🇷🇴 Cluj-napoca, Cluj, Romania