Massey Documents by Type

Permanent URI for this communityhttps://mro.massey.ac.nz/handle/10179/294

Browse

Filters

20132

Settings

Has files: YesSubject: search.filters.subject.Iron deficiency

Search Results

Now showing 1 - 2 of 2
  • Thumbnail Image
    Item
    Iron status of preterm infants after hospital discharge : a thesis presented in partial fulfilment of the requirements for the degree of Masters in Science in Nutrition and Dietetics at Massey University, Albany, New Zealand
    (Massey University, 2013) Moor, Charlotte Felicity
    Background: Preterm infants are at an increased risk of developing iron deficiency (defined in paeditaric populations as a ferritin value <12 μg/L or a serum transferrin receptor concentration >2.4 mg/L) after discharge due to their shortened gestational length, increased requirements for rapid growth, and excessive blood losses through phlebotomy. Optimising preterm infant iron status after discharge is important as poor iron status has been associated with negative health and neurodevelopmental outcomes later in life. Only preterm infants born before 32 weeks gestation or with a birth weight less than 1800 g currently receive routine iron supplementation after discharge from Auckland City Hospital; however there is paucity of evidence to determine whether this is best practice. Objective: To investigate the iron status of preterm infants in Auckland, New Zealand at four months after discharge from hospital. Methods: Sixty one preterm infants were recruited through Auckland City Hospital. At four months after discharge infant haemoglobin, serum ferritin and soluble transferrin receptor (sTfR) concentrations were measured to assess iron status. Weight, length and head circumference were also measured. Information about iron supplementation and mode of feeding was collected using an online questionnaire. Statistical analysis using independent t-tests, Mann-Whitney tests and bivariate correlations were performed. Results: 16.4% of preterm infants had iron deficiency anaemia (defined in paediatric populations as a haemoglobin less than 110 g/L in conjunction with low iron stores) at four months after discharge, with an additional 6.6% of preterm infants classified as having iron deficiency. No infant had iron overload. Iron supplementation was associated with significantly higher haemoglobin (P<0.001) and serum ferritin (P<0.001) concentrations along with lower sTfR concentrations (P=0.005) at four months after discharge. Iron supplementation was also protective against suboptimal iron status at four months after discharge (P=0.018). Mode of feeding, introduction of solids, intrauterine growth restriction, and maternal iron status had no effect on infant iron status at four months after discharge. There was also no relationship between growth and iron supplementation or iron status at four months after discharge. Conclusion: Preterm infants who did not receive iron supplements after discharge had an increased risk of developing iron deficiency and iron deficiency anaemia at four months after discharge. Routine iron supplementation for all preterm infants combined with screening for iron deficiency anaemia after discharge appears to be a safe and effective way to reduce the risk of iron deficiency and iron deficiency anaemia at four months after discharge.
  • Thumbnail Image
    Item
    Iron deficiency in young women : causes, consequences and solutions : a thesis presented in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Nutritional Science at Massey University, Albany, New Zealand
    (Massey University, 2013) Beck, Kathryn Louise
    Background: Iron deficiency is the most common nutritional deficiency worldwide and premenopausal women are at particular risk. Iron deficiency without anaemia is associated with a number of health consequences, including impaired work performance and possible impairments to self-perceived health and well-being, and increased fatigue. Research into iron deficiency and possible causes, consequences and solutions could help to improve the quality of life for many premenopausal women. Objectives: This research aimed to investigate the causes, some of the consequences and a possible solution to iron deficiency in premenopausal women. Objectives were to determine the relative validity and reproducibility of an iron food frequency questionnaire (FeFFQ) developed to identify iron-related dietary patterns; to identify the most important determinants of suboptimal iron status and investigate the relative importance of dietary patterns among these determinants; to determine the relationship between iron status and self-perceived health, well-being and fatigue; and to investigate the effectiveness of a dietary intervention using an iron-fortified breakfast cereal and milk consumed with either high or low ascorbic acid, lutein and zeaxanthin-rich fruit to improve iron status in women with low iron stores. Method: In a validation study, premenopausal women (n=115) completed the FeFFQ twice, one month apart to assess reproducibility and a four-day weighed diet record (4DDR) to assess validity. Dietary patterns from both FeFFQs and the 4DDR were identified using factor analysis and agreement between diet pattern scores were compared using correlation coefficients, Bland and Altman analysis, cross-classification and the weighted κ- statistic. In a cross-sectional study, 375 premenopausal women completed the FeFFQ (from which dietary patterns were identified) and a dietary practices questionnaire. They also completed a health and demographic questionnaire including questions regarding possible determinants of iron status, as well as a validated blood loss questionnaire. In a second cross-sectional study, 233 female university students completed the SF-36v2 General Health Survey and Multidimensional Fatigue Symptom Inventory-Short Form (MFSI-SF) questionnaire to investigate self-perceived health, well-being and fatigue. In both cross-sectional studies, a blood sample was taken to determine iron status (serum ferritin (SF), haemoglobin (Hb), C-reactive protein (CRP)). In a randomised controlled trial (RCT), 69 women with low iron stores (SF≤25μg/L, Hb≥115g/L) received an iron-fortified breakfast cereal (16 mg iron as ferrous sulphate) meal and either kiwifruit (intervention) or banana (control) every day for 16 weeks. Iron status (SF, Hb, CRP, and soluble transferrin receptor) was assessed at baseline and end. Results: Two dietary patterns (‘healthy’; ‘sandwich & drinks’) were identified from the FeFFQs and 4DDR. Correlation coefficients between the FeFFQ and 4DDR diet pattern scores (validity) were 0.34 (‘healthy’), and 0.62 (‘sandwich & drinks’), both P<0.001. Correlation coefficients between the two FeFFQs (reproducibility) were 0.76 for both dietary patterns (P<0.001). Determinants of suboptimal iron status (SF<20μg/L) included blood donation in the past year (odds ratio (OR) 6.7, [95% confidence interval (CI) 3.1, 14.7]; P<0.001), being Asian (5.2 [2.4, 11.2]; P<0.001), having children (2.7 [1.4, 5.3]; P=0.003), previous iron deficiency (2.1 [1.1, 3.9]; P=0.027), longer duration of menstrual period (1.3 [1.1, 1.6]; P=0.01), and following either a ‘milk & yoghurt’ (1.4 [1.1, 1.9]; P=0.014), or a ‘meat & vegetable’ (0.6 [0.4, 0.8]; P=0.002) dietary pattern. Current iron status was not a determinant of self-perceived health, well-being or fatigue after controlling for other variables. In the RCT, iron status improved significantly (P<0.001) in the kiwifruit group (SF from baseline to end (median [25th, 75th percentile]) (17.0 [10.5, 22.0]μg/L to 25.0 [20.0, 32.0]μg/L; P<0.001)) compared to the banana group (16.5 [10.0, 20.8]μg/L to 17.5 [12.3, 22.8)]μg/L; P=0.086). Conclusions: The FeFFQ was found to be a reproducible and reasonably valid tool for identifying ironrelated dietary patterns. Following a ‘meat & vegetable’ dietary pattern reduced the risk, while following a ‘milk & yoghurt’ dietary pattern increased the risk of suboptimal iron status. The strongest predictors of suboptimal iron status were blood donation and Asian ethnicity, followed by parity and previous iron deficiency. Both dietary patterns were stronger predictors of suboptimal iron status than duration of menstrual period. Iron status had no effect on self-perceived health, well-being or fatigue. Consumption of an ironfortified breakfast cereal with kiwifruit compared to banana improved iron status in women with low iron stores. Modification of dietary patterns and blood donation practices, as well as the consumption of an iron-fortified breakfast cereal with an ascorbic acid, lutein, zeaxanthin-rich fruit may contribute to improved iron status in women with low iron stores.