Abstract
Objective
Unexpectedly high serum B12 concentrations were noted in most study subjects with cystic fibrosis (CF) and pancreatic insufficiency (PI) participating in a nutrition intervention at the baseline evaluation. The objectives of this study were to determine dietary, supplement-based and enzyme-based B12 intake, serum B12 concentrations, and predictors of vitamin B12 status in children with CF and PI.
Study Design
Serum B12 status was assessed in subjects (5-18 yrs) and categorized as elevated (Hi-B12) or within reference range (RR-B12) for age and sex. Serum homocysteine, plasma B6, red blood cell folate, height, weight, and body mass index Z scores, pulmonary function, energy, dietary and supplement-based vitamin intake were assessed.
Results
106 subjects, mean age 10.4 ± 3.0 years participated. Median serum B12 was 1083 pg/ml, with 56% in the Hi-B12 group. Dietary and supplement-based B12 intake were both high representing 376% and 667% Recommended Dietary Allowance (RDA). The Hi-B12 group had significantly greater supplement-based B12 intake than the RR-B12 group (1000 vs. 583% RDA, p<0.001). By multiple logistic regression analysis, high supplement-based B12 intake and age >12 years increased risk for Hi-B12, while higher FEV1 decreased risk (Pseudo-R2=0.18, P<0.001).
Conclusions
Serum B12 was elevated in the majority of children with CF and PI. Supplement-based B12 intake was 6 to 10 times the RDA, and strongly predicted elevated serum B12 status. The health consequences of lifelong high supplement-based B12 intake and high serum B12 are unknown and require further study, as does the inversed correlation between serum B12 and FEV1.
Keywords: Supplement-based vitamin intake; cobalamin; B12, B6, folate, cyanide
INTRODUCTION
While fat soluble vitamin status is frequently described in patients with cystic fibrosis (CF) and pancreatic insufficiency (PI), less is known regarding B vitamins. Vitamin B12 (cobalamin) metabolism is a complex process that begins in the oropharynx and is completed in the terminal ileum1. This process requires an intact gastrointestinal tract, acidification of gastric contents, pancreatic function for alkalinization of duodenal fluid and the provision of trypsin to degrade the R-binder protein and allow B12 to bind to intrinsic factor (IF). The IF-B12 complex is actively absorbed at the terminal ileum1. There are possible CF and PI- related perturbations in B12 metabolism, specifically impaired trypsin and bicarbonate production2, 3. Approximately 85% of the CF population has PI4 and are at risk for malabsorption. Pancreatic enzyme replacement therapy (PERT) partially corrects B12 malabsorption and improves B12 concentrations5-7 .
Unexpectedly high serum B12 concentrations were noted in most of the study subjects participating in a nutrition intervention trial in children with CF and PI. The objectives of this current report were to determine dietary, vitamin supplement-based and pancreatic enzyme-based B12 intake, serum B12 concentrations, and predictors of vitamin B12 status in children with CF and PI, to try to identify etiology of elevated serum B12.
METHODS
Children with CF and PI ages 5.0 to 17.9 were recruited from ten CF Centers from March 2007 to May 2010 to participate in a randomized placebo-controlled double-blind longitudinal trial to evaluate the impact of a nutritional supplement, LYM-X-SORB™, on nutritional and growth status. LYM-X-SORB™ is an lipid matrix is composed of lysophosphatidyl choline, triglycerides and essential fatty acids that has been previously been shown to be absorbable without pancreatic enzyme therapy (PERT) and to improve nutritional status and clinical outcomes for children with CF and PI8. Vitamin B12, B6 (pyridoxine) and folate status were assessed as part of this larger study due to their role as co-factors in the phospholipid and 1-methyl donor metabolism. Here we report on these B vitamins at the baseline pre-intervention visit. The diagnoses of CF and PI were made by the home CF Center based on clinical symptoms, and duplicate quantitative pilocarpine iontophoresis sweat test and/or by genotype. In all study subjects PI was confirmed by fecal elastase testing (Genova Diagnostics, Asheville, NC), with < 15μg/g stool required for enrollment. Children were excluded if they had an FEV1 <40% predicted, significant liver disease, history of meconium ileus with significant ileal resection or known current ileal disease, insulin dependent diabetes, or other conditions known to affect growth. The study protocol was approved by the Committee for the Protection of Human Subjects of the Institutional Review Board at the Children’s Hospital of Philadelphia (CHOP), and at the subject’s home institution. Written informed consent and age-appropriate assent were obtained from the parent/legal guardian and each subject, respectively. Subjects with CF were seen at the CHOP Clinical Translational Research Center (CTRC) for overnight admissions while in their usual state of good health. Evaluations included measures of growth and nutritional status, serum vitamin status and other biomarkers, clinical status, spirometry, medication use (including pancreatic enzyme replacement therapy, acid reduction agents as well as antibiotics), dietary and supplemental vitamin intake.
Energy and Nutritional Intake
Dietary intake was assessed with 3-day home-based weighed food records. Subjects and parents/guardians were provided with measuring cups, spoons, and digital food scales after they were given detailed verbal instructions to weigh and record each food/beverage consumed. Diet records were reviewed and analyzed (Nutrition Data System for Research, National Coordinating Center, University of Minnesota, Minneapolis, MN)9. Energy intake was assessed using the Dietary Reference Intakes (DRI)10, and expressed as percent Estimated Energy Requirement (%EER) for active children, as previously determined for children with CF and PI11. Dietary intake of B12, B6, and folate are expressed as percent Recommended Dietary Allowance (%RDA)12,13.
Vitamin Intake
Details of the specific brands of vitamin, mineral and caloric supplemental intake, frequency and dose were recorded from study participant report. The supplement-based vitamin product content was verified from the manufacturers’ information. Supplemental intakes for vitamins B12, B6 and folic acid were expressed as both intake in μg/d or mg/d and as %RDA12, 13. PERT use, including brand, number of capsules and lipase units taken per day were determined by study participant report. The vitamin B12 content of selected PERT products, including Pancreaze™ (11,500 lipase units/capsule; Janssen Pharmaceuticals), Creon™ (11,500 lipase units/capsule; Abbott Laboratories), and Zenpep™ (10,000 lipase units/capsule; Aptalis Pharma) were determined as μg/100g product by the turbidimetric method (Eurofins, Inc, Des Moines, IA).
Vitamin B Status and Biochemistry
Fasting blood samples were collected at baseline and serum vitamin B12 was analyzed by quantitative chemoluminescent immunoassay (CHOP Clinical Laboratory, Philadelphia, PA). Plasma B6 (pyridoxine-5-phosphate) was determined by high performance liquid chromatography (ARUP Laboratory, Salt Lake City, UT). Whole blood was collected for red blood cell folate concentrations by chemoluminescence (ARUP Laboratory, Salt Lake City, UT) and reported correcting for the hematocrit. For serum B12, subjects were designated as having elevated B12 (Hi- B12) if their B12 concentrations were above versus within the established age- and sex-specific clinical laboratory reference ranges (RR-B12)14, 15. Supplement-based B12 in CF specific and in over the counter vitamin products was in the form of cyanocobalamin (i.e., complexed to cyanide). When it became evident that specifically supplement- based B12 intake was very high, whole blood cyanide concentrations were determined by quantitative colorimetry on a limited subset of study subjects (ARUP Laboratory, Salt Lake City, UT) at the 12 month study visit. Potential cyanide toxicity is associated with blood concentrations > 100 μg/dL16. CBC with differential, hepatic function panels, and comprehensive metabolic panels were assessed by standard methods; homocysteine, methionine and cysteine were assessed by high performance liquid chromatography (CHOP Clinical Laboratory). High sensitivity C-reactive protein (hsCRP) was assessed by quantitative immunoturbidimetry (ARUP Laboratories, Salt Lake City, UT).
Body Composition, Growth and Clinical Status
Height and weight were measured using standard techniques17 with a stadiometer accurate to 0.1 cm (Holtain, Crymych, UK), and a digital electronic scale accurate to 0.1 kg (Scaletronix, White Plains, NY). Height was adjusted for genetic potential18 from measured or reported biological parent heights. Z scores for height (HAZ), mid-parent adjusted height (adjHAZ), weight (WAZ), and body mass index (BMI; kg/m2, BMIZ) were computed19. Pulmonary function was evaluated by standard methods20 by spirometry (Medical Graphics Corporation, Minneapolis, MN). FEV1 percent predicted (FEV1%) was calculated using Wang21 and Hankinson22 equations recommended for use in children and adolescents with CF and used as the measure of pulmonary function.
Statistical Methods
Measures of central tendency and variability were calculated for each outcome. Descriptive statistics were calculated for continuous variables using means and standard deviations or medians and ranges as appropriate for normally distributed or skewed data. Frequency distributions were used for categorical variables. Significant differences between Hi-B12 versus RR-B12 groups were assessed for continuous variables using unpaired student’s t tests for normally distributed and Mann-Whitney tests for skewed data, and for categorical variables using chi-squared tests. Four categories for B12 supplemental intake were constructed representing low to high B12 supplemental intake as %RDA (Category 1=0-499, 2=500-999, 3=100-1499, and 4= ≥1500 %RDA). Children were also divided into younger (≤12 yrs) and older (>12 yrs) groups. Potential predictors of elevated B12 status were identified as age group, sex, genotype, BMIZ, FEV1 % predicted, serum B6 and B12 supplemental intake categories (%RDA). These potential predictors were then tested as both individual predictors in logistic models and also using multiple logistic regression analyses, with Hi-B12 vs. RR-B12 serum status as the dichotomous outcome. Best predictor multiple logistic models for B12 status included only those variables that entered the model at p<0.10 level of significance. All statistical analyses were performed using STATA 12.0 (College Station, TX), and results were considered significant at p<0.05.
RESULTS
Serum B12 was assessed for 106 of the 110 subjects (96%) enrolled in the study; median B12 was 1083 pg/ml, and 56% and 44% of the subjects had Hi-B12 and RR-B12, respectively. There were no children with serum B12 below the age- and sex-specific reference ranges. Baseline demographic, growth and clinical status are presented in Table 1.Serum vitamin status, dietary and supplemental intake for energy, B12, B6 and folic acid are presented in Table 2 for the entire sample and for subjects in the Hi- B12 and RR-B12 groups. Overall, children were 10.4±3.0 years of age, 72% were <12 yrs and 57% were male. CF genotype was available for 104 subjects, with 59% classified as ΔF508 homozygous, 34% heterozygous (ΔF508/other) and 7% subjects with other CF genotypes. Growth status was suboptimal in these children with mild lung disease. In contrast to serum B12 status, serum B6 and RBC folate concentrations were within age-and sex-specific reference ranges for the majority of the sample (85% and 94%, respectively). No children were below reference ranges for B6 and 4% were below for RBC folate concentrations. With respect to hepatic enzyme assessments, AST was mildly above reference range in 28%, ALT in 43%, and GGT in 34% of subjects, and were not associated with B12 status. Dietary and supplemental intake of energy and the B vitamins are also presented in Table 2 for 95 children who completed the 3-day weighed food. Overall, energy intake was higher in subjects with CF (115% EER) than the estimated requirement for healthy active children. Dietary and vitamin supplement-based B12 intake were both high representing 376% and 667% RDA, respectively. Total intake of B12 was 18.4 μg/d, corresponding to 1175 %RDA, or nearly 12 times the recommended intake, primarily due to the high CF specific vitamin supplemental B12 intake. B6 intake was high, 5 to 6 times the RDA, with majority from vitamin supplement-based intake. Folic acid intake was 2 to 3 times the RDA, and was evenly distributed between dietary and vitamin supplement-based intake.
Table 1. Characteristics of Children with CF and PI by B12 Status Groups.
Serum B12 Groups |
||||
---|---|---|---|---|
All | Hi-B12 | RR-B12 | P-value1 | |
Number | 106 | 59 | 47 | |
Age, yr | 10.4 ± 3.0 | 11.0 ± 3.3 | 9.6 ± 2.6 | 0.02 |
Age > 12y, % | 28 | 39 | 15 | 0.01 |
Sex, % male | 57 | 51 | 64 | 0.18 |
WAZ | −0.38 ± 0.78 | −0.48 ± 0.68 | −0.24 ± 0.89 | 0.11 |
HAZ | −0.39 ± 0.92 | −0.44 ±0.97 | −0.32 ± 0.86 | 0.51 |
Adj HAZ 2 | −0.68 ± 0.89 | −0.73 ± 0.92 | −0.61 ± 0.85 | 0.49 |
BMIZ | −0.19 ± 0.77 | −0.32 ± 0.68 | −0.03 ± 0.85 | 0.05 |
FEV1, % predicted 2 | 96 ± 23 | 90 ± 23 | 103 ± 20 | 0.005 |
HAZ, height-for-age Z score; adjHAZ, height-for age Z score adjusted for mid-parental height; WAZ, weight-for-age Z score; BMIZ, body mass index-for-age Z score;
Means ± SD and t-tests for normally distributed variables.
n=103 (n=58 for Hi-B12, n=45 for RR - B12).
Table 2. Blood Biomarkers and Dietary Intake by B12 Status Group.
Serum B12 Groups |
||||
---|---|---|---|---|
All | Hi-B12 | RR-B12 | P-value1 | |
Blood Biomarker | ||||
B12, pg/mLA | 1083 (371, 3455) | 1414 (823, 3455) | 853 (371, 1284) | <0.001 |
B6, ng/mL2,A | 16.9 (5.0, 91.7) | 17.6 (5.0, 91.7) | 15.4 (5.4, 39.4) | 0.05 |
RBC folate, ng/mL3,A | 496 (231, 1045) | 509 (231, 857) | 488 (278, 1045) | 0.95 |
Homocysteine, μmol/LA | 4.8 (2.2, 9.0) | 4.7 (2.2, 8.9) | 5.1 (2.8, 9.0) | 0.01 |
Methionine, nmol/mLA | 24.9 (11.1, 65.7) | 23.5 (16.1, 65.7) | 25.9 (11.1, 56.3) | 0.46 |
Cysteine, nmol/mL | 43.7 (12.4, 79.0) | 46.5 (12.4, 66.3) | 41.4 (28, 79) | 0.01 |
hsCRP, mg/L 4 | 0.4 (0.1, 48.4) | 0.4 (0.1, 48.4) | 0.4 (0.1, 5.5) | 0.61 |
WBC, thou/μL 4 | 7.1 (4.1, 17.8) | 7.7 (4.5, 17.8) | 6.9 (4.1, 16.7) | 0.24 |
Dietary Intake | ||||
Number | 95 | 54 | 41 | |
Energy, kcal | 2325 (865, 4909) | 2359 (865, 4909) | 2320 (1413, 4014) | 0.94 |
%EER | 115 (41, 228) | 114 (41, 223) | 117 (64, 228) | 0.49 |
Total B12, μg | 18.4 (5.5,158.9) | 21.9 (8.0, 158.9) | 15.1 (5.3, 33.3) | <0.001 |
Total B12, %RDA | 1175 (310, 8826) | 1391 (479, 8826) | 1000 (310, 1872) | <0.001 |
Diet , μg | 6.0 (1.5, 18.1) | 6.4 (2.6, 18.1) | 5.6 (1.5, 14.0) | 0.17 |
Diet, %RDA | 376 (79, 1085) | 379 (79, 1085) | 373 (83, 780) | 0.80 |
Supplement, %RDA | 667 ( 0, 8333) | 1000 (250, 8333) | 583 (0,1375) | <0.001 |
0 - 499 %RDA | 15 | 11 | 20 | |
500 - 999 %RDA | 47 | 35 | 63 | |
1000 - 1499 RDA | 29 | 39 | 17 | |
1500+ %RDA | 8 | 15 | 0 | 0.002 |
Total B6, mg | 4.6 (1.9, 78.2) | 5.5 (1.9, 78.3) | 3.9 (2.4, 8.3) | <0.001 |
Total B6, %RDA | 545 (243, 7827) | 591 (243, 7827) | 502 (247, 1131) | 0.01 |
Diet, mg | 1.9 (0.5, 8.8) | 1.9 (0.7, 8.8) | 1.8 (0.5, 5.6) | 0.13 |
Diet, %RDA | 217 (51, 931) | 219 (59, 881) | 214 (51, 931) | 0.50 |
Supplement, mg/d | 2.3 (0.0, 75.0) | 3.0 (0.6, 75.0) | 1.9 (0.0, 4.0) | 0.01 |
Supplement, %RDA | 317 (0, 7500) | 317 (105, 7500) | 300 (0, 425) | 0.09 |
Total Folate, μg | 755 (335, 1872) | 933 (376, 1872) | 616 (335, 1518) | <0.001 |
Total Folate, %RDA | 281 (113, 840) | 332 (128, 840) | 227 (113, 506) | 0.003 |
Diet, μg | 413 (140, 1472) | 451 (156, 1473) | 385 (140, 1251) | 0.03 |
Diet, %RDA | 159 (39, 491) | 167 (39, 491) | 143 (47, 417) | 0.14 |
Supplement, μg | 400 (0, 1200) | 400 (66, 1200) | 200 (0, 800) | 0.004 |
Supplement, %RDA | 100 (0, 400) | 133 (33, 400) | 100 (0, 267) | 0.02 |
hsCRP = high sensitivity C-reactive protein (<3 mg/L normal); WBC, white blood cell count; %EER, percent Estimated Energy Requirement; RDA = Recommended Dietary Allowance
Means ± SD and t-tests for normally distributed variables; median (range) and Mann-Whitney for non-normally distributed variables.
n=103 (n=58 for Hi-B12, n=45 for RR - B12).
n=97(n=54 for Hi-B12, n=43 for RR - B12).
n=102 (n=57 for Hi-B12, n=45 for RR - B12).
Biomarker Reference Ranges: B12, pg/mL: Males: 4-6.9 years: 245-1078; 7-9.9 years 271-1170; 10-12.9 years 183-1088; 13-18 years 214-865; >18 year old 199-732. Females: 4-6.9 years 313-1407; 7-9.9 years 247-1174; 10-12.9 years 197-1019; 13-18 years 182-820; >18 year old 199-732. (CHOP Clinical Laboratory, Philadelphia, PA). B6, ng/mL: 5-30 (ARUP Laboratories, Salt Lake City, UT). Folate, ng/mL: 280-903 ng/mL (ARUP Laboratories, Salt Lake City, UT). Homocysteine , μmol/L: 6-10.9 years: 0.8-6.5. 11-16.9 years 5.7-11.7. >17 years 10.5-16.7 (ARUP Laboratories, Salt Lake City, UT). Methionine, nmol/mL: 8-49 nmol/mL (ARUP Laboratories, Salt Lake City, UT).
PERT (porcine pancreatic extract) also contributed to B12 intake. Subjects reported a median intake of 18 PERT capsules per day (range 9 to 42), representing a median of 270,000 lipase units per day. There are between 10 and 15 μg B12 in every 100 g of enzymes. One PERT capsule contains approximately 0.2 g of enzyme, depending upon the specific product. Therefore 18 capsules per day contain ~3.6 g enzymes, or 0.36 to 0.54 μg B12, contributing another ~20 to 30% RDA for a typical 9 year old child with CF and PI. The contribution of B12 from PERT was not included in the total B12 intake calculations for this report. Acid reduction medications (Histamine H2 receptor antagonists and/or proton pump inhibitors) were used by 65% of study subjects. Inhaled tobramycin was used by 29% of study subjects, and oral antibiotics by 36% of study subjects. Both inhaled and oral antibiotics were used by 49% of study subjects. There were no differences in acid reduction medication, inhaled, oral or total antibiotic use between B12 status groups.
Children in the Hi-B12 group were significantly older, had poorer BMIZ and lung function than those with RR-B12 (Table 1). Homocysteine was lower and cysteine was higher in Hi-B12 group, and methionine did not differ by group. Total intake of B12 was significantly higher in the Hi-B12 compared to RR-B12 group, 13 versus 10 times higher than the RDA, respectively. This was driven by the increased supplement-based B12 intake (10 times the RDA in the Hi-B12 group versus 6 times the RDA in the RR-B12 group). Furthermore, there were no group differences in ietary B12 intake between B12 status groups. Study subjects with Hi-B12 were significantly more likely to be taking > 1000 %RDA supplemental B12 than those with RR-B12. Supplemental intakes of both B6 and folic acid were also significantly higher in the Hi- B12 group. B12 groups did not differ by sex, genotype or PERT use (data not shown).
Significant predictors of B12 status were tested using multiple logistic regression analysis and the best model is shown in Table 3. From the multiple logistic regression model, higher supplemental B12 intake and older age significantly increased risk for Hi-B12 status, while higher FEV1% predicted reduced risk, with these predictors combined explaining 18% of the variance in serum B12 status (P<0.001). Compared to subjects receiving <500 %RDA of supplemental B12, there is a 2.3 fold increased risk for Hi-B12 for subjects for every additional 500 %RDA, reaching a 6.9 fold increase for those receiving ≥1500 %RDA B12 from supplement-based B12 intake. BMIZ was inversely associated with B12 status in the simple model, but was no longer significant in the multivariable model. Other potential predictors were tested (for example, the use of acid reduction medications and antibiotic use) and did not add significantly to the model.
Table 3. Multiple Logistic Regression Model Predicting High Serum B12 Status Group.
Hi-B12 Status Group | ||||||
---|---|---|---|---|---|---|
| ||||||
n=103 | Odds ratio |
SE | Z | P | 95% CI | Pseudo-R2 |
<0.001 | 0.18 | |||||
B12 supplement intake group, %RDA1 | 2.26 | 0.67 | 2.78 | 0.005 | 1.27-4.03 | |
Age, > 12 years | 3.38 | 1.85 | 2.23 | 0.026 | 1.16-9.87 | |
Sex, female | 2.34 | 1.11 | 1.80 | 0.072 | 0.93-5.93 | |
FEV1, % predicted | 0.98 | 0.01 | −2.18 | 0.029 | 0.96-0.99 | |
Constant | 0.30 | 0.47 | −0.77 | 0.441 | 0.01-6.55 |
B12 supplementation intake categories, %RDA: category 1 = 0-499; category 2 = 500-999; category 3 = 1000-1499; category 4 = ≥1500
For the assessment of possible cyanide-related toxicity with sustained high cyanocobalamin supplement intake, whole blood cyanide was analyzed in seven subjects. Cyanide was below detectible concentrations (< 5μg/dL) for six subjects, and 8 μg/dL in one subject.
DISCUSSION
Serum B12 concentrations were greater than the age and sex reference ranges for more than half of the subjects, and was mostly driven by supplement-based B12 intake. Total B12, B6, and folic acid intakes were generally greater in subjects with CF than those observed in children of similar age and sex from the general population23. These high B12 intake and serum values were unexpected in this population of patients.
In healthy individuals approximately 50% B12 intake is absorbed, with approximately 98% by active transport at the terminal ileum and 2% via passive intestinal diffusion. Absorbed B12 is bound to transcobalamin (TC) II in the circulation and at the tissue level, and to TC-I in the serum and in the enterohepatic circulation1. Perturbations in B12 digestion and absorption have been reported in CF, including altered glycosylation of intrinsic factor (IF)2, hyperacidity, IF hypersecretion24, and loss of pancreatic function (poor duodenal alkalinization and protease insufficiency with incomplete R binder degradation)2. Patients with meconium resections may have impaired B12 absorption and enterohepatic circulation25. However, despite these potential perturbations in B12 digestion and absorption, alkalinization of the duodenal fluid5, and providing PERT 5 or trypsin26, normalized B12 absorption in subjects with CF and PI. B12 concentrations measured after pancreatin treatment (pancreatic extract predecessor to modern PERT) in subjects with CF and PI were normal or elevated27. Early studies documented abnormal absorption of crystalline B12 and impaired Schilling’s tests. With modern PERT and B12 intake from food and B12 as cobalamin rather than the crystalline form, B12 metabolism is likely similar to healthy children and younger adults. B12 deficiency has not been described in the CF literature since 19736. It is unclear if B12 supplementation is required in patients with CF and PI under current standards of care.
In the current report, we determined B12 intake from the diet and from vitamin supplements to understand the contributions of sources to intake and serum concentrations. Dietary intake of B12 were similar to that reported in healthy children, and both had dietary intake of about three times the RDA23. CF specific vitamins contain approximately the B12 dose found in multivitamins designed for older adults who have increased risk of B12 deficiency and pernicious anemia. In addition to B12 in the diet and vitamin supplements, PERT products contain B12. There was a relationship of age with serum B12, and CF vitamin supplement-based intake increases with age. Often between 8 and 12 years of age, the vitamin pill intake is increased from one CF specific vitamin per day to two per day in order to increase the fat soluble vitamin intake28. The amount of B12 and other vitamins in the product also increases. Age associations are observed with other clinical and nutritional outcomes in CF, specifically, negative associations with FEV1% and BMIZ4. In part this age-based intake multivitamin intake increase may contribute to the inverse relationship of both FEV1 and BMIZ with serum B12 observed in this cohort.
The finding that B12 concentrations were inversely related to homocysteine concentrations likely reflects the 1-methyl metabolic pathway (homocysteine is converted to methionine) or to the transulfuration pathway (homocysteine is converted to cysteine). Homocysteine and methylmalonic acid are used for diagnosing subclinical B12 deficiency29, 30.
Serum B12 may be elevated with inflammation and was postulated as a possible etiology for elevated concentrations in subjects with CF in early studies27. Elevated serum B12 was noted in subjects with CF and was associated with both elevated serum transcobalamin II and normal unsaturated B12 binding capacity. These investigators postulated the findings were related to hepatic dysfunction, recurrent pulmonary infection or increased turnover of myeloid cells. Elevated B12 levels can occur in chronic myelogenous (leukemic) conditions, renal failure and liver disease. We evaluated blood markers for inflammation, renal function, hepatic function and complete blood counts with differentials. High sensitivity-CRP concentration and white blood cell count (WBC) did not differ between B12 status groups. There were no subjects with a myeloproliferative disorder or renal disease. Liver enzymes were mildly elevated as expected in a group of subjects with CF and PI and were not associated with B12 status. There were no associations with hemoglobin, hematocrit, platelet count, liver enzymes, total protein, albumin, BUN or creatinine with serum B12 (data not shown). In this study there was no indication that serum B12 was acting as an acute phase reactant, or that it was related to other diagnoses.
The consequences of lifelong high dose supplement-based B12 and sustained elevated serum concentrations are unknown. In the non-CF medical setting, elevated serum B12 is an indication for a diagnostic work up to rule out serious disease16, 31. Our data demonstrate that with current CF care, patients take CF-specific vitamins containing high doses of B12 and many patients will likely have elevated serum B12. Thus, the elevated B12 cannot serve as a sign of potential serious disease. Supplement-based B12 is in the form of cobalamin (cyanocobalamin). Cyanide is released intracellularly and is rapidly cleared and cyanide toxicity is not expected. While elevated pulmonary secretion cyanide levels have been reported in CF, these likely result from Pseudomonas and Burkholderia secretions32. In the current study, only one of seven subjects had a detectable cyanide level, and this was within the laboratory reference range. From these limited data, the risk of systemic cyanide exposure is likely low.
Of interest, FEV1 differed between B12 status groups and persisted in the multiple logistic regression models after adjusting for age. In CF, FEV1 declines with age; B12 dose increases with age, and the upper limit of serum B12 reference range declines with age. Other factors that may be related to the inversed relationship between B12 and FEV1 include the observation that sicker patients may take more medication including supplements (more prescriptions and/or better adherence to prescribed treatment). Further study is required to better understand mechanisms and clinical significance of the B12 and FEV1 inversed correlation.
It is unclear if there are clinical benefits of B12 intake beyond that to sustain a normal B12 status. Scambi et al33 reported improvements in phospholipid docosahexaenoic acid (DHA) status in young children with CF with daily 5-methyltetrahydrofolate (7.5 mg) and B12 (0.5 mg) supplementation in a 24 week intervention. The phospholipid DHA improvement was thought to be a result of the interaction of folate, B12, phospholipid DHA and 1-methyl metabolic pathway33. The intakes of B12 and B6 were orders of magnitude greater than recommended for healthy people. There are currently no specific CF-specific B-vitamin intake recommendations different than those for the general population. There is no known toxicity of vitamin B1212,13. Chronic supplement based B6 intake >1000 μg/d may increase the risk for peripheral neuropathy13. An adverse effect of high folic acid intake has the potential to mask co-incident B12 deficiency and associated pernicious anemia and progressive neurological damage13. Folic acid intakes were not unusually high in our sample of children.
In summary, total B12 intake (diet, supplement, PERT) was high, and largely due to high supplement-based B12 intake. The B12 and B6 vitamin intake was higher than recommended, and provided no known benefit. Lifelong high B12 intake will result in sustained elevated serum B12. The associated risks or benefits of prolonged high B12 intake and elevated serum B12 in people with CF is unknown. Studies are needed to determine the B12 dose that supports concentrations and status within the reference ranges and to evaluate possible B12-related clinical outcomes across the increasing life span of people with CF. The inverse correlation between B12 and FEV1 merits further investigation.
ACKNOWLEDGEMENTS
The authors thank the subjects, parents, other care providers, and all the CF Centers that participated in the study: Children’s National Medical Center, Washington, DC; Children’s Hospital of Philadelphia, Philadelphia, PA; Monmouth Medical Center, Long Branch, NJ; The Pediatric Lung Center, Fairfax, VA; Cystic Fibrosis Center of University of Virginia, Charlottesville, VA; Children’s Hospital of the King’s Daughters, Eastern Virginia Medical School, Norfolk, VA; Yale University School of Medicine, New Haven, CT; Cohen Children’s Medical Center, New Hyde Park, NY; St Joseph’s Children’s Hospital, Paterson, NJ and the Pediatric Specialty Center at Lehigh Valley Hospital, Bethlehem, PA. We would like to thank Walter Shaw, PhD and the Avanti Polar Lipids, Inc. team as the principal site for the SBIR II funding. We would also like to thank Norma Latham, MS, for study coordination, and Megan Johnson, Thananya Wooden, Elizabeth Matarrese and Nimanee Harris for their valuable contributions to the study.
Supported by the NIDDK NIH SBIR II (R44DK060302) and Nutrition Center at the Children’s Hospital of Philadelphia. The project described was also supported by the National Center for Research Resources and National Center for Advancing Translational Sciences, National Institutes of Health, through Grant UL1TR000003. The content is solely the responsibility of the authors and does not necessarily represent the official views of the NIH.
ABBREVIATIONS AND ACRONYMS
- Adj HAZ
Height-for-age Z score after height adjustment for mid-parent height
- AI
Adequate Intake
- BMI
Body mass index
- BMIZ
BMI-for-age Z score
- CF
Cystic fibrosis
- CHOP
Children’s Hospital of Philadelphia
- CTRC
Clinical Translational Research Center
- DHA
Docosahexaenoic acid
- DRI
Dietary Reference Intake
- EER
Estimated Energy Requirement
- FEV1
Forced expiratory volume at one second
- Hi-B12
Serum B12 above reference range for age and sex
- HAZ
Height-for-age Z score
- RR-B12
Serum B12 within reference range for age and sex
- hsCRP
High sensitivity C-reactive protein
- PERT
Pancreatic enzyme replacement therapy
- PI
Pancreatic insufficiency
- RDA
Recommended Dietary Allowance
- WAZ
Weight-for-age Z score
Footnotes
Clinical Trial Registration: Study of LYM-X-ORB™ to Improve Fatty Acid and Choline Status in Children with Cystic Fibrosis and Pancreatic Insufficiency, NCT00406536.
References
- 1.Carmel R. Cobalamin (B12) In: Shils ME, Moshe S, Ross AC, et al., editors. Modern Nutrition in Health and Disease. 10 th ed. Lippincott Williams & Wilkins; Baltimore, MD: 2006. pp. 482–97. [Google Scholar]
- 2.Gueant JL, Champigneulle B, Gaucher P, et al. Malabsorption of vitamin B12 in pancreatic insufficiency of the adult and of the child. Pancreas. 1990;5:559–67. doi: 10.1097/00006676-199009000-00011. [DOI] [PubMed] [Google Scholar]
- 3.Harms HK, Kennel O, Bertele RM, et al. Vitamin B12 absorption and exocrine pancreatic insufficiency in childhood. Eur J Pediatr. 1981;136:75–9. doi: 10.1007/BF00441715. [DOI] [PubMed] [Google Scholar]
- 4.Cystic Fibrosis Foundation Patient Registry 2011 Annual Report. Bethesda, MD: 2012. http://www.cff.org/UploadedFiles/research/ClinicalResearch/2011-Patient-Registry.pdf. [Google Scholar]
- 5.Carmel R, Hollander D, Gergely HM, et al. Pure human pancreatic juice directly enhances uptake of cobalamin by guinea pig ileum in vivo. Proc Soc Exp Biol Med. 1985;178:143–50. doi: 10.3181/00379727-178-41996. [DOI] [PubMed] [Google Scholar]
- 6.Deren JJ, Arora B, Toskes PP, et al. Malabsorption of crystalline vitamin B12 in cystic fibrosis. N Engl J Med. 1973;288:949–50. doi: 10.1056/NEJM197305032881808. [DOI] [PubMed] [Google Scholar]
- 7.Veeger W, Abels J, Hellemans N, et al. Effect of sodium bicarbonate and pancreatin on the absorption of vitamin B12 and fat in pancreatic insufficiency. N Engl J Med. 1962;267:1341–4. doi: 10.1056/NEJM196212272672604. [DOI] [PubMed] [Google Scholar]
- 8.Lepage G, Yesair DW, Ronco N, et al. Effect of an organized lipid matrix on lipid absorption and clinical outcomes in patients with cystic fibrosis. J Pediatr. 2002;141:178–85. doi: 10.1067/mpd.2002.124305. [DOI] [PubMed] [Google Scholar]
- 9.Feskanich D, Sielaff BH, Chong K, et al. Computerized collection and analysis of dietary intake inflammation. Comput Methods Programs Biomed. 1989;1:47–57. doi: 10.1016/0169-2607(89)90122-3. [DOI] [PubMed] [Google Scholar]
- 10.Institute of Medicine (U.S.) Dietary reference intakes for energy, carbohydrate, fiber, fat, fatty acids, cholesterol, protein, and amino acids. National Academies Press; Washington, D.C.: 2005. [DOI] [PubMed] [Google Scholar]
- 11.Trabulsi J, Ittenbach RF, Schall JI, et al. Evaluation of formulas for calculating total energy requirements of preadolescent children with cystic fibrosis. Am J Clin Nutr. 2007;85:144–51. doi: 10.1093/ajcn/85.1.144. [DOI] [PubMed] [Google Scholar]
- 12.Otten JJ, Hellwig JP, Meyers LD. DRI, dietary reference intakes : the essential guide to nutrient requirements. National Academies Press; Washington, D.C.: 2006. [Google Scholar]
- 13.Institute of Medicine (U.S.) Dietary reference intakes for thiamin, riboflavin, niacin, vitamin B6, folate, vitamin B12, pantothenic acid, biotin, and choline. National Academy Press; Washington, D.C.: 1998. [PubMed] [Google Scholar]
- 14.Hicks JM, Cook J, Goodwin ID, et al. Vitamin B12 and Folate. Pediatric Reference Ranges. Arch Pathol Lab Med. 1993;117:704–6. [PubMed] [Google Scholar]
- 15.Soldin SJ, Wong EC, Brugnara C, et al. Pediatric Reference Intervals. 7th ed. ACC Press; Washington DC: 2011. [Google Scholar]
- 16.Wu A. Tietz Clinical Guide to Laboratory Tests. 4th Edition ed. W.B. Saunders Company; Elsevier Press; St. Louis, MO: 2006. [Google Scholar]
- 17.Lohman TG, Roche AF, Martorell R. Anthropometric standardization reference manual. Human Kinetics Books; Champaign, IL: 1988. [Google Scholar]
- 18.Himes JH, Roche AF, Thissen D, et al. Parent-specific adjustments for evaluation of recumbent length and stature of children. Pediatrics. 1985;75:304–13. [PubMed] [Google Scholar]
- 19.Kuczmarski RJ, Ogden CL, Grummer-Strawn LM, et al. CDC growth charts: United States. Adv Data. 2000:1–27. [PubMed] [Google Scholar]
- 20.Zapletal A, Šamánek M, Paul T. Lung function in children and adolescents: methods, reference values. Karger; New York: 1987. [Google Scholar]
- 21.Wang X, Dockery DW, Wypij D, Jr., et al. Pulmonary function between 6 and 18 years of age. Pediatr Pulmonol. 1993;15:75–88. doi: 10.1002/ppul.1950150204. [DOI] [PubMed] [Google Scholar]
- 22.Hankinson JL, Odencrantz JR, Fedan KB. Spirometric reference values from a sample of the general U.S. population. Am J Respir Crit Care Med. 1999;159:179–87. doi: 10.1164/ajrccm.159.1.9712108. [DOI] [PubMed] [Google Scholar]
- 23.Rhodes DC, Clemens J, Goldman J, et al. What We Eat in America 2009-2010: United States Department of Agriculture. Agricultural Research Service; 2012. [Google Scholar]
- 24.Naimi D, Gueant JL, Hambaba L, et al. Gastric intrinsic factor hypersecretion stimulated by pentagastrin in cystic fibrosis. J Pediatr Gastroenterol Nutr. 1987;6:899–903. doi: 10.1097/00005176-198711000-00013. [DOI] [PubMed] [Google Scholar]
- 25.Simpson RM, Lloyd DJ, Gvozdanovic D, et al. Vitamin B12 deficiency in cystic fibrosis. Acta Paediatr Scand. 1985;74:794–6. doi: 10.1111/j.1651-2227.1985.tb10034.x. [DOI] [PubMed] [Google Scholar]
- 26.Lindemans J, Neijens HJ, Kerrebijn KF, et al. Vitamin B12 absorption in cystic fibrosis. Acta Paediatr Scand. 1984;73:537–40. doi: 10.1111/j.1651-2227.1984.tb09967.x. [DOI] [PubMed] [Google Scholar]
- 27.Lindemans J, Abels J, Neijens HJ, et al. Elevated serum vitamin B12 in cystic fibrosis. Acta Paediatr Scand. 1984;73:768–71. doi: 10.1111/j.1651-2227.1984.tb17773.x. [DOI] [PubMed] [Google Scholar]
- 28.Borowitz D, Baker RD, Stallings V. Consensus report on nutrition for pediatric patients with cystic fibrosis. J Pediatr Gastroenterol Nutr. 2002;35:246–59. doi: 10.1097/00005176-200209000-00004. [DOI] [PubMed] [Google Scholar]
- 29.Carmel R. Biomarkers of cobalamin (vitamin B-12) status in the epidemiologic setting: a critical overview of context, applications, and performance characteristics of cobalamin, methylmalonic acid, and holotranscobalamin II. Am J Clin Nutr. 2011;94:348S–58S. doi: 10.3945/ajcn.111.013441. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 30.Stabler SP. Clinical practice. Vitamin B12 deficiency. N Engl J Med. 2013;368:149–60. doi: 10.1056/NEJMcp1113996. [DOI] [PubMed] [Google Scholar]
- 31.Ermens AA, Vlasveld LT, Lindemans J. Significance of elevated cobalamin (vitamin B12) levels in blood. Clin Biochem. 2003;36:585–90. doi: 10.1016/j.clinbiochem.2003.08.004. [DOI] [PubMed] [Google Scholar]
- 32.Anderson RD, Roddam LF, Bettiol S, et al. Biosignificance of bacterial cyanogenesis in the CF lung. J Cyst Fibros. 2010;9:158–64. doi: 10.1016/j.jcf.2009.12.003. [DOI] [PubMed] [Google Scholar]
- 33.Scambi C, De Franceschi L, Guarini P, et al. Preliminary evidence for cell membrane amelioration in children with cystic fibrosis by 5-MTHF and vitamin B12 supplementation: a single arm trial. PLoS One. 2009;4:e4782. doi: 10.1371/journal.pone.0004782. [DOI] [PMC free article] [PubMed] [Google Scholar]