ABO hemolytic disease of the fetus and newborn: thirteen years of data after implementing a universal bilirubin screening and management program.

OBJECTIVE: ABO hemolytic disease occurs among neonates with blood groups A or B delivered to group O women. Extreme neonatal hyperbilirubinemia due to ABO disease has been reported, but its frequency is not well known. We sought to determine the odds of developing severe ABO hemolytic disease in the 13 years since adopting universal bilirubin screening/management in the Intermountain Healthcare system. STUDY DESIGN: We conducted a retrospective analysis of neonates born between 2004 and 2016, defining "severe hemolytic disease" as; (1) total serum bilirubin (TSB) >25 mg/dL, or (2) hospital readmission for jaundice, or (3) bilirubin encephalopathy. Neonates born to group O (+) mothers were included and considered either; (1) Controls (not at risk for ABO disease because they were group O), (2) Study subjects (at risk for ABO disease because they were group A or B). RESULTS: Of 400,531 live births, 47% were to group O women; 86% of whom were group O (+). Overall, 42,529 (27%) neonates born to group O (+) women had their blood group determined; 29,729 (68%) were O, 10,682 (25%) A, and 3109 (7%) B. Peak TSBs during the first 10 days were higher in group A (11.0 ± 4.2 mg/dL) and B (11.5 ± 4.3) than group O neonates (10.3 ± 4.1). However the relative risks of a TSB ≥25 mg/dL, readmission for jaundice, or kernicterus, were the same in the control vs. study groups. CONCLUSIONS: In our health system, severe hemolytic disease in neonates born to group O (+) woman is not more likely in group A or B neonates than in controls (group O). We recognize that in other practices, particularly those who do not have a universal bilirubin screening/management program, ABO hemolytic disease severity might be different than in our system.

Why do four NICUs using identical RBC transfusion guidelines have different gestational age-adjusted RBC transfusion rates?

OBJECTIVE: To compare neonatal red blood cell (RBC) transfusion rates in four large Intermountain Healthcare NICUs, all of which adhere to the same RBC transfusion guidelines. STUDY DESIGN: This retrospective analysis was part of a transfusion-management quality-improvement project. De-identified data included RBC transfusions, clinical and laboratory findings, the anemia-prevention strategies in place in each NICU, and specific costs and outcomes. RESULT: Of 2389 NICU RBC transfusions given during the 4-year period studied, 98.9 ± 2.1% (mean ± S.D.) were compliant with our transfusion guidelines, with no difference in compliance between any of the four NICUs. However, RBC transfusion rates varied widely between the four, with averages ranging from 4.6 transfusions/1000 NICU days to 21.7/1000 NICU days (P < 0.00001). Gestational age-adjusted transfusion rates were correspondingly discordant (P < 0.00001). The lower-transfusing NICUs had written anemia-preventing guidelines, such as umbilical cord milking at very low birth weight delivery, use of cord blood for admission laboratory studies, and darbepoetin dosing for selected neonates. Rates of Bell stage ⩾ 2 necrotizing enterocolitis and grade ⩾ 3 intraventricular hemorrhage were lowest in the two lower-transfusing NICUs (P < 0.0002 and P < 0.0016). Average pharmacy costs for darbepoetin were $84/dose, with an average pharmacy cost of $269 per transfusion averted. With a cost of $900/RBC transfusion, the anemia-preventing strategies resulted in an estimated cost savings to Intermountain Healthcare of about $6970 per 1000 NICU days, or about $282,300 annually. CONCLUSION: Using transfusion guidelines has been shown previously to reduce practice variability, lower transfusion rates and diminish transfusion costs. Based on our present findings, we maintain that even when transfusion guidelines are in place and adhered to rigorously, RBC transfusion rates are reduced further if anemia-preventing strategies are also in place.

Severe neonatal anemia from fetomaternal hemorrhage: report from a multihospital health-care system.

OBJECTIVE: The incidence of fetomaternal hemorrhage that is severe enough to cause neonatal anemia is not known. Owing to its relative rarity, much of the literature describing this condition is in the form of case reports and small case series. We performed a large, muiticentered, sequential, case series to determine the incidence, antecedents and outcomes. STUDY DESIGN: From the multicentered databases of Intermountain Healthcare, we obtained records of all neonates with hematocrit (Hct) <30% or hemoglobin (Hgb) <10 g dl(-1) on the day of birth, who had Kleihauer-Betke staining or flow cytometric evidence of fetomaternal hemorrhage. RESULT: Among 219,853 live births, 24 had anemia with evidence of fetomaternal hemorrhage (incidence estimate, 1 per 9160 live births). The initial Hgb ranged from 1.4 to 10.2 g dl(-1) (Hct 29.8%). The initial Hgb was <7 g dl(-1) in 18 (67%), <5 g dl(-1) in 12 (50%) and was <3 g dl(-1) in 7 (29%). All 7 mothers in whom neonatal Hgb was <3 g dl(-1) had reported absent fetal movement, as did 13 of 18 mothers when the initial Hgb was <7 g dl(-1). Outcomes were poorer in those with the lowest initial Hgb; in the two lowest, one died on day 1, and the other developed a grade 4 intraventricular hemorrhage (IVH). The adverse outcomes of death, IVH, periventricular leukomalacia, bronchopulmonary dysplasia or hypoxic-ischemic encephalopathy were common; occurring in 71% (17 of the 24), including all with an initial Hgb <5 g dl(-1) and all born at ≤35 weeks of gestation. CONCLUSION: Fetomaternal hemorrhage is a rare but sometimes devastating condition. Those with fetomaternal hemorrhage and an initial Hgb of <5 g dl(-1) are expected to need resuscitation at birth, to receive emergent transfusion support and to be at risk for death and major morbidities. Antenatal suspicion of this diagnosis should occur when absent fetal movement is reported. Improvements in rapid diagnosis are needed to prepare first responders and transfusion services.

Composition of peripheral blood progenitor cell components collected from healthy donors.

BACKGROUND: Peripheral blood progenitor cell (PBPC) components are being collected from healthy donors for allogeneic transplantation, but the quantity, quality, composition, and variability of PBPCs collected from healthy people given granulocyte-colony-stimulating factor (G-CSF) have not been evaluated. STUDY DESIGN AND METHODS: PBPC components were collected from 150 healthy people who were given G-CSF (5, 7.5, or 10 microg/kg/day) for 5 days. The components were evaluated for white cell (WBC), mononuclear cell, CD34+ cell, neutrophil, platelet, and red cell (RBC) composition. RESULTS: The quantities collected were: WBCs, 35.0 +/- 16.4 x 10(9) (range, 11.9-163.3 x 10(9)); mononuclear cells, 33.3 +/- 14.4 x 10(9) (range, 11.9-139.6 x 10(9)); CD34+ cells, 412 +/- 287 x 10(6) (range, 70-1658 x 10(6)); neutrophils, 1.71 +/- 3.59 x 10(9) (range, 0-27.6 x 10(9)); RBCs, 7.2 +/- 4.0 mL (range, 0-22.1 mL); and platelets, 480 +/- 110 x 10(9) (range, 250-920 x 10(9)). PBPC components collected from people given G-CSF at 7.5 or 10 microg per kg per day contained significantly more CD34+ cells (respectively, 428 +/- 300 x 10(6); range, 70-1658 x 10(6) and 452 +/- 294 x 10(6); range, 78-1380 x 10(6)) than those from people given G-CSF at 5 microg per kg per day (276 +/- 186 x 10(6); range, 91-767 x 10(6)) (p = 0.007 and p = 0.002). When 10 microg per kg per day of G-CSF was given, 50 percent of the components contained enough CD34+ cells for transplantation to a 75-kg recipient (375 x 10(6) CD34+ cells), but 10.6 percent of the components contained less than 150 x 10(6) CD34+ cells and thus would provide a transplantable dose only for a 30-kg patient. CONCLUSION: One PBPC component collected from a healthy donor given 7.5 or 10 microg per kg per day of G-CSF should contain 70 to 1660 x 10(6) CD34+ cells, with 0 to 22 mL of RBCs. Because of the great variability in the number of CD34+ cells collected, the quantity of CD34+ cells in each component should be measured after each procedure to ensure that sufficient quantities of cells are present for a successful transplant.

Blood counts in healthy donors 1 year after the collection of granulocyte-colony-stimulating factor-mobilized progenitor cells and the results of a second mobilization and collection.

BACKGROUND: Granulocyte-colony-stimulating factor (G-CSF)-mobilized blood cells are being used for allogeneic transplants, but the long-term effects of G-CSF on healthy individuals are not known. Furthermore, it is not certain how many CD34+ cells can be collected in a second mobilization and collection procedure. STUDY DESIGN AND METHODS: Nineteen people were given 2, 5, 7.5, or 10 micrograms of G-CSF per kg per day for 5 days, and blood progenitor cells were collected by apheresis on the sixth day; this was done on two occasions separated by at least 12 months. Blood counts obtained before and after each course of G-CSF and the quantity of cells collected were compared. RESULTS: There were no differences in white cell (WBC), platelet, red cell, and WBC differential counts measured before each course of G-CSF, and all the values were in the normal range. In a subset of 12 people who received 7.5 or 10 micrograms of G-CSF per kg per day for both courses, the numbers of neutrophils, mononuclear cells, and CD34+ cells in the blood after each course were similar (34.1 +/- 7.31 x 10(9)/L vs. 36.4 +/- 12.3 x 10(9)/L, p = 0.24; 6.59 +/- 2.28 x 10(9)/L vs. 5.63 +/- 2.11 x 10(9)/L, p = 0.24; and 92.0 +/- 55.6 x 10(5)/L vs. 119.2 +/- 104.6 x 10(6)/L; p = 0.48, respectively), as were the quantities of mononuclear cells (31.0 +/- 8.4 x 10(9) vs. 31.0 +/- 6.1 x 10(9); p = 0.64) and CD34+ cells (417 +/- 353 x 10(6) vs. 449 +/- 286 x 10(6); p = 0.53) collected in the two apheresis procedures. Furthermore, there was a positive correlation between the quantity of CD34+ cells collected from each of the 12 people per liter of whole blood processed in the two procedures (r2 = 0.86, p < 0.001). CONCLUSION: One year after the administration of G-CSF to healthy people, their blood counts were normal and unchanged from pretreatment counts. If healthy people donate blood progenitor cells after a second G-CSF course the quantity of CD34+ cells collected will be similar to that obtained in the first collection.

The kinetics of G-CSF mobilization of CD34+ cells in healthy people.

When healthy people are given granulocyte colony stimulating factor (G-CSF) for 10 days the number of CD34+ cells in the peripheral blood begins to increase on the fourth day, reaches a maximum on the sixth day and then decreases. In this study, we further define the time and variability of peak mobilization of CD34+ cells. Twenty-two healthy people were given G-CSF (7.5 or 10 micrograms kg-1 day-1) subcutaneously each morning for 5 days and peripheral blood CD34+ cell counts were analysed immediately prior to the fourth (day 4) and fifth (day 5) G-CSF injection and 24 h after the fifth injection (Day 6). White blood cell (WBC) and neutrophil counts were greatest on day 6 [WBC = 43.8 +/- 13.9 x 10(9) L-1 (mean +/- 1 SD) and neutrophils = 36.6 +/- 12.8 x 10(9) L-1]. In contrast the CD34+ cell counts on day 6 (107 +/- 104 x 10(6) L-1) were less than on day 5 (128 +/- 136 x 10(6) L-1) (P = 0.048) but still greater than on day 4 (60.7 +/- 40.2 x 10(6) L-1) (P < 0.0001). The CD34+ cell counts of 10 donors were measured 2, 4 and 6 h after the fifth injection to determine if the counts increased further between days 5 and 6. The number of CD34+ cells in the blood on day 5 2 h after the fifth injection (193 +/- 277 x 10(6) L-1) was greater than the number prior to the injection (158 +/- 190 x 10(6) L-1), 4 h post-injection (139 +/- 158 x 10(6) L-1) and 6 h post-injection (170 +/- 236 x 10(6) L-1), but the differences were not significant (P = 0.29, 0.25 and 0.45). The number of CD34+ cells in the blood of 12 people were measured before and after the fourth G-CSF dose. Prior to the day 4 injection the CD34+ count was 61 +/- 40 x 10(6) L-1. At 2, 4 and 6 h the counts were 60 +/- 40, 61 +/- 29 and 64 +/- 30 x 10(6) L-1, respectively, and the differences were not significant (P = 0.99, P = 0.98, and P = 0.73). In conclusion, when healthy volunteers are given daily G-CSF injections, the number of mobilized CD34+ cells was the greatest on day 5, slightly less on day 6 and the least on day 4. If only one PBSC component is needed, PBSCs can be collected on day 5 after only 4 days of G-CSF. If PBSC components are collected on both days 5 and 6, the fifth dose can be given either before or after the collection of the first PBSC component.

Changes in blood counts after the administration of granulocyte-colony-stimulating factor and the collection of peripheral blood stem cells from healthy donors.

BACKGROUND: After the collection of granulocyte-colony-stimulating factor (G-CSF)-mobilized peripheral blood stem cells from healthy donors, the donor platelet counts fall. However, the magnitude and duration of this decrease are not known. STUDY DESIGN AND METHODS: Sixty healthy people were given G-CSF (5, 7.5, or 10 micrograms/kg/day) for 5 days (Days 1-5), and 1 peripheral blood stem cell component was collected on Day 6. The platelet count, white cell count, absolute neutrophil count, hematocrit, and red cell count were measured before administration of G-CSF (Day 0), before collection of peripheral blood stem cells on Day 6, and on Days 8, 10, 13, 16, and 20. RESULTS: The platelet count fell from 261 +/- 47 x 10(9) cells per L on Day 0 to 159 +/- 30 x 10(9) cells per L on Day 8 (p < 0.0001) and reached its lowest level on Day 10 (146 +/- 30 x 10(9)/L; p < 0.001). Compared to Day 0 levels, the platelet count was lower on Day 13 (185 +/- 49 x 10(9)/L, p < 0.001), was the same on Day 16 (270 +/- 53 x 10(9)/L), and was greater on Day 20 (333 +/- 60 x 10(9)/L, p < 0.0001). The white cell count returned to pretreatment values on Day 13, and the absolute neutrophil count returned to pretreatment values on Day 10 (Day 0 white cell count = 6.05 +/- 1.59 x 10(9)/L and Day 0 absolute neutrophil count = 3.97 +/- 1.52 x 10(9)/L). On Day 20, both were less than pretreatment values (white cell count = 5.14 +/- 1.24 x 10(9)/L, p = 0.0007 and absolute neutrophil count = 3.20 +/- 1.24 x 10(9)/L, p = 0.0036). The red cell counts on Day 16 (4.52 +/- 0.41 x 10(12)/L) and Day 20 (4.42 +/- 0.39 x 10(12)/L) were less than Day 0 values (4.73 +/- 0.43 x 10(12)/L, p = 0.008 and p < 0.0001, respectively). The hematocrit on Day 20 (39.2 +/- 3.2%) was also less than that on Day 0 (41.2 +/- 4.8%; p = 0.01). The changes in these blood counts were not affected by the dose of the G-CSF. CONCLUSION: After stimulation with granulocyte-colony-stimulating factor and the collection or peripheral blood stem cells, the platelet counts in normal donors were decreased for at least 7 days (Days 6-13). Two weeks after collection of peripheral blood stem cells (Day 20), platelet production was increased, but the production of neutrophils and red cells was decreased. If two or more peripheral blood stem cell components are collected, then the platelet count should be measured after the second and subsequent collections. Further studies on the long-term effect of G-CSF on blood counts are needed.

Exchange transfusion the hard way: massive hemolysis following transplantation of bone marrow with minor ABO incompatibility.

BACKGROUND: Bone marrow transplantation using donors with minor ABO incompatibility may result in the rapid production of donor-derived red cell isohemagglutinins, causing hemolysis of recipient red cells. CASE REPORT: The transplant of sibling-donor marrow with minor ABO incompatibility (group O donor marrow to group A recipient), using FK-506 as an immunosuppressant to prevent graft-versus-host disease, is reported. Following early myeloid engraftment, the recipient developed hemolysis of her entire A red cell population between Day 8 and Day 11. This brisk hemolytic anemia was due to rapid donor lymphoid engraftment that resulted in the explosive production of donor-derived anti-A. CONCLUSION: Patients undergoing the transplantation of marrow from donors with minor ABO incompatibility in which the donor cells can produce isohemagglutinins against the recipient's red cells must be kept under vigilant observation for the possible development of severe hemolysis, particularly in the setting of profound T-cell suppression without B-cell suppression.