Patients with sickle cell anemia are chronically transfused. Therefore, it is important to prevent the alloimmunization of RBC antigens. The authors identified a high frequency antigen-negative blood group in patients with sickle cell anemia. As the number of foreigners residing in Korea is increasing, it is necessary to know what to consider when transfusing blood to sickle cell anemia patients. Patients with sickle cell anemia should be informed of the exact blood group type using extended RBC typing to confirm the ABO, Rh, Kell, and Duffy blood types at diagnosis or before the first blood transfusion. Extended matched blood transfusion can reduce the risk of alloimmunization of RBC antigens.
Anemia ; Anemia, Sickle Cell* ; Blood Transfusion ; Diagnosis ; Duffy Blood-Group System ; Emigrants and Immigrants ; Erythrocytes* ; Humans ; Korea

OBJECTIVETo screen rare blood groups Fy(a-), s-, k-, Di(b-) and Js(b-) in an ethnic Zhuang population.

METHODSSequence-specific primers were designed based on single nucleotide polymorphism (SNP) sites of blood group antigens Fy(b) and s. A specific multiplex PCR system I was established. Multiplex PCR system II was applied to detect alleles antigens Di(b), k, Js(b)1910 and Js(b) 2019 at the same time. The two systems was were used to screen for rare blood group antigens in 4490 randomly selected healthy donors of Guangxi Zhuang ethnic origin.

RESULTSWe successfully made the multiplex PCR system I. We detected the rare blood group antigens using the two PCR system. There are five Fy(a-), three s(-), two Di(b-) in 4490 Guangxi zhuang random samples. The multiplex PCR system I has achieved good accuracy and stability. With multiplex PCR systems I and II, 4490 samples were screened. Five Fy(a-), three s(-) and two Di(b-) samples were discovered.

CONCLUSIONMultiplex PCR is an effective methods, which can be used for high throughput screening of rare blood groups. The rare blood types of Guangxi Zhuang ethnic origin obtained through the screening can provide valuable information for compatible blood transfusion. Through screening we obtained precious rare blood type materials which can be used to improve the capability of compatible infusion and reduce the transfusion reactions.

Blood Group Antigens ; genetics ; Duffy Blood-Group System ; genetics ; Genotype ; Humans ; Multiplex Polymerase Chain Reaction ; methods ; Receptors, Cell Surface ; genetics

BACKGROUND: In the Duffy blood group system (Fy(a), Fy(b), Fy(x), and Fy antigens), Fy(x) antigen is associated with weak Fy(b) while Fy antigen means the null phenotype Fy (a-b-). Fyx antigen and Fy antigen result from the polymorphisms of Fy125 allele. This report assessed the allele frequency and genotype frequency of Fy(a), Fy(b), Fy(x), and Fy antigens in Koreans. METHODS: We performed a study of the followings on 253 visitors to the health promotion center of Seoul National University Bundang Hospital: PCR-RFLP and PCR-SSP for the detection of Duffy 125G > A and -33T > C; PCR-SSP for the detection of Duffy 265C > T and 298G > A. RESULTS: The results of PCR-RFLP and PCR-SSP were consistent with each other in a total of 253 subjects. Allele frequency was as follows: Fy 92.3%, Fy(125) 6.1%, and fy(125/265) 1.6%. The fy(125/265) allele was newly observed. Fy(125/298), fy(125/265/298), and fy(-33/125) alleles were not detected in Koreans. The distribution of Duffy phenotypes in Koreans was as follows: Fy (a+b-) 88.1%, Fy (a-b+) 0.4%, Fy (a+b+) 11.5%, and Fy (a-b-) 0.0%. Fy (a+) was 99.6% and Fy (b+) was 11.9%. CONCLUSION: In our study for Duffy polymorphisms, the frequency of Fy allele was very high. The frequency was similar to those of other Asian populations, but different from those of Caucasians. The fy(125/265) allele, which was associated with Fy(x) antigen, was newly detected in Koreans.
Alleles* ; Asian Continental Ancestry Group ; Duffy Blood-Group System ; Gene Frequency ; Genotype ; Health Promotion ; Humans ; Phenotype ; Polymerase Chain Reaction ; Seoul

This study was aimed to establish the real-time multiple-PCR with melting curve analysis for Duffy blood group Fy-a/b genotyping. According to the sequence of mRNA coding for β-actin and Fy-a/b, the primers of β-actin and Fy-a/b were synthesized. The real-time multiple-PCR with melting curve analysis for Fy-a/b genotyping was established. The Fy-a/b genotyping of 198 blood donors in Chinese Chengdu area has been investigated by melting curve analysis and PCR-SSP. The results showed that the results of Fy-a/b genotype by melting curve analysis were consistent with PCR-SSP. In all of 198 donors in Chinese Chengdu, 178 were Fy(a) (+) (89.9%), 19 were Fy(a) (+) Fy(b) (+) (9.6%), and 1 was Fy(b) (+) (0.5%). The gene frequency of Fy(a) was 0.947, while that of Fy(b) was 0.053. It is concluded that the genotyping method of Duffy blood group with melting curve analysis is established, which can be used as a high-throughput screening tool for Duffy blood group genotyping; and the Fy(a) genotype is the major of Duffy blood group of donors in Chinese Chengdu area.
Alleles ; Blood Grouping and Crossmatching ; methods ; Duffy Blood-Group System ; genetics ; Freezing ; Gene Frequency ; Genotype ; Humans ; Real-Time Polymerase Chain Reaction

Blood Group Antigens ; genetics ; Duffy Blood-Group System ; genetics ; Humans ; Kell Blood-Group System ; genetics ; Kidd Blood-Group System ; genetics ; Polymorphism, Single Nucleotide ; Rh-Hr Blood-Group System ; genetics

BACKGROUNDMolecular testing is more precise compared to serology and has been widely used in genotyping blood group antigens. Single nucleotide polymorphisms (SNPs) of blood group antigens can be determined by the polymerase chain reaction with sequence specific priming (PCR-SSP) assay. Commercial high-throughput platforms can be expensive and are not approved in China. The genotype frequencies of Kidd, Kell, Duffy, Scianna, and RhCE blood group antigens in Jiangsu province were unknown. The aim of this study is sought to detect the genotype frequencies of Kidd, Kell, Duffy, Scianna, and RhCE antigens in Jiangsu Chinese Han using molecular methods with laboratory developed tests.

METHODSDNA was extracted from EDTA-anticoagulated blood samples of 146 voluntary blood donors collected randomly within one month. Standard serologic assay for red blood cell antigens were also performed except the Scianna blood group antigens. PCR-SSP was designed to work under one PCR program to identify the following SNPs: JK1/JK2, KEL1/KEL2, FYA/FYB, SC1/SC2, C/c and E/e.

RESULTSSerologic antigen results were identical to the phenotypes that were predicted from genotyping results. The allele frequencies for Jk*01 and Jk*02 were 0.51 and 0.49, respectively; for Fy*A and Fy*B 0.94 and 0.06; for RHCE*C and RHCE*c 0.68 and 0.32; and for RHCE*E and RHCE*e 0.28 and 0.72. Among 146 blood donors, all were KEL*02/KEL*02 and SC*01/SC*01, indicating allele frequencies for KEL*02 and SC*01 close to 1.00.

CONCLUSIONSThe use of PCR-SSP working under the same condition for testing multiple antigens at the same time is practical. This approach can be effective and cost-efficient for small-scale laboratories and in developing counties. These molecular tests can be also used for identifying rare blood types.

Blood Group Antigens ; genetics ; Butyrophilins ; China ; ethnology ; Duffy Blood-Group System ; genetics ; Gene Frequency ; Genotype ; Humans ; Kell Blood-Group System ; genetics ; Kidd Blood-Group System ; genetics ; Polymerase Chain Reaction ; Polymorphism, Single Nucleotide ; Rh-Hr Blood-Group System ; genetics

BACKGROUND: Knowledge about the frequency of red blood cell-antigen phenotypes in a population can be helpful in the creation of a donor data bank for the preparation of indigenous cell panels and for providing antigen-negative compatible blood to patients with multiple alloantibodies. METHODS: ABO and RhD blood grouping was performed on 9,280 continuous voluntary and replacement donors. For other rare blood groups, 508 ACD blood samples were obtained from the donors at the Blood Bank of the Department of Transfusion Medicine, All India Institute of Medical Sciences (AIIMS), New Delhi, India. Blood group antigens were determined by tube method using anti-sera (Bio-Rad, USA), and the phenotype frequencies were expressed as percentages. RESULTS: Group B (37.39%) was the most common, followed by group O (31.85%). R1R1 and rr were the most common phenotypes amongst Rh positive and Rh negative groups, respectively. A rare phenotype R2Rz was found in one donor. For Kidd and Duffy blood group systems, Jk (a+b+) and Fy (a+b+) were the most common phenotypes (46.06% and 48.03%, respectively). The most common phenotypes for MNSs, Lu, and Kell blood groups were M+N+, S-s+, Lu (a-b+), and K-k+, respectively. A very rare case of Fy (a-b-) and Jk (a-b-) was found in a single donor. CONCLUSION: This study is the first small step to create a rare donor data bank and to prepare indigenous cell panels to provide compatible blood to all multi-transfused alloimmunized patients.
Blood Banks ; Blood Donors ; Blood Group Antigens ; Blood Grouping and Crossmatching ; Duffy Blood-Group System ; Humans ; India ; Phenotype ; Tertiary Healthcare ; Tissue Donors

BACKGROUND: Knowledge about the frequency of red blood cell-antigen phenotypes in a population can be helpful in the creation of a donor data bank for the preparation of indigenous cell panels and for providing antigen-negative compatible blood to patients with multiple alloantibodies. METHODS: ABO and RhD blood grouping was performed on 9,280 continuous voluntary and replacement donors. For other rare blood groups, 508 ACD blood samples were obtained from the donors at the Blood Bank of the Department of Transfusion Medicine, All India Institute of Medical Sciences (AIIMS), New Delhi, India. Blood group antigens were determined by tube method using anti-sera (Bio-Rad, USA), and the phenotype frequencies were expressed as percentages. RESULTS: Group B (37.39%) was the most common, followed by group O (31.85%). R1R1 and rr were the most common phenotypes amongst Rh positive and Rh negative groups, respectively. A rare phenotype R2Rz was found in one donor. For Kidd and Duffy blood group systems, Jk (a+b+) and Fy (a+b+) were the most common phenotypes (46.06% and 48.03%, respectively). The most common phenotypes for MNSs, Lu, and Kell blood groups were M+N+, S-s+, Lu (a-b+), and K-k+, respectively. A very rare case of Fy (a-b-) and Jk (a-b-) was found in a single donor. CONCLUSION: This study is the first small step to create a rare donor data bank and to prepare indigenous cell panels to provide compatible blood to all multi-transfused alloimmunized patients.
Blood Banks ; Blood Donors ; Blood Group Antigens ; Blood Grouping and Crossmatching ; Duffy Blood-Group System ; Humans ; India ; Phenotype ; Tertiary Healthcare ; Tissue Donors

BACKGROUNDThe influence of inflammatory processes has been one of the hot topics in discussions of the etiology of chronic venous insufficiency (CVI). Erythrocytes are very important in controlling inflammatory immunity and innate immune reactions. The purpose of this study was to analyze the correlation between the development of CVI and the change of CD35, Fy6 on erythrocytes, and interleukin-8 (IL-8) levels.

METHODSA group of 43 patients with CVI were studied in parallel with 8 healthy individuals serving as control subjects. Control subjects were those with normal findings on lower extremity duplex examinations. We used an erythrocyte flow cytometer to examine the expression of both CD35 and Fy6 on red blood cells, and an enzyme-linked immunosorbent assay analysis method to measure plasma IL-8 levels. We also analyzed the change of IL-8 levels under the influence of erythrocytes using a modified method of the hemaimmune reaction.

RESULTSCompared with normal control subjects, CD35 expression increased significantly among patients with CVI classified as C4 without lipodermatosclerosis, but tended to decrease and reach the lowest level among patients classified as C5-C6. Fy6 expression increased significantly among patients in the early stages of CVI, but tended to decrease remarkably among patients classified as C5-C6. The inflammatory response intensified at the C5-C6 classification, where high levels of IL-8 coexisted with a low expression of Fy6. The increase in IL-8 in the CVI group was higher than in the control group in association with the complete blood cells, regardless of the presence of erythrocytes, when inactive tumour cells were added, whereas the level of IL-8 in the CVI group was significantly lower than in the control group.

CONCLUSIONSAbnormalities of erythrocyte innate immunity represents a fundamental derangement in CVI. These inadequate inflammatory responses may lead to local tissue and microvascular damage of the lower extremity.

Chronic Disease ; Duffy Blood-Group System ; blood ; Erythrocytes ; immunology ; physiology ; Humans ; Interleukin-8 ; blood ; physiology ; Leg ; blood supply ; Receptors, Cell Surface ; blood ; Receptors, Complement 3b ; blood ; Venous Insufficiency ; immunology

The Duffy antigen was discovered in 1950, in a multiply transfused hemophiliac. Important progress has since been made in understanding the Duffy blood group system and its complexity. The Duffy blood group antigen (gp-Fy) is present primarily in erythrocytes, and also in endothelial cells of capillary and postcapillary venules, Purkinje cells of cerebellum, kidney, and pulmonary alveoli. The gp-Fy serves not only as a blood group antigen, but also as a receptor for chemokines, and as a receptor for Plasmodium vivax malaria parasites. The Duffy antigen is encoded by the DARC gene, its approved name is Duffy blood group chemokine receptor. Investigation of the DARC gene can help us in understanding the relationship of infectious disease to race or population. In addition, the allelic frequency of DARC varies according to the geographic area, which appears to reflect the history that mankind had adapted to environments and diseases, emigrating. As a result, further study of Duffy antigens can provide us with an integral and sound understanding of the human race.
Blood Group Antigens ; Capillaries ; Cerebellum ; Chemokines ; Communicable Diseases ; Continental Population Groups ; Duffy Blood-Group System ; Endothelial Cells ; Erythrocytes ; Humans ; Kidney ; Malaria, Vivax ; Parasites ; Plasmodium vivax ; Pulmonary Alveoli ; Purkinje Cells ; Venules