Real-Time PCR-Based Screening for Homozygous SMN2 Deletion Using Residual Dried Blood Spots.

The survival motor neuron 2 (SMN2) gene is a recognized modifier gene of spinal muscular atrophy (SMA). However, our knowledge about the role of SMN2-other than its modification of SMA phenotypes-is very limited. Discussions regarding the relationship between homozygous SMN2 deletion and motor neuron diseases, including amyotrophic lateral sclerosis, have been mainly based on retrospective epidemiological studies of the diseases, and the precise relationship remains inconclusive. In the present study, we first estimated that the frequency of homozygous SMN2 deletion was ~1 in 20 in Japan. We then established a real-time polymerase chain reaction (PCR)-based screening method using residual dried blood spots to identify infants with homozygous SMN2 deletion. This method can be applied to a future prospective cohort study to clarify the relationship between homozygous SMN2 deletion and motor neuron diseases. In our real-time PCR experiment, both PCR (low annealing temperatures) and blood (high hematocrit values and low white blood cell counts) conditions were associated with incorrect results (i.e., false negatives and positives). Together, our findings not only help to elucidate the role of SMN2, but also aid in our understanding of the pitfalls of current SMA newborn screening programs for detecting homozygous SMN1 deletions.

Correction: Noguchi et al. PCR-Based Screening of Spinal Muscular Atrophy for Newborn Infants in Hyogo Prefecture, Japan. Genes 2022, 13, 2110.

The authors wish to make the following correction to this paper [...].

PCR-Based Screening of Spinal Muscular Atrophy for Newborn Infants in Hyogo Prefecture, Japan.

Spinal muscular atrophy (SMA) is a common devastating neuromuscular disorder, usually involving homozygous deletion of the SMN1 gene. Newly developed drugs can improve the motor functions of infants with SMA when treated in the early stage. To ensure early diagnosis, newborn screening for SMA (SMA-NBS) via PCR-based genetic testing with dried blood spots (DBSs) has been spreading throughout Japan. In Hyogo Prefecture, we performed a pilot study of SMA-NBS to assess newborn infants who underwent routine newborn metabolic screening between February 2021 and August 2022. Hyogo Prefecture has ~40,000 live births per year and the estimated incidence of SMA is 1 in 20,000-25,000 based on genetic testing of symptomatic patients with SMA. Here, we screened 8336 newborns and 12 screen-positive cases were detected by real-time PCR assay. Multiplex ligation-dependent probe amplification assay excluded ten false positives and identified two patients. These false positives might be related to the use of heparinized and/or diluted blood in the DBS sample. Both patients carried two copies of SMN2, one was asymptomatic and the other was symptomatic at the time of diagnosis. SMA-NBS enables us to prevent delayed diagnosis of SMA, even if it does not always allow treatment in the pre-symptomatic stage.

A Case of Paroxysmal Cold Hemoglobinuria Possessing Moderate Paroxysmal Nocturnal Hemoglobinuria-Type Erythrocytes.

BACKGROUND Paroxysmal cold hemoglobinuria (PCH) is an autoimmune hemolytic disease caused by the Donath-Landsteiner (DL) antibody. Paroxysmal nocturnal hemoglobinuria (PNH) is a non-autoimmune hemolytic disease that is caused by a dysfunction in the synthesis of the glycosyl phosphatidylinositol anchor protein, resulting in the deregulation of the complement cascade and hypersensitivity for a hemolytic attack against erythrocytes. The mechanisms of these 2 hemolytic diseases are distinct. If PCH and PNH coexist in a patient, it is difficult to perform a differential diagnosis. We introduce a case of PCH that had DL antibodies and large PNH-type clones. CASE REPORT An 82-year-old female patient was referred to our hospital because of anemia. Initial workup revealed a negative antiglobulin test and a positive DL test. For the differential diagnosis, we surveyed the population of cells that had PNH-type clones, which revealed erythrocyte PNH clones (19.6%) and granulocyte PNH clones (73.3%). During the patient's clinical course, mild hemolysis persisted without any attack. The percentage of the PNH-type erythrocytes was not obviously changed, and the DL antibody was detected 8 months after the initial admission. We determined that the persistent mild anemia was caused by concomitant diseases of PCH and PNH, although determining which of the 2 hemolytic systems was primarily responsible for the anemia was difficult. CONCLUSIONS When considering the differential diagnosis for hemolytic diseases, an adequate combination of laboratory tests for hemolysis is required.

Glycogen Storage Disease Type Ia Screening Using Dried Blood Spots on Filter Paper: Application of COP-PCR for Detection of the c.648G>T G6PC Gene Mutation.

Glycogen storage disease type Ia (GSDIa, OMIM #232200) is an autosomal recessive metabolic disease characterized by impaired glucose homeostasis and has a long-term complication of hepatocellular adenoma/carcinoma. GSDIa is caused by deleterious mutations in the glucose-6-phosphatase gene (G6PC). Recent studies have suggested that early treatment by gene replacement therapy may be a good solution to correct the glucose metabolism and prevent serious late complications. Early treatment of the disease needs an early disease detection system. Thus, we aimed to develop a screening system for GSDIa using dried blood spots (DBS) to detect the c.648G>T mutation in G6PC, which is a frequent mutation in the East Asian population. In this study, a total of 51 DBS samples (50 healthy controls and one patient with c.648G>T) were tested by modified competitive oligonucleotide priming PCR (mCOP-PCR). In control DBS samples, the c.648G allele was amplified at lower Cq (quantification cycle) values (<11), while the c.648T allele was amplified at higher Cq values (>14). In the patient DBS sample, the c.648T allele was amplified at a lower Cq value (<11), and the c.648G allele was amplified at a higher Cq value (>14). Based on these findings, we concluded that our mCOP-PCR system clearly differentiated the wild-type and mutant alleles, and may be applicable for screening for GSDIa with the c.648G>T mutation in G6PC.

Dried Blood Spot Screening System for Spinal Muscular Atrophy with Allele-Specific Polymerase Chain Reaction and Melting Peak Analysis.

Background and Aim: Spinal muscular atrophy (SMA) is a lower motor neuron disease with autosomal recessive inheritance caused by homozygous SMN1 deletions. Although SMA has been considered as incurable, newly developed drugs improve life prognoses and motor functions of patients. To maximize the efficacy of the drugs, SMA patients should be treated before symptoms become apparent. Thus, newborn screening for SMA is strongly recommended. In this study, we aim to establish a new simple screening system based on DNA melting peak analysis. Materials and Methods: A total of 124 dried blood spot (DBS) on FTA® ELUTE cards (51 SMN1-deleted patients with SMA, 20 carriers, and 53 controls) were punched and subjected to direct amplification of SMN1 and CFTR (reference gene). Melting peak analyses were performed to detect SMN1 deletions from DBS samples. Results: A combination of allele-specific polymerase chain reaction (PCR) and melting peak analyses clearly distinguished the DBS samples with and without SMN1. Compared with the results of fresh blood samples, our new system yielded 100% sensitivity and specificity. The advantages of our system include (1) biosafe collection, transfer, and storage for DBS samples, (2) obviating the need for DNA extraction from DBS preventing contamination, (3) preclusion of fluorescent probes leading to low PCR cost, and (4) fast and high-throughput screening for SMN1 deletions. Conclusion: We demonstrate that our system would be applicable to a real-world newborn screening program for SMA, because our new technology is efficient for use in routine clinical laboratories that do not have highly advanced PCR instruments.

Assessment of Spinal Muscular Atrophy Carrier Status by Determining SMN1 Copy Number Using Dried Blood Spots.

Spinal muscular atrophy (SMA) is a common neuromuscular disease with autosomal recessive inheritance. The disease gene, SMN1, is homozygously deleted in 95% of SMA patients. Although SMA has been an incurable disease, treatment in infancy with newly developed drugs has dramatically improved the disease severity. Thus, there is a strong rationale for newborn and carrier screening for SMA, although implementing SMA carrier screening in the general population is controversial. We previously developed a simple, accurate newborn SMA screening system to detect homozygous SMN1 deletions using dried blood spots (DBS) on filter paper. Here, we modified our previous system to detect the heterozygous deletions of SMN1, which indicates SMA carrier status. The system involves a calibrator-normalized relative quantification method using quantitative nested PCR technology. Our system clearly separated the DBS samples with one SMN1 copy (carrier status with a heterozygous deletion of SMN1) from the DBS samples with two SMN1 copies (non-carrier status with no deletion of SMN1). We also analyzed DBS samples from SMA families, confirmed SMA in the affected children, and determined the carrier status of their parents based on the SMN1 copy number. In conclusion, our system will provide essential information for risk assessment and genetic counseling, at least for SMA families.

Spinal Muscular Atrophy: New Screening System with Real-Time mCOP-PCR and PCR-RFLP for SMN1 Deletion.

BACKGROUND: Spinal Muscular Atrophy (SMA) is a common autosomal recessive neuromuscular disorder characterized by degeneration or loss of lower motor neurons. More than 95% of SMA patients show homozygous deletion for the survival motor neuron 1 (SMN1) gene. For the screening of SMN1 deletion, it is necessary to differentiate SMN1 from its highly homologous gene, SMN2. We developed a modified competitive oligonucleotide priming-PCR (mCOP-PCR) method using dried blood spot (DBS)-DNA, in which SMN1 and SMN2-specific PCR products are detected with gel-electrophoresis. Next, we added a targeted pre-amplification step prior to the mCOP-PCR step, to avoid unexpected, non-specific amplification. The pre-amplification step enabled us to combine mCOP-PCR and real-time PCR. In this study, we combined real-time mCOP-PCR and PCR-restriction fragment length polymorphism (PCR-RFLP) to develop a new screening system for detection of SMN1 deletion. METHODS: DBS samples of the subjects were stored at room temperature for a period of less than one year. Each subject had already been genotyped by the first PCR-RFLP using fresh blood DNA. SMN1/SMN2 exon 7 was collectively amplified using conventional PCR (targeted pre-amplification), the products of which were then used as a template in the real-time PCR with mCOP-primer sets. To confirm the results, the pre-amplified products were subject to the second PCR-RFLP. RESULTS: The real-time mCOP-PCR separately amplified SMN1 and SMN2 exon7, and clearly demonstrated SMN1 deletion in an SMA patient. The results of the real-time mCOP-PCR using DBS-DNA were completely consistent with those of the first and second PCR-RFLP analysis. CONCLUSION: In our new system for detection of SMN1 deletion, real-time mCOP-PCR rapidly proved the presence or absence of SMN1 and SMN2, and the results were easily tested by PCR-RFLP. This solid genotyping system will be useful for SMA screening.

Spinal Muscular Atrophy: Advanced Version of Screening System with Real-Time mCOP-PCR and PCR-RFLP for SMN1 Deletion.

BACKGROUND: Spinal Muscular Atrophy (SMA) is a common autosomal recessive neuromuscular disease characterized by defects of lower motor neurons. More than 95% of SMA patients show homozygous deletion for the survival motor neuron 1 (SMN1) gene. For the screening of SMN1 deletion using dried blood spot (DBS), we developed a new combined system with real-time "modified competitive oligonucleotide priming"-polymerase chain reaction (mCOP-PCR) and PCR restriction fragment length polymorphism (PCR-RFLP). Although our real-time mCOP-PCR method is secured enough to be gene-specific, its amplification efficiency is not as good because the reverse primers carry a nucleotide mismatched with the sequence of the pre-amplified product. The mismatch has consequently been generated in the process of introducing a restriction enzyme site in the pre-amplified products for PCR-RFLP. METHOD: DBS samples of the subjects were stored at room temperature for a period of less than one year. Each subject had already been genotyped by the first PCR-RFLP using fresh blood DNA. SMN1/SMN2 exon 7 was collectively amplified using conventional PCR (targeted pre-amplification). Pre-amplified products were used as template in the real-time mCOP-PCR, and, on the other hand, were digested with DraI enzyme (PCR-RFLP). To improve the amplification efficiency of mCOP-PCR, one nucleotide change was introduced in the original reverse primers (SMN1-COP and SMN2-COP) to eliminate the mismatched nucleotide. RESULTS: The real-time mCOP-PCR with a new primer (SMN1-COP-DRA or SMN2-COP-DRA) more rapidly and specifically amplified SMN1 and SMN2, and clearly demonstrated SMN1 deletion in an SMA patient. With the new primers, the amplification efficiencies of real-time mCOP-PCR were improved and the Cq values of SMN1 (+) and SMN2 (+) samples were significantly lowered. CONCLUSION: In the advanced version of our screening system for homozygous SMN1 deletion using DBS, the real-time mCOP-PCR with newly-designed reverse primers demonstrated the presence or absence of SMN1 and SMN2 within a shorter time, and the results were easily tested by PCR-RFLP. This rapid and accurate screening system will be useful for detection of newborn infants with SMA.

Nested PCR Amplification Secures DNA Template Quality and Quantity in Real-time mCOP-PCR Screening for SMA.

BACKGROUND: Spinal Muscular Atrophy (SMA) is a common autosomal recessive disorder caused by SMN1 gene deletion. SMA has been considered an incurable disease. However, a newly-developed antisense oligonucleotide drug, nusinersen, brings about a good outcome to SMA patients in the clinical trials. Now, a screening for SMA is required for early diagnosis and early treatment so as to give a better clinical outcome to the patients. We have invented a new technology, mCOP-PCR, for SMA screening using dried blood spot (DBS) on the filter paper. One of the problems encountered in SMA screening is poor quality and quantity of DNA extracted from DBS. METHODS: DNA was extracted from DBS of six individuals. Fresh blood DNA of each individual had already been genotyped using PCR/RFLP. The fragments including the sequence of SMN1/SMN2 exon 7 were pre-amplified with conventional PCR. To determine which pre-amplified product is a better template for the real-time mCOP-PCR, we did pre-amplification with a single PCR or pre-amplification with a nested PCR. RESULTS: The real-time mCOP-PCR using pre-amplified products with a single PCR brought about ambiguous results in some SMN1-carrying individuals. However, the results of real-time mCOP-PCR following pre-amplification with a nested PCR were completely matched with those of PCR-RFLP. CONCLUSION: In our study on the real-time mCOP-PCR screening system for SMA, a nested PCR secured the DNA template quality and quantity, leading to unambiguous results of SMA screening.

Newborn Screening for Spinal Muscular Atrophy: DNA Preparation from Dried Blood Spot and DNA Polymerase Selection in PCR.

BACKGROUND: Polymerase chain reaction (PCR) analysis using DNA from dried blood spot (DBS) samples on filter paper is a critical technique for spinal muscular atrophy (SMA) newborn screening. However, DNA extraction from DBS is time-consuming, and elimination of PCR inhibitors from DBS is almost impossible. METHODS: Exon 7 of the two homologous SMA-related genes, survival motor neuron (SMN) 1 and SMN2, of five SMA patients and five controls were amplified by PCR with a punched-out circle of the DBS paper. Two types of DNA preparation methods were tested; DNA-extraction (extracted DNA was added in a PCR tube) and non-DNA-extraction (a punched-out DBS circle was placed in a PCR tube). As for the DNA polymerases, two different enzymes were compared; TaKaRa Ex Taq™ and KOD FX Neo™. To test the diagnostic quality of PCR products, RFLP (Restriction fragment length polymorphism) analysis with DraI digestion was performed, differentiating SMN1 and SMN2. RESULTS: In PCR using extracted DNA, sufficient amplification was achieved with TaKaRa Ex Taq™ and KOD FX Neo™, and there was no significant difference in amplification efficiency between them. In direct PCR with a punched-out DBS circle, sufficient amplification was achieved when KOD FX Neo™ polymerase was used, while there was no amplification with TaKaRa Ex Taq™. RFLP analysis of the direct PCR products with KOD FX Neo™ clearly separated SMN1 and SMN2 sequences and proved the presence of both of SMN1 and SMN2 in controls, and only SMN2 in SMA patients, suggesting that the direct PCR products with KOD FX Neo™ were of sufficient diagnostic quality for SMA testing. CONCLUSION: Direct PCR with DNA polymerases like KOD FX NeoTM has potential to be widely used in SMA newborn screening in the near future as it obviates the DNA extraction process from DBS and can precisely amplify the target sequences in spite of the presence of PCR inhibitors.

Spinal muscular atrophy carriers with two SMN1 copies.

BACKGROUND: Spinal muscular atrophy (SMA) is an autosomal recessive neuromuscular disorder. Over 95% of SMA patients have homozygous deletions of the SMA-causative gene, SMN1. Thus, SMA carriers are usually diagnosed based on SMN1 copy number, with one copy indicating SMA carrier status. However, two SMN1 copies do not always exclude carrier status. In this study, we identified SMA carriers with two SMN1 copies. SUBJECTS AND METHODS: From 33 families, 65 parents of genetically confirmed SMA patients were tested to determine SMA carrier status. Molecular genetic analyses, including multiplex ligation-dependent probe amplification (MLPA) assay, were performed using blood samples from family members. RESULTS: Of the 65 parents, three parents from three families had two SMN1 copies. Accordingly, the frequency of carriers with two SMN1 copies was 4.6%. Two of these families were further studied. Patient 1 was homozygous for SMN1 deletion. Patient 1's mother had two SMN1 copies on one chromosome, with deletion of SMN1 on the other chromosome ([2+0] genotype). Patient 1 inherited SMN1-deleted chromosomes from both parents. Patient 2 was compound heterozygous for two SMN1 mutations: whole-gene deletion and intragenic missense mutation, c.826T>C (p.Tyr276His). Patient 2's father had two SMN1 copies with the same intragenic mutation in one copy ([1+1d] genotype, d intragenic mutation). Patient 2 inherited the chromosome with an SMN1 mutation from the father and SMN1-deleted chromosome from the mother. CONCLUSION: SMA carriers with two SMN1 copies may be rare, but its possibility should be taken into consideration in carrier testing and counseling for SMA families or population-based carrier screening.

Genetic screening of spinal muscular atrophy using a real-time modified COP-PCR technique with dried blood-spot DNA.

BACKGROUND: Spinal muscular atrophy (SMA) is a common neuromuscular disorder caused by mutations in SMN1. More than 95% of SMA patients carry homozygous SMN1 deletion. SMA is the leading genetic cause of infant death, and has been considered an incurable disease. However, a recent clinical trial with an antisense oligonucleotide drug has shown encouraging clinical efficacy. Thus, early and accurate detection of SMN1 deletion may improve prognosis of many infantile SMA patients. METHODS: A total of 88 DNA samples (37 SMA patients, 12 carriers and 39 controls) from dried blood spots (DBS) on filter paper were analyzed. All participants had previously been screened for SMN genes by PCR restriction fragment length polymorphism (PCR-RFLP) using DNA extracted from freshly collected blood. DNA was extracted from DBS that had been stored at room temperature (20-25°C) for 1week to 5years. To ensure sufficient quality and quantity of DNA samples, target sequences were pre-amplified by conventional PCR. Real-time modified competitive oligonucleotide priming-PCR (mCOP-PCR) with the pre-amplified PCR products was performed for the gene-specific amplification of SMN1 and SMN2 exon 7. RESULTS: Compared with PCR-RFLP using DNA from freshly collected blood, results from real-time mCOP-PCR using DBS-DNA for detection of SMN1 exon 7 deletion showed a sensitivity of 1.00 (CI [0.87, 1.00])] and specificity of 1.00 (CI [0.90, 1.00]), respectively. CONCLUSION: We combined DNA extraction from DBS on filter paper, pre-amplification of target DNA, and real-time mCOP-PCR to specifically detect SMN1 and SMN2 genes, thereby establishing a rapid, accurate, and high-throughput system for detecting SMN1-deletion with practical applications for newborn screening.

SMA mutations in SMN Tudor and C-terminal domains destabilize the protein.

BACKGROUND AND PURPOSE: Most spinal muscular atrophy (SMA) patients are homozygous for survival of motor neuron 1 gene (SMN1) deletion. However, some SMA patients carry an intragenic SMN1 mutation. Such patients provide a clue to understanding the function of the SMN protein and the role of each domain of the protein. We previously identified mutations in the Tudor domain and C-terminal region of the SMN protein in three Japanese SMA patients. To clarify the effect of these mutations on protein stability, we conducted expression assays of SMN with mutated domains. PATIENTS AND METHODS: Patients A and B carried a mutation in SMN1 exon 3, which encodes a Tudor domain, c.275G>C (p.Trp92Ser). Patient C carried a mutation in SMN1 exon 6, which encodes a YG-box; c.819_820insT (p.Thr274Tyrfs). We constructed plasmid expression vectors containing wild-type and mutant SMN1 cDNAs. After transfection of HeLa cells with the expression plasmids, RNA and protein were isolated and analyzed by reverse-transcription PCR and western blot analysis. RESULTS: The abundance of wild-type and mutant SMN1 transcripts in HeLa cells was almost the same. However, western blot analysis showed lower levels of mutant SMN proteins compared with wild-type SMN. In mutant SMN proteins, it is noteworthy that the level of the p.Thr274Tyrfs mutant was much reduced compared with that of the p.Trp92Ser mutant. CONCLUSIONS: SMN mutations may affect the stability and levels of the protein.

New, Improved Version of the mCOP-PCR Screening System for Detection of Spinal Muscular Atrophy Gene (SMN1) Deletion.

BACKGROUND: Spinal muscular atrophy (SMA) is a frequent autosomal recessive disorder, characterized by lower motor neuron loss in the spinal cord. More than 95% of SMA patients show homozygous survival motor neuron 1 (SMN1) deletion. We previously developed a screening system for SMN1 deletion based on a modified competitive oligonucleotide priming-PCR (mCOP-PCR) technique. However, non-specific amplification products were observed with mCOP-PCR, which might lead to erroneous interpretation of the screening results. AIM: To establish an improved version of the mCOP-PCR screening system without non-specific amplification. METHODS: DNA samples were assayed using a new version of the mCOP-PCR screening system. DNA samples had already been genotyped by PCR-restriction fragment length polymorphism (PCR-RFLP), showing the presence or absence of SMN1 exon 7. The new mCOP-PCR method contained a targeted pre-amplification step of the region, including an SMN1-specific nucleotide, prior to the mCOP-PCR step. mCOP-PCR products were electrophoresed on agarose gels. RESULTS: No non-specific amplification products were detected in electrophoresis gels with the new mCOP-PCR screening system. CONCLUSION: An additional targeted pre-amplification step eliminated non-specific amplification from mCOP-PCR screening.

Gender Effects on the Clinical Phenotype in Japanese Patients with Spinal Muscular Atrophy.

BACKGROUND: Spinal muscular atrophy (SMA) is a neuromuscular disease caused by a mutation in SMN1. SMA is classified into three subtypes (types 1, 2, 3) based on achieved motor milestones. Although NAIP and SMN2 are widely accepted as SMA-modifying factors, gender-related modifying factors or gender effects on the clinical phenotype are still controversial. METHODS: A total of 122 Japanese patients with SMA, of which SMN1 was homozygously deleted, were analyzed from the perspective of the achieved motor milestone, NAIP status and SMN2 copy number. RESULTS: A predominance of male patients was observed in SMA type 3 (the walker group) without NAIP-deletion or with high SMN2 copy number (3 or 4 copies). CONCLUSION: We suggest the presence of gender-related modifiers on disease severity in SMA patients. The modifiers may contribute only in the presence of NAIP and a high copy number of SMN2.

SMA Diagnosis: Detection of SMN1 Deletion with Real-Time mCOP-PCR System Using Fresh Blood DNA.

BACKGROUND: Spinal muscular atrophy (SMA) is one of the most common autosomal recessive disorders. The symptoms are caused by defects of lower motor neurons in the spinal cord. More than 95% of SMA patients are homozygous for survival motor neuron 1 (SMN1) deletion. We previously developed a screening system for SMN1 deletion based on a modified competitive oligonucleotide priming-PCR (mCOP-PCR) technique using dried blood spot (DBS) on filter paper. This system is convenient for mass screening in the large population and/or first-tier diagnostic method of the patients in the remote areas. However, this system was still time-consuming and effort-taking, because it required pre-amplification procedure to avoid non-specific amplification and gel-electrophoresis to detect the presence or absence of SMN1 deletion. When the fresh blood samples are used instead of DBS, or when the gel-electrophoresis is replaced by real-time PCR, we may have a simpler and more rapid diagnostic method for SMA. AIM: To establish a simpler and more rapid diagnostic method of SMN1 deletion using fresh blood DNA. METHODS: DNA samples extracted from fresh blood and stored at 4 ℃ for 1 month. The samples were assayed using a real-time mCOP-PCR system without pre-amplification procedures. DNA samples had already been genotyped by PCR-restriction fragment length polymorphism (PCR-RFLP), showing the presence or absence of SMN1 exon 7. The DNA samples were directly subjected to the mCOP-PCR step. The amplification of mCOP-PCR was monitored in a real-time PCR apparatus. RESULTS: The genotyping results of the real-time mCOP-PCR system using fresh blood DNA were completely matched with those of PCR-RFLP. In this real-time mCOP-PCR system using fresh blood-DNA, it took only four hours from extraction of DNA to detection of the presence or absence of SMN1 deletion, while it took more than 12 hours in PCR-RFLP. CONCLUSION: Our real-time mCOP-PCR system using fresh blood DNA was rapid and accurate, suggesting it may be useful for the first-tier diagnostic method of SMA.

Blood supply during Japan's 1995 Hanshin-Awaji Earthquake.

On January 17, 1995, a magnitude 7.3 earthquake occurred in southern Hyogo Prefecture, a substantially urban area of Japan's main island, Honshu. Now known as the Hanshin-Awaji Earthquake, this disaster damaged or destroyed 639 686 houses and took 6434 lives. Within the disaster area, the Japanese Red Cross (JRC) Hyogo Blood Center had regional responsibilities for collecting, testing, processing, storing, and distributing blood components, including red blood cells (RBCs), fresh frozen plasma (FFP) and platelet concentrates (PLTs). Platelet shakers collapsed, forcing the discard of 103 PLT bags (1125 units) that could not be temperature-controlled or agitated. RBCs and FFP in refrigerated and frozen storage, respectively, remained in temperature control with the help of dry ice imported from non-affected areas. Local blood collection was suspended and replaced by products from other blood centers. Local demand for blood components decreased to 66% of comparable pre-quake demand. Emergent supplies rather than reserved supplies of blood components were markedly increased after the earthquake. Communication infrastructure damage prompted JRC Hyogo Blood Center to send blood delivery vehicles loaded with RBCs and FFP on a circuit of main hospitals in the affected area. Local blood donation and processing resumed 20 days after the quake. In retrospect, a nationally coordinated system of production and distribution demonstrated JRC's ability to meet transfusion demand after the 1995 Hanshin-Awaji Earthquake, and prompted changes in anticipation of subsequent disasters.

Mechanisms responsible for delayed and immediate hemolytic transfusion reactions in a patient with anti-E + Jk(b)+ Di(b) and anti-HLA alloantibodies.

Immediate hemolytic transfusion reactions (IHTR) occurred in the course of delayed hemolytic transfusion reactions (DHTR). An 84-year-old man had received a blood transfusion 20 years ago. Progressive anemia developed, because of continuous bleeding from a bladder tumor. He was transfused with concentrated red blood cells (CRC) which were Rh-E antigen negative, because he had anti-E antibodies (day 0). He received CRC on day 3, and underwent resection of bladder tumor on day 6. Although crossmatch-compatible CRCs were prepared for the operation, those were not required and were kept in a refrigerator in the ward. On day 9, when a CRC kept in the ward was transfused, he suddenly had a IHTR. In order to analyze a mechanism of IHTR, the anti-Jk(b) and anti-Di(b) antibodies, anti-HLA antibodies and the concentrations of inflammatory cytokines were measured in serum samples. The anti-Jk(b) and anti-Di(b) antibodies increased prior to IHTR experienced on day 9. The concentrations of IL-6 and IL-1beta increased from day 2, while the concentration of IL-8 increased from day 7. The anti-HLA class I antibody could be detected 2 days before IHTR. Thus, the anti-Jk(b) and anti-Di(b) antibodies induced the production of inflammatory cytokines and symptoms of DHTR and IHTR. The anti-HLA class I antibody could be produced in spite of using the filer for removing leukocytes, and may take part in the induction of IHTR. Further, blood products should be transfused soon after completing a crossmatch test in patients with anti-RBC alloantibodies.