Normalized transcranial Doppler velocities, stroke prevention and improved pulmonary function after stem cell transplantation in children with sickle cell anemia.

BACKGROUND: Abnormal transcranial Doppler velocities (TCD) indicate an increased risk of stroke in patients with sickle cell anemia (SCA) and require regular blood transfusions. Hematopoietic stem cell transplantation (HSCT) is under discussion as an alternative to chronic transfusion in these patients. PATIENTS AND METHODS: This retrospective analysis includes 9 patients with SCA undergoing HSCT at a single center in Germany. Special focus was given to the neurologic follow-up and to the results of TCD studies. RESULTS: High risk of stroke or previous stroke was an HSCT-indication in 8 of 9 patients, although most patients had more than one indication for HSCT. TCD was normalized in all 5 patients after HSCT in whom this test was available. None of the patients developed a stroke after HSCT. No further strokes occurred even in patients that experienced recurrent strokes during chronic transfusion before HSCT. 2 of the 9 patients received a 10/10 HLA-matched unrelated donor graft, the others matched related grafts.All patients were alive, free of SCA symptoms and transfusion-independent with stable chimerism 3-11 years after HSCT. Pulmonary function tests normalized in 1 patient with severe sickle cell lung disease. CONCLUSION: HSCT is able to prevent stroke in patients with SCA. Its perspectives and limitations should be discussed early during the treatment of a patient with complicated SCA.

Effects of platelet concentrate storage time reduction in patients after blood stem cell transplantation.

OBJECTIVE: To evaluate the clinical effect of platelet concentrate (PC) transfusions after PC storage time reduction to 4 days. PATIENTS AND METHODS: This was a single-centre cohort study comparing two 3-month periods of time, before and after the reduction of PC storage time from 5 to 4 days. Seventy-seven consecutive patients with PC transfusions were enrolled after blood stem cell transplantation. Corrected platelet count increment (CCI) on the morning after transfusion, time to next platelet transfusion, need for red blood cell (RBC) transfusion and clinical bleeding symptoms were compared. RESULTS: Platelet concentrate storage time was reduced between period 1 (storage for up to 5 days, median storage time 78 h, range 11-136 h) and period 2 (storage for up to 4 days, median storage time 53 h, range 11-112 h). Patients were comparable for age, weight, body surface area, underlying disorder, type of transplantation and transfused platelet dose. The CCI increased from a median of 4 (range 0-20) to 8 (0-68) × 10(9) /l per 10(11) platelets/m(2) (P < 0·0001). Time to next PC transfusion increased from 1·1 to 2·0 days (P < 0·0001). Any bleeding symptom was noted in 20 of 36 patients (56%) vs. 9/41 patients (22%, P < 0·01). Nose bleeds, haematuria and bleeding at more than one site were significantly reduced. Frequency of RBC transfusion within 5 days after PC transfusion was reduced from 74 to 58% (P < 0·0001). CONCLUSION: Platelet concentrate storage time shortening was associated with highly significant CCI increase, reduced RC needs and lower patient numbers with bleeding events.

Good manufacturing practice-compliant validation and preparation of BM cells for the therapy of acute myocardial infarction.

BACKGROUND: Intracoronary application of BM-derived cells for the treatment of acute myocardial infarction (AMI) is currently being studied intensively. Simultaneously, strict legal requirements surround the production of cells for clinical studies. Thus good manufacturing practice (GMP)-compliant collection and preparation of BM for patients with AMI was established by the Cytonet group. METHODS: As well as fulfillment of standard GMP requirements, including a manufacturing license, validation of the preparation process and the final product was performed. Whole blood (n=6) and BM (n=3) validation samples were processed under GMP conditions by gelafundin or hydroxyethylstarch sedimentation in order to reduce erythrocytes/platelets and volume and to achieve specifications defined in advance. Special attention was paid to the free potassium (<6 mmol/L), some rheologically relevant cellular characteristics (hematocrit <0.45, platelets <450 x 10(6)/mL) and the sterility of the final product. RESULTS: The data were reviewed and GMP compliance was confirmed by the German authorities (Paul-Ehrlich Institute). Forty-five BM cell preparations for clinical use were carried out following the validated methodology and standards. Additionally three selections of CD34+ BM cells for infusion were performed. All specification limits were met. Discussion In conclusion, preparation of BM cells for intracoronary application is feasible under GMP conditions. As the results of sterility testing may not be available at the time of intracoronary application, the highest possible standards to avoid bacterial and other contaminations have to be applied. The increased expense of the GMP-compliant process can be justified by higher safety for patients and better control of the final product.

Impact of tobacco smoking on platelet function in apheresis products in vitro.

BACKGROUND AND OBJECTIVES: The aim of this study was to analyse the platelet function, over a 5-day time-period, of apheresis-derived platelet concentrates obtained from smokers and non-smokers. MATERIALS AND METHODS: Smoker and non-smoker plateletpheresis products were investigated on days 1, 3 and 5 of storage. Receptor expression (as evaluated by flow cytometry) and the platelet aggregation response were measured. RESULTS: There was only a slight loss of platelet function in apheresis products from smokers compared to non-smokers. CONCLUSIONS: Smoking does not significantly change the quality of platelet preparations. The current practice, of not to exclude smokers from platelet donation, can be continued.

A comparative study of adverse reactions occurring after administration of glycosylated granulocyte colony stimulating factor and/or dexamethasone for mobilization of neutrophils in healthy donors.

Both granulocyte colony-stimulating factor (G-CSF) and dexamethasone (DXM) are used for neutrophil (PMN) mobilization and collection. This prospective study was aimed to evaluate and compare the rate, severity and clinical significance of adverse reactions of these drugs alone and in combination in healthy donors. PMN mobilization was carried out using dexamethasone alone (8 mg orally; n=25) or glycosylated G-CSF alone (Lenograstim, 5 microg/kg subcutaneously, n=24) or in combination (n=23) prior to a standard granulocyte apheresis on the Spectra cell separator. The number of PMNs counted in the mobilized peripheral blood of the donors was 7.0 (3.6-20.4) x10(9)/L (DXM), 25.2 (15.5-49.7) x10(9)/L (G-CSF), and 31.6 (20.0-43.0) x10(9)/L (G-CSF+DXM), corresponding to PMN apheresis yields of 13 (8-43) x10(9)/U, 56 (34-118) x10(9)/U, and 83 (33-117) x10(9)/U, respectively. The three groups had comparable percentages of donors with at least one adverse effect (ranging from 75 to 80%), but the G-CSF-containing regimens were generally more toxic, as was reflected by higher percentages of donors with moderate to severe adverse reactions and higher overall severity scores of 2.28 (G-CSF) and 2.08 (G-CSF+DXM) compared with 1.33 in the DXM group ( p

Collection of two consecutive neutrophil concentrates for transfusion from donors mobilized with glycosylated granulocyte-CSF plus dexamethasone.

BACKGROUND: The objective of this study was to establish a mobilization and apheresis regimen for collection of two consecutive polymorphonuclear neutrophil (PMN) concentrates from the same donor. STUDY DESIGN AND METHODS: In this prospective study, 111 healthy unrelated volunteers underwent either one (Group 1, n = 57) or two consecutive granulocyte apheresis procedure (Group 2, n = 54) using the a cell separator (Spectra). Both Group 1 and 2 donors were initially mobilized with glycosylated G-CSF 6.0 micro g per kg (range, 5.2-7.0 micro g/kg) subcutaneously plus oral dexa-methasone (DXM, 8 mg) and underwent granulocyte apheresis (GA-1) 16 hours (range, 13-18 hr) after initial G-CSF+DXM. Group 2 donors were remobilized with a second DXM dose of 8 mg (n = 13), 4 mg (n = 15), 1.5 mg (n = 13), or none (n = 13), and a second apheresis (GA-2) was run 40 hours (range, 37-42 hr) after G-CSF+DXM administration and 12 hours after remobilization with DXM alone. RESULTS: Based on equivalent median preapheresis WBC and PMN counts of around 35 x 10(9) WBCs per L and 33 x 10(9) PMNs per L after initial mobilization the GA-1 yields were 85 x 10(9) PMNs per U (range, 34-150) in Group 1 and 75 x 10(9) PMNs per U (range, 35-135) in Group 2 (p = 0.14, NS). In Group 2, median preapheresis values of 19.6 x 10(9) WBCs per L (range, 9.5-37.0) and 16.6 x 10(9) PMNs per L (range, 8.8-34.8) were measured after remobilization and GA-2 yields of 49 x 10(9) WBCs per U (range, 26-113) and 42 x 10(9) PMNs per U (range, 21-95) were obtained. Borderline statistical differences in the GA-2 yields were observed from the remobilized donors: 8 mg: 36 x 10(9) PMNs per U (range, 23-60); 4 mg: 47 x 10(9) PMNs per U (range, 21-56) (p

Equivalent mobilization and collection of granulocytes for transfusion after administration of glycosylated G-CSF (3 microg/kg) plus dexamethasone versus glycosylated G-CSF (12 microg/kg) alone.

BACKGROUND: The aim of this study was to find a regimen for mobilization and collection of granulocytes that combines low-dose G-CSF administration with satisfactory PMN mobilization and apheresis at a low rate of donor adverse reactions. STUDY DESIGN AND METHODS: In a prospective study, 52 healthy unrelated volunteers received a single subcutaneous injection of glycosylated G-CSF (Lenograstim Chugai-Pharma, Frankfurt, Germany) at medians of 3.1 (range, 2.4-3.6) microg per kg plus dexamethasone (8 mg orally; n = 29) or at 11.8 (7.1-18.5) microg of lenograstim per kg (p < or = 0.0001) without dexamethasone (n = 23) and underwent standard apheresis using the PMN program of a cell separator (Spectra, COBE [now Gambro] BCT). WBC and PMN mobilization results and apheresis yields were compared and the severity and clinical significance of donor adverse reactions was evaluated. RESULTS: For the low-dose G-CSF plus dexamethasone versus the high-dose G-CSF alone group, similar mobilization results were observed for WBCs with 31.3 (19.1-44.9) x 10(9) per L versus 27.5 (19.2-44.0) x 10(9) per L (p = 0.21, NS) and PMNs with 29.0 (17.6-42.2) x 10(9) per L versus 25.2 (16.2-39.0) x 10(9) per L (p = 0.08, NS). The PMN apheresis yields were equal with 70 (39-139) x 10(9) per unit with low-dose G-CSF versus 68 (33-120) x 10(9) per unit in the high-dose G-CSF group (p = 0.83, NS). Regarding donor adverse reactions, 7 out of 29 (24%) and 8 out of 23 donors (35%) reported moderate or severe symptoms. The character of these reactions was different; symptoms of greater clinical significance and a higher need for analgesics were observed in the high-dose G-CSF group. CONCLUSIONS: A Lenograstim dose of 3 microg per kg plus DXM assures effective PMN mobilization and acceptable apheresis components. The combination of glycosylated G-CSF with DXM allows a significant dose reduction in G-CSF for PMN mobilization and collection as compared with higher G-CSF doses alone. In the high-dose G-CSF mobilization group, adverse reactions were more severe and required more analgesics.

Inverse relationship between patient peripheral blood CD34+ cell counts and collection efficiency for CD34+ cells in two automated leukapheresis systems.

BACKGROUND: The purpose of this study was to analyze the CD34 cell collection efficiency (CE) of automated leukapheresis protocols of two blood cell separators (Spectra, COBE [AutoPBSC protocol] and AS104, Fresenius [PBSC-Lym, protocol]) for peripheral blood progenitor cell (PBPC) harvest in patients with malignant diseases. STUDY DESIGN AND METHODS: PBPCs were collected by the Spectra AutoPBSC protocol in 95 patients (123 collections) and the AS104 PBSC-Lym protocol in 87 patients (115 harvests). Patients underwent a median of one (range, 1-4) conventional-volume apheresis procedure of 10.8 L (9.0-13.9) to obtain a target cell dose of > or =2.5 x 10(6) CD34+ cells per kg. RESULTS: The median overall CD34 CE was significantly better on the AS104 than on the Spectra: 55.8 percent versus 42.4 percent (p = 0.000). This was also true below (59.2% vs. 50.1%; p = 0.022) and above (51.2% vs. 41.3%; p = 0.001) the preleukapheresis threshold of 40 CD34+ cells per microL needed to collect a single-apheresis autograft. However, at > or =40 circulating CD34+ cells per microL, both cell separators achieved the target of > or =2.5 x 10(6) CD34+ cells per kg. The CD34 CE dropped significantly, from 59.2 percent at <40 cells per microL to 51.2 percent at > or =40 cells per microL on the AS104 (p = 0.017) and from 50.1 percent to 41.3 percent on the Spectra (p = 0.033). CONCLUSION: Whereas the CD34 CE was significantly different with the AS104 and the Spectra, the CD34 CE of both machines correlated inversely with peripheral blood CD34+ cell counts, showing a significant decline with increasing numbers of circulating CD34+ cells. Nevertheless, at > or 40 preapheresis CD34+ cells per microL, sufficient hematopoietic autografts of > or =2.5 x 10(6) CD34+ cells per kg were harvested by a single conventional-volume (11 L) leukapheresis on both cell separators.

Automated collection of peripheral blood stem cells with the COBE spectra for autotransplantation.

BACKGROUND: A convenient, effective and safe peripheral blood stem cell (PBSC) apheresis procedure is desirable to cope with the increasing requirements for PBSC collections. We performed PBSC harvesting with the novel COBE Spectra AutoPBSC(TM) system using the default software configuration recommended by the manufacturer. We analyzed collection parameters and clinical efficiency of harvested autografts following high-dose chemotherapy (HDCT). PATIENTS AND METHODS: Eighty-one patients underwent 102 harvests after standard chemotherapy plus filgrastim (5-10 microg/kg/day) to obtain a target of >/=2.5 x 10(6) CD34+ cells/kg for autologous blood stem cell transplantation. Conventional-volume leukaphereses (median: 11 liters) were performed using the manufacturer's standard software default regarding inlet flow, harvest/chase volume (3/7 ml) and number of collection cycles. The ratio of ACD-A to whole blood was initially set at 1:12 (56 collections), later at 1:10 (46 aphereses). RESULTS: With respect to preapheresis counts of 93 (9-876) CD34+ cells/microl, 69 patients (85.2%) achieved >/=2.5 x 10(6) CD34+ cells/kg by the first apheresis. PBSC products contained medians of 5.0 x 10(6) (0.7-77.3) CD34+ cells/kg and 13.8 x 10(4) (2.3-105.0) CFU-GM/kg. A preapheresis count of >/=40 CD34+ cells/microl predicted a single-apheresis yield of >/=2.5 x 10(6) CD34+ cells/kg. Apheresis products showed a high mononuclear cell (MNC) purity of >/=89%. The median overall collection efficiency of CD34+ cells (CD34-CE) was 42.6% (12.2-87.4). The CD34-CE decreased significantly with increasing numbers of circulating CD34+ cells: 52.5% at CD34+ cells <40/microl versus 41.0% at CD34+ cells >/=40/microl (p 0.5 x 10(3)/microl, 10 (8-13) days for WBC >1.0 x 10(3)/microl and 11 (8-17) days for platelets >20 x 10(3)/microl. CONCLUSIONS: As a result of efficient PBSC mobilization, a single conventional-volume leukapheresis with the COBE Spectra AutoPBSC system resulted in hematopoietic autografts with >/=2.5 x 10(6) CD34+ cells/kg in 85% of patients. Following the standard PBSC apheresis recommendations of the manufacturer, the AutoPBSC system assures PBSC products with a high MNC purity and a moderate CD34-CE that declines significantly at increasing levels of circulating CD34+ cells. Leukaphereses performed at an ACD-A to whole blood ratio of 1:10 should run without coagulation problems.

Phase I clinical study applying autologous immunological effector cells transfected with the interleukin-2 gene in patients with metastatic renal cancer, colorectal cancer and lymphoma.

Natural killer-like T lymphocytes termed cytokine-induced killer (CIK) cells have been shown to eradicate established tumours in a severe combined immune deficient (SCID) mouse/human lymphoma model. Recently, we demonstrated that CIK cells transfected with cytokine genes possess an improved proliferation rate and a significantly higher cytotoxic activity as compared to non-transfected cells. Here, in a phase I clinical protocol, autologous CIK cells were generated from peripheral blood obtained by leukapheresis in patients with metastatic renal cell carcinoma, colorectal carcinoma and lymphoma. CIK cells were transfected with a plasmid containing the interleukin-2 (IL-2) gene via electroporation. Transfected cells generated IL-2 in the range of 330-1800 pg 10(-6) cells 24 h(-1) with a mean of 836 pg 10(-6) cells 24 h(-1). Ten patients received 1-5 intravenous infusions of IL-2-transfected CIK cells; five infusions with transfected CIK cells were given. In addition, the same patients received five infusions with untransfected CIK cells for control reasons. In three patients, WHO grade 2 fever was observed. Based on polymerase chain reaction of peripheral blood transfected cells could be detected for up to 2 weeks after infusion. There was a significant increase in serum levels of interferon gamma (IFN-gamma), granulocyte-macrophage colony-stimulating factor (GM-CSF) and transforming growth factor beta (TGF-beta) during treatment. Interestingly, there was also an increase in CD3+ lymphocytes in the blood of patients during therapy. In accordance, a partial increase in cytotoxic activity in peripheral blood lymphocytes (PBLs) was documented when patient samples before and after therapy were compared. Concerning clinical outcome, six patients remained in progressive disease, three patients showed no change by treatment, and one patient with lymphoma developed a complete response. In conclusion, we were able to demonstrate that CIK cells transfected with the IL-2 gene can be administered without major side-effects and are promising for future therapeutic trials.

Occurrence of a novel DNA virus (TTV) infection in patients with liver diseases and its frequency in blood donors.

A novel DNA virus (TTV) was identified recently in Japanese patients with posttransfusion hepatitis non-A-E and has been implicated as a cause of acute and chronic liver diseases of unknown etiology in some patients. The frequency of TTV infections was investigated in 284 blood donors, 105 patients with different liver disorders before and after liver transplantation (OLT), as well as in 64 patients with chronic hepatitis C who received antiviral therapy. TTV infections were found more frequently by nested-PCR in patients with liver disorders (15%) as compared to blood donors (7%). TTV occurred independently of the aetiology of the liver disease (e.g., cryptogenic cirrhosis [12.5%], alcoholic cirrhosis [16%], fulminant hepatic failure non-A-E [35%], and chronic hepatitis C [12.5%]; p=n.s.). After OLT, a high rate of TTV de novo infections (44%) was observed. However, TTV viremia after OLT (in 56 out of the 105 patients) was not associated with graft hepatitis. Analysis of patients with chronic hepatitis C coinfected with TTV who have been treated with interferon alpha alone or in combination with ribavirin revealed that TTV is an interferon-sensitive virus. Phylogenetic analysis of TTV sequences suggest that at least four different genotypes and several subtypes exist in Germany. In conclusion, the high prevalence of TTV infections observed in patients with parenteral risk factors is an argument in favour of transmission of the virus via blood and blood products. A relevant hepatitis-inducing capacity of TTV, however, seems unlikely, considering the observation that in the majority of patients, TTV infection after OLT was not accompanied by graft hepatitis.

Epidemiological and clinical aspects of hepatitis G virus infection in blood donors and immunocompromised recipients of HGV-contaminated blood.

BACKGROUND AND OBJECTIVES: The infectiousness and clinical relevance of the newly discovered blood-borne Flaviviridae-like agent, termed hepatitis G virus (HGV), are not well understood. MATERIALS AND METHODS: Twenty-three transfusion recipients of two HGV-affected long-term blood donors were studied for HGV genome and antibodies to the putative envelope 2 glycoprotein (anti-E2) of HGV. Nine recipients had nonhematological disorders and 14 suffered from severe hematological diseases and 7 of them received allogeneic bone marrow or blood stem cell transplantation. The molecular epidemiology of the observed HGV infection was studied by direct sequencing of parts of the 5'-noncoding region, NS3, and NS5 region of HGV in the 2 long-term donors and in their 6 recipients who became HGV RNA positive. Additionally, 549 individuals-homologous (n = 254) and autologous blood donors (n = 202), and medical staff (n = 89)--were investigated for the presence of HGV RNA. RESULTS: HGV RNA in serum was found in 15 of the 23 (65%) transfusion recipients with known exposure of HGV-contaminated blood. Seven of the remaining 8 recipients showed only an anti-E2 response, indicating previous HGV infection with spontaneous clearance of the virus. In one recipient neither HGV RNA nor anti-E2 could be detected. Molecular evidence for HGV transmission by the 2 donors was found in 3 of the 6 recipients studied. The alanine aminotransferase levels were not significantly different in the HGV RNA positive and negative recipients, and none of the 23 recipients developed posttransfusion hepatitis. Persistent HGV infection was observed especially in recipients with severe hematological disorders or in those in whom intensive immunosuppressive treatment was necessary. Of the 549 individuals studied, 10 (1.8%) were healthy carriers of HGV RNA. CONCLUSION: The persistence of transfusion-acquired HGV infection is not associated with acute or chronic hepatitis, but may be influenced by the recipient's underlying disease.

Bacterial contamination of autologous bone marrow: reinfusion of culture-positive grafts does not result in clinical sequelae during the posttransplantation course.

OBJECTIVES: Microbiological cultures and posttransplantation course were analyzed in order to investigate the incidence and clinical significance of bacterial contamination of autologous bone marrow (BM) grafts. METHODS: Cultures were obtained from BM after collection, BM concentrate after processing, contaminated/cryopreserved BM at thawing, and from peripheral blood (PB) following autologous BM transplantation (ABMT). The posttransplantation course of patients grafted with culture-positive BM was recorded and compared with patients who underwent ABMT with noncontaminated BM grafts. RESULTS: In 239 BM grafts processed, the incidence of microbiological contamination was 26.4% (n = 63). Fifty marrow grafts were contaminated by bacteria from the skin flora: coagulase-negative Staphylococcus (CNSC), Propionibacterium, and Corynebacterium species (79%). Thirty-eight patients underwent ABMT (day 0) with cryopreserved culture-positive BM, and 32 patients were evaluable for microbiological cultures at thawing: in 10 of 32 BM grafts CNSC was found prior to reinfusion. Following ABMT, PB cultures revealed CNSC in 5 of 38 patients between days +4 and +12. However, the late occurrence of positive PB cultures after BM reinfusion made a relationship between BM CNSC and PB CNSC unlikely. In 33 of 38 patients, no graft-contaminating bacteria were detected in PB. Comparison of the posttransplantation course of patients who received contaminated BM with that of patients grafted with noncontaminated BM showed no significant differences concerning time to engraftment, febrile days, and days on antibiotics. CONCLUSION: (1) Collection and/or ex vivo processing can result in microbiological contamination of BM grafts predominantly with bacteria from the skin flora, and (2) only CNSC can be cultured at thawing from previously contaminated/cryopreserved BM. Since patients undergoing ABMT usually receive oral antibiotics from beginning of the conditioning regimen which are active against CNSC, no further administration of antibiotics is recommended for the reinfusion of bacterially contaminated BM grafts.

Preparation of autologous bone marrow grafts for cryopreservation using the AS104 cell separator.

We evaluated the AS104 cell separator (Fresenius AG, Bad Homburg, Germany) for ex vivo processing of bone marrow (BM) grafts of 43 patients suffering from germ cell cancer (GCC, n = 22), acute lymphocytic leukemia (ALL, n = 13) and malignant lymphoma (ML, n = 8). Recoveries of total nucleated cells (TNC), mononuclear cells (MNC) and colony-forming units granulocyte-macrophage (CFU-GM) were determined in the BM concentrates prepared for cryopreservation. Hematopoietic reconstitution was analyzed in patients who underwent autologous transplantation following high-dose radio-/chemotherapy (HDRCT). Processing of the BM suspension with a median volume of 1,013 ml (range: 422-1,574) resulted in 156 ml (80-186) within 50-120 min (median: 90). In the BM concentrates, medians of 28.6% TNC (10.6-69.6), 37.9% MNC (22.3-86.4), and 52.4% CFU-GM (20.8-96.4) were recovered. Twenty-six patients underwent HDRCT with reinfusion of autologous BM and were evaluable for engraftment. They received a median of 0.8 x 10(8) MNC/kg (0.3-1.6 x 10(8)) and 2.2 x 10(4) CFU-GM/kg (0.6-12.8 x 10(4) for hematopoietic rescue. Engraftment with neutrophils > 500/microliter occurred in a median time of 12 days (8-33) in all patients. We conclude that ex vivo processing of autologous BM with median recovery rates of 37.9% for MNC, and 52.4% for CFU-GM, results in a cell population that can rescue patients from HDRCT. The described technique is convenient, time-efficient, and provides reliable results in preparing BM autografts for cryopreservation.

Peripheral blood progenitor cell collection during hematopoietic recovery following autologous blood progenitor cell transplantation.

BACKGROUND AND OBJECTIVES: Peripheral blood progenitor cells (PBPC) are increasingly used for autologous transplantation after high-dose radio/chemotherapy in patients suffering from cancer. PBPC are usually collected after mobilization with conventional-dose chemotherapy plus growth factor. However, it is conceivable to perform leukapheresis for the second autograft during recovery of hematopoiesis after the first course of HDCT/ABPCT. MATERIALS AND METHODS: We treated two patients this way. In the first, with germ cell cancer, six 12-liter leukaphereses yielded 1.8 x 10(6) CD34+ cells/kg after mobilization with cis-platinum, etoposide and ifosfamide (PEI) plus granulocyte colony-stimulating factor (G-CSF). The second patient, with relapsed Hodgkin's disease, underwent PBPC collection after treatment with dexamethasone, carmustine, etoposide, cytarabine and melphalan (DexaBEAM) plus G-CSF. Due to excellent mobilization, 8.5 x 10(6) CD34+ cells/kg were collected by one 12-liter leukapheresis. Both patients then underwent PBPC collection during hematopoietic recovery following HDCT and ABPCT. RESULTS: In patient 1, following HDCT and ABPCT, three 12-liter aphereses resulted in 0.7 x 10(6) CD34+ cells/kg. In patient 2, also after HDCT and ABPCT, a second autograft with 3.2 x 10(6) CD34+ cells/kg was harvested by a single 10-liter apheresis. No adverse effects were seen in either patient during apheresis following ABPCT. To our knowledge this is the first report dealing with PBCT collection during hematopoietic recovery following HDCT and ABPCT. CONCLUSIONS: (1) PBPC harvesting is feasible and well tolerated in this setting. (2) In appropriate patients with efficient PBPC mobilization after conventional-dose chemotherapy, a further PBPC autograft can be collected during recovery of hematopoiesis after ABPCT, serving as a rescue for a second course of HDCT.

Responsiveness to interferon alpha treatment in patients with chronic hepatitis C coinfected with hepatitis G virus.

BACKGROUND/AIMS: Patients with chronic hepatitis C are often coinfected with the new identified Flaviviridae-like agent, termed hepatitis G virus (HGV). The aim of the study was to investigate the responsiveness of hepatitis G virus to interferon alpha and to evaluate whether a hepatitis G virus coinfection negatively influences the outcome of treatment in chronic hepatitis C. METHODS: One hundred and fifteen patients with histologically proven chronic hepatitis C were treated with interferon alpha and investigated for the presence of hepatitis G virus coinfection by nested polymerase chain reaction with primers from the helicase region of hepatitis G virus. All patients received at least 3 MU (range 3-6) interferon alpha thrice weekly for at least 6 months (mean 8, range 6-12). Polymerase chain reaction products of seven pre- and post-treatment hepatitis G virus positive patients were directly sequenced for identification of sequence variability during the follow-up. RESULTS: Eighteen (16%) patients were coinfected with hepatitis G virus. Although nine (50%) of these patients became HGV RNA negative during interferon alpha therapy, only three patients (17%) remained HGV RNA negative at the end of follow-up (mean 24 months). The rate of sustained response of chronic hepatitis C was not significantly different between patients with hepatitis C virus infection and HCV/HGV coinfection (19% vs 28%). Severity of liver disease as determined by alanine aminotransferase levels, histology and hepatitis C virus viremia was not significantly different in patients with hepatitis C virus or HCV/HGV coinfection. Sequence analysis of the helicase region revealed that our isolates all belonged to the hepatitis G virus and not to the GBV-C like genotype. No amino acid exchanges during the observation period of up to 48 months were observed, indicating that this region is highly conserved. CONCLUSIONS: The responsiveness of hepatitis G virus to interferon alpha in chronic HCV/HGV coinfected patients is similar to that observed in chronic hepatitis C. Hepatitis G virus coinfection seems not to interfere with the efficacy of interferon alpha treatment in patients with chronic hepatitis C.