A meta-analysis on the effects of incarceration-based opioid substitution treatment.

Objective: Opioid substitution treatment (OST) is a common treatment for individuals who use opioids; however, empirical evidence on the effects of OST during incarceration is scarce. Our aim was to conduct a meta-analysis on the effects of incarceration-based OST on substance use, treatment engagement post-release and re-incarceration. Method: We searched for studies on individuals who were incarcerated and treated with OST, compared to a comparison group. Studies were only included if they reported data post-release. Results: N = 15 studies met the inclusion criteria. We found less opioid use, less other drug use, higher treatment engagement post-release and less re-incarceration among treated individuals compared to the comparison group. Moderator analyses showed some influence of length of follow-up period and study quality. Conclusions: Incarceration-based OST reduces drug use, re-incarceration and leads to higher treatment engagement after release. More research is needed on the effects of incarceration-based OST on secondary outcomes (e.g. health and social integration) and on factors that moderate these effects.

The novel tribody [(CD20)(2)xCD16] efficiently triggers effector cell-mediated lysis of malignant B cells.

Bispecific antibodies (bsab) offer a promising approach for optimizing antibody-based therapies. In the present study, [(CD20)(2)xCD16], a recombinant CD20- and CD16-directed bsab in the tribody format, was designed to optimize recruitment of FcγRIII (CD16)-positive effector cells. [(CD20)(2)xCD16] retained the antigen specificities of the parental monoclonal antibodies and binding to FcγRIIIa was not compromised by the F/V polymorphism at amino-acid position 158. [(CD20)(2)xCD16] mediated potent lysis of lymphoma cell lines and freshly isolated tumor cells from patients, even at low picomolar concentrations (∼10 pM). Irrespective of the CD16a allotype, potency as well as efficacy of lysis obtained with the tribody was significantly higher than lysis triggered by rituximab. Tumor cell killing also occurred when autologous NK cells were used as effector cells. Compared with rituximab, the tribody demonstrated depletion of autologous B cells in ex vivo whole blood assays at 100-fold lower antibody concentration. In mice with a reconstituted humanized hematopoietic system, established by transplantation of human CD34-positive cord blood cells, this novel tribody significantly depleted autologous human B cells. Thus, tribodies such as [(CD20)(2)xCD16], recruiting CD16-positive effector cells, may represent promising candidates for clinical development.

Serum-free production and purification of chimeric IgA antibodies.

Natural IgA antibodies are abundantly produced in vivo to protect serosal surfaces from invading infectious organisms. However, the immunotherapeutic potential of IgA has hardly been explored, although there is evidence that recombinant IgA antibodies may broaden the armentarium to combat certain infectious or malignant diseases. One of the limitations for exploring IgA's therapeutic activity has been the difficulty to obtain enough recombinant material with desired specificity for in vivo studies. Here, we describe the production and purification of monomeric recombinant IgA1 and IgA2 antibodies under serum-free conditions. For antibody production, suspension adapted CHO-K1 cells and a glutamine synthetase selection vector were used, which resulted in specific production rates of up to 2.2 pg/cell/day. Purities of >95% of monomeric antibodies were obtained by a combination of affinity chromatography-using an anti-kappa-light chain matrix-and size exclusion chromatography. Purified antibodies displayed the expected biochemical characteristics and were functionally fully active. Importantly, all required reagents and methods are commercially available and not dependent on the specificity of the desired antibody. In addition, all employed technologies and methodologies are similar to those used for the production of therapeutic IgG antibodies - thus allowing further up-scaling and streamlining according to existing antibody production technologies. In conclusion, the described methodology may assist in the development of recombinant IgA antibodies for therapeutic applications.

Screening, identification, and functional analysis of three novel missense mutations in the TRADD gene in children with ALL and ALPS.

BACKGROUND: Apoptosis is known to be a crucial process involved in embryogenesis, development and homeostasis of the immune system. Impaired apoptosis causes dysfunction of lymphocyte homeostasis, growth advantage of tumor cells as well as resistance to current treatment protocols. To investigate the role of the apoptosis adaptor molecules TRADD and FADD in the development of hematological diseases, patient samples were screened for mutations in these genes. PROCEDURE: Genomic DNA from 51 children suffering from B-lineage-ALL (n = 17), T-lineage-ALL (n = 24), ALPS Type Ia (n = 3) and ALPS Type III (n = 7) were analyzed. Genomic DNA from 50 unrelated donors without hematological diseases served as controls. Identified mutations were cloned and their influence on cell viability and NFkappaB activation was analyzed by flow cytometry and luciferase assay, respectively. RESULTS: In the FADD gene no genetic alteration could be detected. However, three novel missense mutations in the TRADD gene could be detected. They are located within a region of TRADD known to exert mainly anti-apoptotic effects for example through the activation of the NFkappaB pathway. Functional analysis of cells overexpressing mutant TRADD cDNA demonstrated a reduced NFkappaB activity and consequently increased cell death compared to wild-type TRADD. CONCLUSION: Mutations in the TRADD gene may contribute to the development of different hematological diseases. The identified mutations demonstrate a putative impact on TRADD signaling and cell survival but may not mainly explain the pathology of the diseases investigated.

Prevalence and specificity of immunoglobulin G and immunoglobulin A non-complement-binding anti-HLA alloantibodies in retransplant candidates.

The role of complement-binding donor-directed anti-human leukocyte antigen (HLA) antibodies in graft rejection is well established, whereas the prevalence and relevance of non-complement-binding (NCB) anti-HLA antibodies are less well defined. The aim of our study was to establish a sensitive and reliable test system for the detection and the specification of these NCB anti-HLA antibodies. Sera from 60 patients awaiting retransplantation were analysed for the presence of anti-HLA class I alloantibodies with complement-dependent cytotoxicity (CDC) tests. Immunoglobulin (Ig)G(all) anti-HLA class I and class II alloantibodies were differentiated on generic level by plate-based solid phase enzyme-linked immunosorbent assay. Subsequently, a modified bead-based (Luminex) assay was applied, allowing the investigation of IgG(2/4) NCB isotypes as well as IgA(1/2). The anti-HLA specificities of the NCB alloantibodies were determined and compared with known mismatches from previous transplants. Seventeen of the 60 sera (28%) were positive in the CDC increasing to 26 of 60 (43%) in the class I and 33 of 60 (55%) in the class II plate-based assay. Using the modified bead-based system 24 of 60 sera (40%) contained NCB IgG(2/4), which were mostly donor specific. In addition, a high prevalence of NCB IgA antibodies was detected (26 of 60 sera), which occurred independently of IgG(2/4) NCB, and half of which were donor specific. NCB anti-HLA alloantibodies, including the IgA isotype, can reliably be detected using the modified bead-based test system. These NCB alloantibodies had a high prevalence in retransplant candidates and were mostly donor specific.

CYP3A5 genotype markedly influences the pharmacokinetics of tacrolimus and sirolimus in kidney transplant recipients.

It is currently not clear whether the concentration-time curves of the immunosuppressants differ with respect to the CYP3A5, MDR1, or MRP2 genotype in dose-adapted stable kidney transplant patients. Dose/trough concentration ratios were obtained in 134 tacrolimus and 20 sirolimus-treated patients, and plasma concentration-time profiles were obtained from 16 (tacrolimus) and 10 (sirolimus) patients. Genotyping was carried out for CYP3A5 6986A>G; ABCB1 2677G>T/A, 3435C>T and ABCC2 -24C>T; 1249G>A; 3972C>T. Dose/trough concentration ratios were 0.67+/-0.3 and 1.36+/-0.73 x 10(3) l (P<0.00001) for tacrolimus and 0.42+/-0.17 and 0.84+/-0.46 x 10(3) l (P=0.18) for sirolimus in CYP3A5 non-expressors and expressors. The unadjusted tacrolimus area under curve (AUC)(0-12) was 106.8+/-17.5 ng/ml x h compared with 133.3+/-42.2 ng/ml x h (P=0.37) without affecting serum creatinine. Mean unadjusted AUC(0-24) of sirolimus did not differ significantly either. Therefore, CYP3A5 expressor status and not transporter variants is a main determinant of oral clearance, particularly for tacrolimus. Dose adaptation according to trough levels, however, appears to be sufficient to maintain similar concentration-time profiles.

IgA antibodies for cancer therapy.

Antibody-based therapy is a new treatment option for selected tumor patients. Today, human IgG(1) is the most widely used isotype, because it effectively activates human complement, recruits NK cells for ADCC, and has an extended plasma half life. In recent work, however, neutrophils--the most populous cytotoxic cells in humans--were more effectively recruited by human IgA than by IgG antibodies. IgA antibodies may have the additional advantages of forming natural dimers with improved signaling capacity on tumor cells, and being actively transported into mucosal secretions with the potential for improved targeting of certain carcinomas from the luminal surface.

Mechanisms of G-CSF- or GM-CSF-stimulated tumor cell killing by Fc receptor-directed bispecific antibodies.

Studies with gene-modified mice have recently reinforced the importance of Fc receptor-mediated effector mechanisms for the therapeutic efficacy of rituxan and herceptin - two clinically approved antibodies for the treatment of tumor patients. We investigated Fc receptor-dependent tumor cell killing by mononuclear and granulocytic effector cells - comparing human IgG1 antibodies against CD20 or HER-2/neu with their respective FcgammaRI (CD64)-, FcgammaRIII (CD16)-, or FcalphaRI (CD89)-directed bispecific derivatives. With blood from healthy donors as effector source, human IgG1 and FcgammaRIII (CD16)-directed bispecific antibodies proved most effective in recruiting mononuclear effector cells, whereas tumor cell killing by granulocytes was most potently triggered by FcalphaRI-directed bispecific constructs. Granulocyte-mediated tumor cell lysis was significantly enhanced when blood from G-CSF- or GM-CSF-treated patients was investigated. Interestingly, however, both myeloid growth factors improved effector cell recruitment by different mechanisms, which were furthermore dependent on the tumor target antigen, and on the selected cytotoxic Fc receptor.

Triggering Fc alpha-receptor I (CD89) recruits neutrophils as effector cells for CD20-directed antibody therapy.

CD20 Abs induce clinical responses in lymphoma patients, but there are considerable differences between individual patients. In (51)Cr release assays with whole blood as effector source, RAJI cells were effectively killed by a mouse/human chimeric IgG1 construct of CD20 Ab 1F5, whereas ARH-77 proved resistant to killing by this Ab. When whole blood was fractionated into plasma, mononuclear cells, or granulocytic effector cells, RAJI cells were effectively killed in the presence of complement-containing plasma, whereas the mature B cell line ARH-77 proved complement resistant. However, with a bispecific Ab (BsAb) against the myeloid receptor for IgA (CD89; FcalphaRI) and CD20, a broad range of B cell lines were effectively killed. FcalphaRI is expressed on monocytes/macrophages, neutrophils, and eosinophils. As the numbers of these effector cells and their functional activity can be enhanced by application of G-CSF or GM-CSF, lysis via (FcalphaRI x CD20) BsAb was significantly enhanced in blood from patients during therapy with these myeloid growth factors. Interestingly, the major effector cell population for this BsAb were polymorphonuclear neutrophils, which proved ineffective in killing malignant B cells with murine, chimeric IgG1, or FcgammaRI- or FcgammaRIII-directed BsAbs against CD20. Experiments with blood from human FcalphaRI/FcgammaRI double-transgenic mice showed corresponding results, allowing the establishment of relevant syngenic animal models in these mice. In conclusion, the combination of myeloid growth factors and an (FcalphaRI x CD20) BsAb may represent a promising approach to improve effector cell recruitment for CD20-directed lymphoma therapy.

Evaluating antibodies for their capacity to induce cell-mediated lysis of malignant B cells.

Promising results from clinical trials have led to renewed interest in effector mechanisms operating in antibody-based therapy of leukemia and lymphoma. We tested a panel of B-cell antibodies from the Sixth Human Leukocyte Differentiation Antigen workshop for their capacity to mediate antibody-dependent cellular cytotoxicity, often considered to be one of the most potent effector mechanisms in vivo. As effector cells, mononuclear cells and polymorphonuclear (PMN) cells from healthy donors were compared with Fc gammaRI (CD64)-expressing PMN cells from patients receiving granulocyte colony-stimulating factor (G-CSF) treatment. Of the 29 IgG workshop antibodies binding most strongly to the tested malignant human B-cell lines, only 3 consistently induced target cell lysis. These three antibodies were determined to be HLA DR reactive. Experiments with a panel of HLA class II antibodies showed the involvement of individual Fc gamma receptors on effector cells to be strongly dependent on the antibody isotype. We then compared killing mediated by chimeric IgG1 antibodies with that from Fc gammaRI-directed bispecific antibodies, targeting classical HLA class II, or the Lym-1 and Lym-2 antigens. The latter two are variant forms of HLA class II, which are highly expressed on the surface of malignant B cells but which are found only at low levels in normal cells. With blood from G-CSF-treated donors, bispecific antibodies showed enhanced killing compared to their chimeric IgG1 derivatives, because they were more effective in recruiting Fc gammaRI-expressing PMN cells. G-CSF- and Fc gammaRI-directed bispecific antibodies to HLA class II, therefore, seem to be an attractive combination for lymphoma therapy.

Generation of HER-2/neu-specific cytotoxic neutrophils in vivo: efficient arming of neutrophils by combined administration of granulocyte colony-stimulating factor and Fcgamma receptor I bispecific antibodies.

Abs are able to induce inflammatory antitumor responses by recruiting IgG Fc receptor (FcgammaR)-bearing cytotoxic effector cells. We recently described the capacity of the high affinity FcgammaRI (CD64) to trigger cytotoxic activity of neutrophils (PMN) during granulocyte CSF (G-CSF) treatment. To take advantage of FcgammaRI as a cytotoxic trigger molecule on PMN, two Ab constructs were prepared. We show that a chimeric human IgG1 Ab (Ch520C9) and an anti-FcgammaRI bispecific Ab (BsAb; 22x520C9), both directed to the proto-oncogene product HER-2/neu, interact with FcgammaRI. In addition, both Ab constructs mediate enhanced lysis of HER-2/neu-expressing tumor cells by G-CSF-primed PMN. However, engagement of FcgammaRI by Ch520C9 was inhibited by human serum IgG, thereby abrogating the enhanced Ch520C9-mediated cytotoxicity. BsAb 22x520C9, which binds FcgammaRI outside the ligand binding domain, effectively recruits the cytotoxic potential of FcgammaRI on G-CSF-primed PMN regardless of the presence of human serum. These results indicate that under physiologic conditions, serum IgG impairs activation of FcgammaRI-mediated cytotoxicity by conventional antitumor Abs. The IgG blockade can be circumvented with anti-FcgammaRI BsAbs. Using human FcgammaRI transgenic mice we demonstrate that BsAb 22x520C9 is able to engage FcgammaRI in vivo. BsAb 22x520C9 injected i.v. was readily detected on circulating PMN of G-CSF-treated transgenic animals. In addition, we showed that PMN remain "armed" with BsAb 22x520C9 during migration to inflammatory sites, and that after isolation such PMN specifically lyse HER-2/neu-expressing tumor cells. These results point to the possibility of targeting anti-FcgammaRI BsAbs to G-CSF-primed PMN in vivo, endowing them with specific anti-tumor activity.