A retrospective study of lower limb cellulitis in a regional hospital in Ghana

Background: Cellulitis is a non-necrotizing inflammation of the dermis of skin and subcutaneous tissues. Lower limb cellulitis is a common cause of hospitalization in Ghana but scarcely reported. Objective: To document management and outcomes of lower limb cellulitis at the Ashanti Regional Hospital in Ghana. Materials and Methods: Retrospective review of patients admitted to the Ashanti Regional Hospital with a diagnosis of lower limb cellulitis from November 2016 to October 2018. We reviewed patients' clinical records for data on patient demographics, risk factors, clinical presentation, treatment modality and outcome of cellulitis. A p-value of less than 0.05 was considered to be statistically significant. Results: Eighty two (82) patients with lower limb cellulitis were admitted over the study period. There were 47 (57.3%) females and 35 (42.7%) males. The mean age of patients was 38.8 years (standard deviation 21.6065). Among females, the majority, 10 (21.3%) were in the 6th decade whilst the majority, 9 (25.7%) of males were in the 4th decade. All the patients presented with swelling of the lower limb involving the left lower limb in 38(46.3%) and right in 44(53.7%) cases. The leg was the most common location involved 60 (73%). The mean duration of swelling prior to admission was 5. 2 days (SD 3.196). Antibiotics treatment resulted in complete resolution in 29 (35.4%) cases and complications in 53 (54.5%), cases requiring surgical treatment in 31(58.5%) patients. Conclusion: Lower limb cellulitis had a high complication rate influenced by duration of symptoms prior to hospitalization and antibiotic therapy

Using metabolomics to dissect host-parasite interactions.

Protozoan parasites have evolved diverse growth and metabolic strategies for surviving and proliferating within different extracellular and intracellular niches in their mammalian hosts. Metabolomic approaches, including high coverage metabolite profiling and (13)C/(2)H-stable isotope labeling, are increasingly being used to identify parasite metabolic pathways that are important for survival and replication in vivo. These approaches are highlighting new links between parasite carbon metabolism and the ability of different parasite stages to colonize specific niches or host cell types. They have also revealed novel metabolic regulatory mechanisms that are important for homeostasis and survival in potentially nutrient variable environments. These studies highlight the importance of parasite and host metabolism as determinants of host-parasite interactions.

Guiding postablative lymphocyte reconstitution as a route toward transplantation tolerance.

Anti-lymphocyte-depleting antibodies have increasingly been utilized in the clinic as induction therapy aiming to improve transplantation outcomes by reducing the need for long-term immunosuppression. However, maintenance immunosuppression is still required as lymphocyte reconstitution through homeostatic proliferation, partially driven by IL-7, continues to replenish tolerance-refractory immune cells capable of rejection. In murine models of MHC mismatched skin grafting, we investigated whether it is feasible to control the lymphocyte reconstitution process to delay rejection and favor tolerance processes. We found that a short course of anti-IL-7 receptor blocking antibody following T cell depletion, combined with the mammalian target of rapamycin inhibitor Rapamycin, could significantly delay graft rejection in one mouse strain, and achieve transplantation tolerance in another. The combination treatment was found to delay T cell reconstitution and, in the short term, enriched for Foxp3+ regulatory T cells (Tregs), at the expense of effector cells. Extended graft survival and tolerance were dependent on TGF-ß, indicating a role for induced Tregs. These findings point to the feasibility of building on lympholytic induction by guiding early lymphocyte reconstitution to favor endogenous regulatory mechanisms.

CD73 and adenosine generation in the creation of regulatory microenvironments.

Extracellular adenosine 5'-triphosphate (ATP) acts on many immune cells to promote inflammation. Conversely, the ATP metabolite adenosine is mainly an anti-inflammatory molecule. The ecto-enzymes CD39 and CD73 can dephosphorylate extracellular ATP to adenosine, thereby controlling this important pathway of immune modulation. Despite their established roles in the immune system, little is known of how CD39 and CD73 are themselves regulated. Recent data have shown that CD73 expression and adenosine generation are up-regulated by transforming growth factor-ß, depending on the cytokine content of the local microenvironment. We review here these recent findings and discuss their implications in disease.

Th17 cells induce a distinct graft rejection response that does not require IL-17A.

IL-17A-producing helper T (Th17) cells have been implicated in the pathogenesis of autoimmune disease, inflammatory bowel disease and graft rejection, however the mechanisms by which they cause tissue damage remain ill-defined. We examined what damage Th17 cell lines could inflict on allogeneic skin grafts in the absence of other adaptive lymphocytes. CD4(+) Th17 cell lines were generated from two TCR transgenic mouse strains, A1(M).RAG1(-/-) and Marilyn, each monospecific for the male antigen Dby. After prolonged in vitro culture in polarizing conditions, Th17 lines produced high levels of IL-17A with inherently variable levels of interferon gamma (IFNγ) and these cells were able to maintain IL-17A expression following adoptive transfer into lymphopenic mice. When transferred into lymphopenic recipients of male skin grafts, Th17 lines elicited a damaging reaction within the graft associated with pathological findings of epidermal hyperplasia and neutrophil infiltration. Th17 cells could be found in the grafted skins and spleens of recipients and maintained their polarized phenotype both in vivo and after ex vivo restimulation. Antibody-mediated neutralization of IL-17A or IFNγ did not interfere with Th17-induced pathology, nor did it prevent neutrophil infiltration. In conclusion, tissue damage by Th17 cells does not require IL-17A.

Successful attenuation of humoral immunity to viral capsid and transgenic protein following AAV-mediated gene transfer with a non-depleting CD4 antibody and cyclosporine.

The ability of transient immunosuppression with a combination of a non-depleting anti-CD4 (NDCD4) antibody and cyclosporine (CyA) to abrogate immune reactivity to both adeno-associated viral vector (AAV) and its transgene product was evaluated. This combination of immunosuppressants resulted in a 20-fold reduction in the resulting anti-AAV8 antibody titres, to levels in naïve mice, following intravenous administration of 2 × 10(12) AAV8 vector particles per kg to immunocompetent mice. This allowed efficient transduction upon secondary challenge with vector pseudotyped with the same capsid. Persistent tolerance did not result, however, as an anti-AAV8 antibody response was elicited upon rechallenge with AAV8 without immunosuppression. The route of vector administration, vector dose, AAV serotype or the concomitant administration of adenoviral vector appeared to have little impact on the ability of the NDCD4 antibody and CyA combination to moderate the primary humoral response to AAV capsid proteins. The combination of NDCD4 and CyA also abrogated the humoral response to the transgene product, that otherwise invariably would occur, following intramuscular injection of AAV5, leading to stable transgene expression. These observations could significantly improve the prospects of using rAAV vectors for chronic disorders by allowing for repeated vector administration and avoiding the development of antibodies to the transgene product.

CD8+ T-Cell depletion and rapamycin synergize with combined coreceptor/stimulation blockade to induce robust limb allograft tolerance in mice.

The growing development of composite tissue allografts (CTA) highlights the need for tolerance induction protocols. Herein, we developed a mouse model of heterotopic limb allograft in a stringent strain combination in which potentially tolerogenic strategies were tested taking advantage of donor stem cells in the grafted limb. BALB/c allografts were transplanted into C57BL/6 mice treated with anti-CD154 mAb, nondepleting anti-CD4 combined to either depleting or nondepleting anti-CD8 mAbs. Some groups received additional rapamycin. Both depleting and nondepleting mAb combinations without rapamycin only delayed limb allograft rejection, whereas the addition of rapamycin induced long-term allograft survival in both combinations. Nevertheless, robust donor-specific tolerance, defined by the acceptance of a fresh donor-type skin allograft and simultaneous rejection of third-party grafts, required initial CD8(+) T-cell depletion. Mixed donor-recipient chimerism was observed in lymphoid organs and recipient bone marrow of tolerant but not rejecting animals. Tolerance specificity was confirmed by the inability to produce IL-2, IFN-gamma and TNF-alpha in MLC with donor antigen while significant alloreactivity persisted against third- party alloantigens. Collectively, these results show that robust CTA tolerance and mixed donor-recipient chimerism can be achieved in response to the synergizing combination of rapamycin, transient CD8(+) T-cell depletion and costimulation/coreceptor blockade.

Fc-disabled anti-mouse CD40L antibodies retain efficacy in promoting transplantation tolerance.

CD40L antibodies have proven to be powerful immunosuppressive agents in nonhuman primates but unfortunately perturb blood coagulation. Neither the therapeutic nor the prothrombotic mechanism of anti-CD40L is defined sufficiently to determine whether these effects can be uncoupled. Recent evidence suggests that the Fc region of anti-CD40L antibodies interacting with Fc receptors plays an important role in stabilizing platelet aggregates. An Fc-disabled, aglycosylated anti-CD40L heavy chain variant was therefore created to determine whether it might still be useful in promoting transplantation tolerance. In a number of mouse models an engineered aglycosyl anti-CD40L recapitulated the effects of the intact anti-CD40L antibody in tolerance protocols involving transplantation of allogeneic bone marrow and skin. In contrast, another anti-CD40L variant with a conventional rat gamma2b heavy chain was less effective in ensuring long-term skin graft survival, possibly associated with its faster clearance from the circulation. These results show that short pulses of anti-CD40L antibody therapy may still be useful in tolerance protocols even when the Fc region is disabled.

Regulatory T cells and transplantation tolerance.

Rodent models of transplantation have demonstrated that it is possible to induce specific immunological tolerance of donor antigens and indefinite graft survival in the absence of any continued immunosuppression. If this situation could be achieved clinically it would avoid many of the longer term complications of organ grafting, such as the increased risk of infection and cancer and the nephrotoxicity of many immunosuppressive agents. In this review we shall consider the interplay between regulatory T cells, dendritic cells and the graft itself and the resulting local protective mechanisms that are coordinated to maintain the tolerant state. We will discuss how both anti-inflammatory cytokines and negative costimulatory interactions can elicit a number of interrelated mechanisms to regulate both T cell and antigen-presenting cell activity. The induction and maintenance of tolerance via acquired local immune privilege has implications for the design of therapeutic regimens and the monitoring of the tolerant status of patients being weaned off immunosuppression.

Regulatory T cells in transplantation tolerance.

Our ability to harness tolerance mechanisms will have a major impact in organ transplantation if it becomes possible to minimize drug maintenance, or even wean off immunosuppressive drugs. An improved understanding of the biology of regulatory T cells will make it possible to replace current induction regimens with those favouring the vaccination and selection of T cells that prevent graft rejection. Once tolerance is established, the continuous supply of graft antigens should sustain T cell mediated regulation as the dominant mechanism preventing graft rejection.

The role of CD4+ T-cell subsets in determining transplantation rejection or tolerance.

Peripheral tolerance to allogeneic organ grafts can be induced in rodents by treating with non-depleting CD4 and CD8 monoclonal antibodies. This tolerance is maintained by CD4+ T cells with a potent capacity to induce tolerance in further cohorts of T cells (i.e. infectious tolerance). We have cloned CD4+ T-cell subsets against the male transplantation antigen in vitro and find, in contrast to Th1 or Th2 clones that elicit rejection, that there is a distinct population of CD4+ T cells that suppress rejection by adoptive transfer (here called Treg). In order to identify molecular markers associated with tolerance and gain insights into the mechanisms of action of Treg cells, we carried out serial analysis of gene expression. We identified genes overexpressed in Treg compared to Th1 and Th2 cultures and found that some of these correlated in vivo with CD4-induced transplantation tolerance rather than rejection. The genes overexpressed in Treg cultures and within tolerated skin grafts were primarily expressed by mast cells (e.g. tryptophan hydroxylase and FcepsilonR1alpha), suggesting that regulatory cell activity and this form of tolerance may be associated with a localised but non-destructive form of Th2-like activation and a recruitment of mast cells.

Therapeutic aspects of tolerance.

The immune system is naturally unresponsive to 'self' antigens. Improved knowledge of mechanisms underlying self tolerance is giving rise to a new generation of immunosuppressive agents, that can exploit these mechanisms and so reduce the nature and level of medication that needs to be given long-term to control diseases where the immune system does harm.

Approaching tolerance in transplantation.

Basic research has provided substantial encouragement that tolerance processes may be harnessed to the benefit of organ transplants. The goal of achieving mixed chimerism to ensure a robust tolerance, however elegant, may yet prove to be too complex and, consequently, risky as a procedure to compensate for the breadth of genetic differences, and prior immunological experiences of donor and host. Tolerance through regulation may prove to be easier to generate, but insufficiently robust to maintain. In the end the chosen protocol will be one that is simple, cheap and can guarantee patient compliance. Pragmatically, such a protocol need not be one aimed at clear-cut drug-free tolerance, but rather one which is trouble free. This could end up as a combination of partial tolerance (where tolerance processes have been harnessed) induced through a short-term treatment, in conjunction with easily tolerated maintenance therapy with select immunosuppressive drugs. Perhaps to the patient, the holy grail of tolerance is not as important as the complete assurance that the graft will survive and continue to function in all circumstances.

Appropriate targets for monoclonal antibodies in the induction of transplantation tolerance.

There are many routes to exploiting tolerance processes to ensure long-term graft survival. Complete tolerance although attractive as a goal, may not be the most practical in the clinic. Instead simple and low-impact procedures that harness tolerance processes used in conjunction with low doses of immunosuppressive drugs may prove the most reliable and user-friendly of approaches.

CAMPATH-1 antibodies in stem-cell transplantation.

BACKGROUND: CAMPATH-1 (CD52) Abs have been used in stem-cell transplants for the prevention of GvHD and graft rejection. These complications can effectively be prevented by depletion of T lymphocytes from both donor and recipient. However, donor lymphocytes might contribute an anti-leukemia effect and lymphocyte depletion may exacerbate problems with immune reconstitution. There is a fine balance between the risks of GvHD and host-versus-graft reactions, relapse and infection. METHODS: Clinical outcomes for 4264 patients were reported to a central registry and analyzed by univariate and multivariate methods to determine the superior protocols. Various protocols of lymphocyte depletion were tested, using either CAMPATH-1M (IgM) plus complement or CAMPATH-1G (IgG2b) to treat the donor BM ex vivo and CAMPATH-1G in vivo to treat the recipient. The humanized antibody CAMPATH-1H has recently replaced CAMPATH-1G. A meeting of the clinical collaborators was convened to discuss the results and to review the experiences of individual centers. RESULTS: Interest focused on the use of mobilized PBSC for transplantation and on the use of reduced-intensity conditioning regimens ('mini' or 'non-Correspondence myeloablative' transplants). These approaches are likely to become increasingly important in the future and will allow transplant procedures to be used for relatively older patients. The use of CAMPATH-1G or CAMPATH-1H was associated with a low incidence of GvHD or rejection, though there were some differences that might be related to the longer half-life of the humanized antibody. An unexpected and apparently paradoxical effect of post-transplant CYA was observed - it appeared to reduce the risk of dying from infection after 6 months. Although part of the benefit could be explained by a reduction in GvHD, the effect was still evident when patients with GvHD or graft rejection were excluded from analysis. DISCUSSION: CAMPATH-1H appears to have a useful role in the prevention of graft rejection and GvHD, particularly in patients who are at high risk of these complications. It can equally well be used by admixture with the infused stem cells, or by administration to the patient prior to the transplant. Future studies will seek to understand the mechanism of the CYA effect and to improve the quality of immune reconstitution.

Cutting edge: anti-CD154 therapeutic antibodies induce infectious transplantation tolerance.

Nondepleting anti-CD154 (CD40 ligand) mAbs have proven effective in inducing transplantation tolerance in rodents and primates. In the induction phase, anti-CD154 Ab therapy is known to enhance apoptosis of Ag reactive T cells. However, this may not be the sole explanation for tolerance, as we show in this study that tolerance is maintained through a dominant regulatory mechanism which, like tolerance induced with CD4 Abs, manifests as infectious tolerance. Therefore, tolerance induced with anti-CD154 Abs involves not only the deletion of potentially aggressive T cells, but also a contagious spread of tolerance to new cohorts of graft-reactive T cells as they arise.

High dose bone marrow transplantation induces deletion of antigen-specific T cells in a Fas-independent manner.

BACKGROUND: Monoclonal antibody induced tolerance to high doses of multiple lymphocyte stimulating (MLS)+minor mismatched bone marrow has recently been associated with clonal deletion, as reported in fully allogeneic models of bone marrow transplantation. FasL-induced apoptosis has been shown to mediate antigen-specific T cell deletion after antigenic stimulation in wild-type and T cell receptor transgenic mice. Therefore, we investigate a role for the Fas pathway in deletional tolerance to high dose bone marrow. METHODS: Fas mutant and control mice (H-2k, MLS-1b) were tolerized under the cover of monoclonal antibodies to high dose (5 x 10(7) cells) AKR (H-2k, MLS-1a) bone marrow. Tolerance was confirmed by AKR skin grafting after antibody clearance. Antigen-reactive cell deletion was monitored by Vbeta6+ T cell elimination, measured by flow cytometry of peripheral blood throughout the experiment. Donor T cell (Thy1.1+) chimerism was assessed in a similar manner. RESULTS: Fas mutant mice infused with high dose AKR bone marrow under the cover of antibody were tolerant, as demonstrated by indefinite survival of AKR skin grafts. When high levels of donor cell chimerism were established in Fas mutant mice, peripheral deletion of antigen-reactive cells was observed to be independent of signaling through Fas. CONCLUSIONS: Apoptosis mediated by Fas receptor signaling is not the mechanism of clonal deletion of antigen-reactive cells after antibody facilitated high dose marrow transplantation. However, the Fas mutation does impair the development of adequate donor chimerism.

Dominant tolerance and linked suppression induced by therapeutic antibodies do not depend on Fas-FasL interactions.

BACKGROUND: Nonlytic anti-CD4 monoclonal antibody therapy can be used to induce transplantation tolerance in rodent models. Such tolerance is often associated with dominant regulation, mediated by CD4+ cells, and characterized by infectious tolerance and linked suppression. Understanding the mechanisms by which CD4+ regulatory cells function may improve the manner in which current immunosuppressants are applied and may lead to the development of new tolerance-inducing therapeutics. Fas-mediated apoptosis has been characterized as an important mechanism of peripheral self-tolerance and we here examine whether it has any role in anti-CD4 monoclonal antibody-induced dominant tolerance. METHODS: Tolerance to transplanted skin and bone marrow, mismatched for multiple minor histocompatibility antigens, was induced in Fas mutant and control mice using anti-CD4 and anti-CD8 monoclonal antibodies. To test for linked suppression, animals were transplanted with a second graft-bearing tolerated and third party antigens. The ability of splenocytes from tolerant animals to suppress graft rejection was assessed by transfer into partially immunocompromised recipients. RESULTS: Monoclonal antibody therapy rendered Fas mutant mice tolerant of minor disparate skin and bone marrow. Splenocytes from these and control tolerant animals when transferred into partially immunocompromised Fas mutant or control recipients, induced antigen-specific suppression of graft rejection. Additionally, tolerant Fas mutant mice accepted grafts bearing tolerated and third party antigens. CONCLUSIONS: Signal transduction through the Fas receptor plays no essential role in the induction of tolerance using anti-CD4 and anti-CD8 monoclonal antibodies or its maintenance by active regulation.