Pilot study of a novel combination of two therapeutic vaccines in advanced non-small-cell lung cancer patients

Cancer vaccines contain tumor antigens in a pro-inflammatory context with the purpose to generate potent antitumor immune responses. However, tumor cells develop different immunosuppressive mechanisms that limit the effectiveness of an anticancer immune response. Therefore, therapeutic vaccine treatment alone is usually not sufficient to generate tumor regression or survival improvement, especially in the advanced disease scenario in which most clinical studies have been conducted. Combining cancer vaccines with different anticancer therapies such as chemotherapy, radiotherapy and other immunotherapeutic agents has had different levels of success. However, the combination of cancer vaccines with different mechanisms of action has not been explored in clinical trials. To address this issue, the current review summarizes the main clinical and immunological results obtained with two different therapeutic vaccines used in advanced non-small-cell lung cancer patients, inducing an immune response against epidermal growth factor (CIMAvax-EGF) and NGcGM3 ganglioside (racotumomab). We also discuss preliminary findings obtained in a trial of combination of these two vaccines and future challenges with these therapies.     

HER-2/neu Cancer Vaccines: Present Status and Future Prospects

Immunotherapeutic approaches to cancer should focus on novel undertakings that modulate immune responses by synergistic enhancement of anti-tumor immunological parameters. Cancer vaccines should preferably be composed of multiple defined tumor antigen specific B- and T-cell epitopes. The main focus of this article is to briefly review the present status of Her-2/neu vaccine strategies and to describe the innovative strategies developed in my laboratory for a vaccine against HER-2/neu (ErbB-2) with emphasis on the humoral arm of the immune response. Elucidating the underlining mechanisms of anti-tumor effects elicited by peptide vaccines against a self-protein is a requirement for developing an immunotherapeutic strategy that might be effective in human cancer vaccines. Our approach entails the identification of biologically relevant epitopes, establishing relevant in vitro assays for monitoring vaccine efficacy, devising strategies to engineer conformationally dependent sequences, developing highly immunogenic vaccines for an outbred population and delivering the immunogen/vaccine in a safe and efficacious vehicle, utilizing transgenic animal models for assessing tumor development, and developing challenge models using transplantable tumors to study efficacy of vaccine constructs. We have developed a multi-HER-2/neu B-cell epitope approach and shown in preclinical studies that immunization with a combination of two B-cell epitope was more effective in preventing mammary tumors than a single epitope. We have translated that work to the clinic (OSU 0105) in an FDA approved, NCI sponsored “Phase 1 Active Immunotherapy trial with Chimeric and Multi-epitope based peptide vaccine targeting HER-2 oncoprotein and nor-MDP adjuvant in patients with metastatic and/or recurrent solid tumors” at the James Cancer Hospital at the Ohio State University. The correlation between overexpression of HER-2/neu and up-regulation of VEGF has been demonstrated in breast cancer patients. Thus, blocking angiogenesis is an attractive strategy to inhibit tumor growth, invasion, and metastasis. The hypothesis that combination of anti-angiogenic therapy and tumor immunotherapy of cancer may be synergistic is an important future goal. In this review, I will discuss insights into our preclinical studies that might aid in the design of the next generation of cancer vaccines and become an integrated component of prophylactic/preventive and therapeutic approach.     

Production of myeloid dendritic cells (DC) pulsed with tumor-specific idiotype protein for vaccination of patients with multiple myeloma

BACKGROUND: Immunotherapy of cancer with DC vaccines has produced encouraging results in clinical trials. Antigen (Ag)-pulsed DC have elicited CD4+ and CD8+ T-cell immunity and tumor regression in humans. However, there is no standard method of DC production. The DC phenotype, number and Ag-loading process used in these studies have varied, making comparisons between trials difficult. METHODS: In the present report a reproducible method was developed for the production of a DC-based vaccine. Monocytes were enriched by adhesion from healthy donor apheresis products and cultured with growth factors for maturation into DC. The cells were loaded with the tumor Ag idiotype proteins from patients with multiple myeloma. DC culture and Ag loading were performed in an automated and closed system. The DC product was characterized for phenotype by flow cytometry and for function in Ag uptake and Ag presentation. RESULTS: These monocyte-derived DC expressed high levels of costimulatory molecules (CD80/86). Ag-pulsed DC functioned to induce allogeneic proliferative lymphocyte responses and Ag-specific cytotoxic T lymphocyte (CTL) responses. The DC viability, phenotype and function were well preserved following prolonged frozen storage. Aliquots from the product of a single DC preparation could be used for sequential vaccinations without batch to batch variability. DISCUSSION: Ag-pulsed DC can be reproducibly generated for clinical use. These standardized methods are now being employed for a clinical trial to evaluate idiotype-pulsed DC vaccine therapy following non-myeloablative transplant for the treatment of multiple myeloma.     

Tumor-derived chaperone-rich cell lysates are effective therapeutic vaccines against a variety of cancers

With the clinical use of purified, tumor-derived chaperone proteins as anti-cancer vaccines already in clinical trial stages, we have focused our attention on the utility of chaperone-rich cell lysates (CRCL) in cancer immunotherapy. CRCL, as prepared from tumor lysates via a free solution-isoelectric focusing (FS-IEF) technique, is a high-yield vaccine enriched for numerous chaperone proteins. We have compared the efficacy of CRCL vaccines to that of individual chaperone protein vaccines in in vivo settings, including ELISPOT assays, tumor-growth assays and survival assays. In all experiments, CRCL vaccines were at least as effective, and in some settings perhaps even more effective, than either of the two most heavily studied components of CRCL, HSP70 and GRP94/gp96, in reduction in tumor growth and prolongation of survival in both prophylactic and pre-existing tumor settings against tumors of diverse origin and genetic background. Combining CRCL preparations with dendritic cells ex vivo resulted in a cellular vaccine that could eradicate pre-existing tumors in a high percentage of cases. The high yields of CRCL vaccines from small quantities of starting materials, the relative ease of its procurement and the functional data presented here suggest that CRCL vaccines are worthy of evaluation in pilot clinical trial cancer immunotherapy protocols.     

Active specific immunotherapy with an autologous tumor cell vaccine in patients with resected non-small cell lung cancer

Eighteen postoperative patients with non-small cell lung cancer were actively immunized with a vaccine that included autologous cryopreserved irradiated tumor cells admixed with bacillus Calmette-Guerin. Patients received three weekly intradermal immunizations beginning 1-3 months after surgery (15 patients) or after completion of postoperative radiotherapy (3 patients). There was marked heterogeneity in the relative proportion of tumor cells versus host infiltrating cells within individual vaccines (range of percent tumor cells 7-75%). Five patients exhibited positive delayed cutaneous skin test reactivity (DCR) to autologous irradiated tumor cells prior to immunization, whereas 8 of 13 converted from skin test negative to positive. There were no correlations between DCR reactivity and in vitro lymphoproliferative responses to autologous tumor cells or to clinical outcomes, i.e., freedom from relapse. Possible explanations for the heterogeneity of the lung cancer vaccine and approaches for improving its immunogenicity are discussed.     

Phase I clinical trial of a recombinant canarypoxvirus (ALVAC) vaccine expressing human carcinoembryonic antigen and the B7.1 co-stimulatory molecule

 The generation of cytotoxic effector T cells requires delivery of two signals, one derived from a specific antigenic epitope and one from a costimulatory molecule. A phase I clinical trial was conducted with a non-replicating canarypoxvirus (ALVAC) constructed to express both human carcinoembryonic antigen (CEA) and the B7.1 costimulatory molecule. This was the first study in cancer patients to determine if the delivery of costimulation with a tumor vaccine was feasible and improved immune responses. Three cohorts of six patients, each with advanced CEA-expressing adenocarcinomas, were treated with increasing doses of an ALVAC-CEA-B7.1 vaccine (4.5 × 10⁶, 4.5 × 10⁷, and 4.5 × 10⁸ plaque-forming units, PFU). Patients were vaccinated by intramuscular injection every 4 weeks for 3 months and monitored for side-effects, tumor growth and anti-CEA immune responses. ALVAC-CEA- B7.1 at doses up to 4.5 × 10⁸ PFU was given without evidence of significant toxicity or autoimmune reactions. Three patients experienced clinically stable disease that correlated with increasing CEA-specific precursor T cells, as shown by in vitro interferon-γ enzyme-linked immunoassay spot tests (ELISPOT). These three patients underwent repeated vaccination resulting in augmented CEA-specific T cell responses. This study represents the first use of costimulation to enhance antitumor vaccines in cancer patients. This approach resulted in CEA-specific immunity associated with stable diseases in three patients. This study also demonstrated that CEA-specific T cell responses could be sustained by repeated vaccinations. Although the number of patients was small, the addition of B7.1 to virus-based vaccines may improve immunological and stable diseases to vaccination against tumor-associated antigens with tolerable toxicity. Received: 6 May 2000 / Accepted: 13 July 2000     

Sheep-pox vaccine prepared from formaldehyde inactivated virus adsorbed to aluminium hydroxide gel

The aim of the study was to produce an efficacious formaldehyde inactivated, adsorbed vaccine from the Mongolian sheep-pox MH virus strain. Aluminium hydroxide gel prepared from AlCl3 X 6 H2O proved to be the most efficacious adsorbent among the gels prepared from different substances. Above 1.8% Al2O3 content the unadsorbed virus quantity was less than 1% of the original one. Using gel prepared from KAl(SO4)2 and AlCl3 X 6 H2O, respectively, the quantity of adsorbed virus was the same during the adsorption period from 10 min to 24 h. Intradermal inoculation of sheep proved more advantageous for virus production than subcutaneous inoculation. Three vaccines containing different quantities of antigen were prepared from virus propagated in sheep. The vaccine containing 19 800 ID50 inactivated virus did not protect the sheep even against a virus challenge of 25 ID50, while that of 67 000 ID50 content protected 50% of the animals infected with 125 to 287 ID50, and that of 395 000 ID50 content protected 100% of the animals against challenge with more than 100 000 ID50. More than 3 million sheep were inoculated in Mongolia with vaccines of 350 000 ID50 virus content in the last years. In the areas where vaccination has been introduced no sheep-pox epizootic has occurred.     

Role of whole-cell pertussis vaccine in severe local reactions to the preschool (fifth) dose of diphtheria-pertussis-tetanus vaccine.

OBJECTIVE: To estimate the contribution of whole-cell pertussis vaccine to severe local reactions after the preschool (fifth) dose of adsorbed diphtheria toxoid-pertussis vaccine-tetanus toxoid (DPT) vaccine. DESIGN: Double-blind randomized controlled trial. SETTING: Urban community. PARTICIPANTS: Volunteer sample of 200 healthy children 4 to 6 years old who were eligible for the fifth dose of DPT vaccine. INTERVENTIONS: Children received, in both arms, either diphtheria toxoid-tetanus toxoid (DT) and monovalent pertussis vaccines (group A, 99 children) or DPT and meningococcal vaccines (group B, 101 children). All were licensed products from single lots. The children were assessed 24 hours later by a trained observer. Serum samples obtained before vaccination were tested for antibodies to tetanus and diphtheria toxins and five pertussis antigens by means of enzyme-linked immunosorbent assay. MAIN OUTCOME MEASURES: Rates of severe local reactions (an area of redness or swelling or both of 50 mm or greater) 24 hours after vaccination. Relation between serum antibody levels before vaccination and rates of severe local reactions to corresponding vaccines. RESULTS: All of the subjects were followed up 24 hours after vaccination. Severe redness was present in 38% given DPT vaccine, 29% given intramuscular pertussis vaccine and 9% given DT vaccine (p < or = 0.002, three-way comparison). Severe swelling was common after vaccination with all three products. After intramuscular pertussis vaccination a relation was evident between the prevaccination levels of antibody to whole-cell pertussis bacteria and the rates of redness (p < 0.02) but not between the prevaccination subcellular antibody levels and the rates of redness. CONCLUSION: That pertussis vaccine resembled the DPT vaccine in causing severe redness suggests that it is the principal cause of such reactions after DPT vaccination. The DT vaccine was also reactogenic; thus, cumulative sensitization to one or more of its constituents may be a factor.     

Active specific immunotherapy with Newcastle-diseasevirus-modified autologous tumor cells following resection of liver metastases in colorectal cancer

Summary A group of 23 colorectal cancer patients were treated by a new type of active specific immunotherapy (ASI) following complete surgical resection of liver metastases (R0 resection). For ASI treatment we used a vaccine consisting of 1 × 10⁷ autologous, irradiated (200 Gy) metastases-derived tumor cells incubated with 32 hemagglutination units (HU) of Newcastle disease virus (NDV). The adjuvant vaccine therapy was started 2 weeks after surgery and was repeated five times at 14-days intervals followed by one boost 3 months later. The delayed-type hypersensitivity (DTH) skin reactions to the vaccine were measured as well as the DTH reactions to a challenge test of 1 × 10⁷ non-virus-modified autologous tumor cells from liver metastases or 1 × 10⁷ autologous normal liver cells. In addition 32 HU NDV alone and a standard antigen test (Merieux test) were applied pre- and post-vaccination. The vaccination was well tolerated. In 13 of 23 patients an increasing reactivity against the vaccine was observed during the vaccination procedure. Nine patients (40%) experienced an increased DTH reactivity against autologous tumor cells following vaccination, while 17% or fewer showed an increased reactivity to Merieux test antigens, NDV, or normal liver cells. The increased antitumor response was not correlated to responsiveness to NDV alone, autologous liver cells, enzymes and culture medium used for vaccine preparation or standard antigens (Merieux test). After a follow-up of at least 18 months 61% of the vaccinated patients developed tumor recurrence in comparison to 87% of a matched control groups from the same institution that had been only surgically treated. The results of this phase II trial are encouraging and should stimulate further prospective randomized studies.     

Immune response to a hepatitis B DNA vaccine in Aotus monkeys: a comparison of vaccine formulation, route, and method of administration.

BACKGROUND: Attempts to optimize DNA vaccines in mice include using different routes of administration and different formulations. It may be more relevant to human use to carry such studies out in nonhuman primates. Here we compare different approaches to delivery of a DNA vaccine against the hepatitis B virus (HBV) in Aotus monkeys. MATERIALS AND METHODS: Thirty-two adult Aotus l. lemurinus monkeys divided into 8 groups of four were immunized with 400 microg of a DNA vaccine which encoded hepatitis B surface antigen (HBsAg). DNA in saline was administered by intradermal (ID) or intramuscular (IM) injection with needle and syringe, IM injection with the Biojector needleless injection system or combined ID (needle) and IM (Biojector). DNA formulated with cationic liposomes (CellFECTIN) was injected IM with needle or Biojector. DNA with added E. coli DNA (100 microg) was injected IM with the Biojector or ID. A ninth group of 4 monkeys was injected IM (needle) with Engerix-B, a commercial vaccine containing recombinant HBsAg (10 microg) adsorbed onto alum. Monkeys were boosted in an identical fashion to their prime at 8 weeks, but all received the protein vaccine (Engerix-B) at 16 weeks. Sera was assessed for antibodies against HBsAg (anti-HBs) by enzyme-linked imunosorbent assay (ELISA). RESULTS: The primary humoral response induced by IM delivery of the DNA vaccine was very poor. In most cases there was no detectable anti-HBs even after 2 DNA doses but the kinetics of the response to subsequent protein indicated that a memory B cell response had been induced. In contrast, following IM-administration of DNA using the Biojector, detectable anti-HBs were observed in 3 of 8 animals and evidence for immunological priming was apparent in an additional 4 of the 8 monkeys. ID injection of DNA vaccine in saline induced a potent antibody response which was augmented 6-fold by the addition of E. coli DNA. Combining ID and IM administration did not improve humoral immunity over ID injection alone. CONCLUSIONS: For immunization of primates with DNA vaccines, ID may be a preferable route to IM, although it is not clear whether the Aotus monkey is a relevant model for humans in this respect. Nevertheless, the use of the Biojector needleless injection system may improve responses with IM delivery of DNA vaccines. As well, the immunostimulatory action of E. coli DNA may be used to augment the humoral response induced by a DNA vaccine.     

Limited controlled trial of the reactogenic properties of ADTP vaccines containing stab cultures as the pertussis component

The reactogenic properties of adsorbed DPT vaccine containing Bordetella pertussis cultures, grown by submerged cultivation, as the pertussis component were studied. The study revealed that the vaccine was low-reactogenic: no severe postvaccinal reactions were recorded in immunized children. The frequency and intensity of febrile and local reactions in children immunized with adsorbed DPT vaccine under trial and the commercial preparation commonly used in the USSR were identical, but considerably less pronounced than in children immunized with foreign vaccines having similar composition.     

Pilot study of mutant ras peptide-based vaccine as an adjuvant treatment in pancreatic and colorectal cancers

INTRODUCTION: There is mounting evidence describing the immunosuppressive role of bulky metastatic disease, thus countering the therapeutic effects of tumor vaccine. Therefore, adjuvant immunotherapy may have a better impact on clinical outcome. In this phase II clinical trial, we aimed to test the feasibility of using a specific mutant ras peptide vaccine as an adjuvant immunotherapy in pancreatic and colorectal cancer patients. MATERIALS AND METHODS: Twelve patients with no evidence of disease (NED), five pancreatic and seven colorectal cancer patients were vaccinated subcutaneously with 13-mer mutant ras peptide, corresponding to their tumor's ras mutation. Vaccinations were given every 4 weeks, up to a total of six vaccines. RESULTS: No serious acute or delayed systemic side effects were seen. We detected specific immune responses to the relevant mutant ras peptide by measuring IFN-gamma mRNA expression by quantitative real-time PCR. Five out of eleven patients showed a positive immune response. Furthermore, the five pancreatic cancer patients have shown a mean disease-free survival (DFS) of 35.2+ months and a mean overall survival (OS) of 44.4+ months. The seven colorectal cancer patients have shown a mean disease-free survival (DFS) of 27.2+ months and a mean overall survival (OS) of 41.5+ months. CONCLUSION: In this study, we found that it is feasible to use mutant ras vaccine in the adjuvant setting. This vaccine is safe, can induce specific immune responses, and it appears to have a positive outcome in overall survival. Therefore, we believe that such an approach warrants further investigation in combination with other therapies.     

Mumps vaccine L-Zagreb, prepared in chick fibroblasts. I. Production and field trials

Leningrad-L3 Mumps Vaccine virus has been further attenuated by adaptation and passage on SPF chick embryo fibroblast cell cultures. This new mumps strain has been designated L-Zagreb and has been used to prepare mumps vaccines which meet the WHO requirements. Observations during both the field trial period prior to registration and during the later use of the vaccine showed that the few reactions observed were mild and that seroconversion was obtained in 88-98% of vaccines. The morbidity of mumps in Croatia declined more than tenfold after the introduction of the new vaccine. During a mumps epidemic, vaccine efficiency was calculated to be 97-100%.     

Animal models of human-derived cancer vaccines

Preclinical cancer vaccine studies must address vaccine safety, immunogenicity, and efficacy, as well as mechanism of vaccine action. Animal models of vaccines employing human tumor-associated antigen or epitopes (TAA, TAE) differ fundamentally from those employing tumor-specific antigens or epitopes (TSA, TSE). TSA and TSE vaccines will most likely demonstrate similar toxicity, immunogenicity, and efficacy in both tumor-bearing animals and patients. In contrast, TAA/TAE immunizations may have to overcome a host’s immunological tolerance to TAA/TAE expressed not only on tumor, but also on normal tissues; immunity to TAA/TAE will potentially target normal tissues and thus may induce autoimmunity. Various experimental models for human-derived TAA/TAE vaccines have been developed. These models include transgenic mice, mice with severe combined immunodeficiency (SCID), and non-human primates. Recently, unique animal models of TAA/TAE cancer vaccines have been developed, taking advantage of the discovery of animal tissue antigens with significant sequence homologies to human TAA/TAE. These models mimic perhaps most closely the situation in cancer patients.     

Composition of acellular pertussis and combination vaccines: a general review.

Since the development and introduction of the acellular pertussis vaccine in Japan in the early eighties, we have come a long way in using this component in combination with other vaccines. However, the basic problem in development of an effective and safe pertussis vaccine is that the antigens to induce complete protection against clinical pertussis and the precise mechanism by which pertussis vaccine confers immunity is yet unknown. Hence, the composition of future acellular pertussis vaccine remains an open issue. Recently, acellular pertussis vaccine has been licensed for the booster doses in the U.S.A. and for primary immunization of infants in Italy and Germany. A multicentric trial has been carried out to compare the serological response and adverse reactions of 13 acellular pertussis vaccines. These vaccines contained one or more of the four components, i.e. FHA, PT, 69 kDa OMP and fimbriae. All vaccines were associated with substantially fewer and less adverse reactions and were more immunogenic with respect to antibodies against the added antigens. DTP vaccines in the near future will have combinations of other components and the key antigen for combination will be acellular pertussis component which is going to replace whole cell pertussis component in DTP vaccines. In view of this, manufacturers like ourselves from the developing countries are still groping in the dark, uncertain whether we should have a single component acellular pertussis vaccine or multicomponent one. This will have a major impact on the cost of production, the final cost of the combination vaccines and the regulatory issues that we will have to tackle in view of the recent thinking on harmonization in the pharmaceutical industry.     

Antitumor therapeutic effects of e7 subunit and DNA vaccines in an animal cervical cancer model: antitumor efficacy of e7 therapeutic vaccines is dependent on tumor sizes, vaccine doses, and vaccine delivery routes

We previously reported that E7 subunit and DNA vaccines are both capable of inducing antitumor protection through induction of antigen-specific CTL. In this study, we investigated their ability to control established tumors according to tumor size, vaccine doses, and vaccine delivery routes. Antitumor therapeutic efficacy of both vaccine types was dependent on tumor burden. However, E7 subunit vaccines induced a higher level of antitumor therapeutic activities at the tested dose compared to DNA vaccines. This was concomitant with induction of antibody, CTL, and IFN-gamma responses, as well as histologic changes (heavy infiltration of lymphocytes and presence of apoptotic bodies). In vaccine dose titration assays, 50 and 100 microg of DNA vaccines exhibited an equivalent antitumor efficacy to 0.5 and 1 microg of E7 subunit vaccines, respectively, i.e., a 100-fold difference in E7 dosage, suggesting the importance of vaccine doses for achieving antitumor immunity. Furthermore, tumors of a larger size were controlled by intratumoral injection with E7 subunit vaccines, underscoring the importance of vaccine delivery routes for antitumor therapeutic efficacy. Thus, these data suggest that antitumor therapeutic efficacy of E7 therapeutic vaccines is determined by vaccine doses, vaccine delivery routes, and tumor sizes, and that these vaccines could be another addition to conventional therapy modalities against cervical cancer.     

Autologous dendritic cell vaccine for estrogen receptor (ER)/progestin receptor (PR) double-negative breast cancer

Purpose

A wealth of preclinical information, as well as a modest amount of clinical information, indicates that dendritic cell vaccines have therapeutic potential. The aim of this work was to assess the immune response, disease progression, and post-treatment survival of ER/PR double-negative stage II/IIIA breast cancer patients vaccinated with autologous dendritic cells pulsed with autologous tumor lysates.

Methods

Dendritic cell (DC) vaccines were generated from CD14+ precursors pulsed with autologous tumor lysates. DCs were matured with defined factors that induced surface marker and cytokine production. Individuals were immunized intradermally four times. Specific delayed type IV hypersensitivity (DTH) reaction, ex vivo cytokine production, and lymphocyte subsets were determined for the evaluation of the therapeutic efficiency. Overall survival and disease progression rates were analyzed using Kaplan–Meier curves and compared with those of contemporaneous patients who were not administered DC vaccines.

Results

There were no unanticipated or serious adverse effects. DC vaccines elicited Th1 cytokine secretion and increased NK cells, CD8+ IFN-γ+ cells but decreased the percentage of CD3+ T cells and CD3+ HLA-DR+ T cells in the peripheral blood. Approximately 58% (18/31) of patients had a DTH-positive reaction. There was no difference in overall survival between the patients with and without DC vaccine. The 3-year progression-free survival was significantly prolonged: 76.9% versus 31.0% (with vs. without DC vaccine, p?Conclusion Our findings strongly suggest that tumor lysate-pulsed DCs provide a standardized and widely applicable source of breast cancer antigens that are very effective in evoking anti-breast cancer immune responses.     

Reactions after pertussis vaccine: a manufacturer's experiences and difficulties since 1964

Pertussis vaccines vary in quality, safety, and efficacy according to the production strains of Bordetella pertussis, the method of manufacture, and quality control procedures. It is therefore not justifiable to combine information on the incidence, nature, and severity of reactions after all manufacturers'' pertussis vaccines as if they were a single product. Attempts were made to collect information on all suspected cases of severe reactions that occurred after administration of about 15 million doses of Wellcome pertussis vaccines in the United Kingdom and Northern Ireland from 1964 to mid-1977. Altogether six deaths, six neurological reactions with sequelae, and 17 convulsions without sequelae were reported, but some were clearly not attributable to the vaccine, while, in other cases, the available information was inadequate for assessing the role of vaccination. Neurological disorders, similar to those reported in a few children after pertussis vaccination, occur unexpectedly in apparently healthy infants at the recommended age for immunisation, so chance association between vaccination and these events can be expected in some children. The Joint Committee on Vaccination and Immunisation has made several recommendations aimed at reducing severe reactions after pertussis vaccination. These include replacing plain vaccine with aluminium-adsorbed vaccine, but there is no clear evidence that the aluminium-adsorbed vaccine produces fewer reactions than the plain.There are difficulties enough in deciding the cause of events that occur after vaccination, since these reactions often occur naturally in children of vaccination age. The task is made even harder by the assumption that various manufacturers'' vaccines are the same and the lack of information available to manufacturers about cases in which their vaccine has been implicated. Information on vaccines administered is entered on immunisation records cards; it should be used and referred to if reactions occur.     

Mathematical model of a personalized neoantigen cancer vaccine and the human immune system

Cancer vaccines are an important component of the cancer immunotherapy toolkit enhancing immune response to malignant cells by activating CD4⁺ and CD8⁺ T cells. Multiple successful clinical applications of cancer vaccines have shown good safety and efficacy. Despite the notable progress, significant challenges remain in obtaining consistent immune responses across heterogeneous patient populations, as well as various cancers. We present a mechanistic mathematical model describing key interactions of a personalized neoantigen cancer vaccine with an individual patient’s immune system. Specifically, the model considers the vaccine concentration of tumor-specific antigen peptides and adjuvant, the patient’s major histocompatibility complexes I and II copy numbers, tumor size, T cells, and antigen presenting cells. We parametrized the model using patient-specific data from a clinical study in which individualized cancer vaccines were used to treat six melanoma patients. Model simulations predicted both immune responses, represented by T cell counts, to the vaccine as well as clinical outcome (determined as change of tumor size). This model, although complex, can be used to describe, simulate, and predict the behavior of the human immune system to a personalized cancer vaccine.     

Anti-HER2 vaccines: new prospects for breast cancer therapy

Each year, breast cancer accounts for more than 400,000 new cancer cases and more than 130,000 cancer deaths in Europe. Prognosis of nonmetastatic breast cancer patients is directly related to the extent of the disease, mainly nodal spreading and tumor size, and to the molecular profile, particularly HER2 over-expression. In patients with HER2-over-expressing tumors, different studies have shown cellular and/or humoral immune responses against HER2 associated with a lower tumor development at early stages of the disease. These findings have led to the hypothesis that the generation of an anti-HER2 immune response should protect patients from HER2-over-expressing tumor growth. Taken together with the clinical efficiency of trastuzumab-based anti-HER2 passive immunotherapy, these observations allowed to envisage various vaccine strategies against HER2. The induction of a stable and strong immunity by cancer vaccines is expected to lead to establishment of immune memory, thereby preventing tumor recurrence. However, an immunological tolerance against HER2 antigen exists representing a barrier to effective vaccination against this oncoprotein. As a consequence, the current challenge for vaccines is to find the best conditions to break this immunological tolerance. In this review, we will discuss the different anti-HER2 vaccine strategies currently developed; considering the strategies having reached the clinical phases as well as those still in preclinical development. The used antigen can be either composed of tumoral allogenic cells or autologous cells, or specific to HER2. It can be delivered by dendritic cells or in a DNA, peptidic or proteic form. Another area of research concerns the use of anti-idiotypic antibodies mimicking HER2.