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Drought is a pressing environmental issue with profound socio-economic impacts. Frequent drought disasters around the world have brought huge impacts and challenges, severely constraining the sustainable development of cities. How to improve drought resilience to guarantee regional sustainable development has become a hot research topic. In this study, we developed a comprehensive framework to assess drought resilience in China, analyzing its spatiotemporal evolution characteristics, uncovering the underlying impact mechanisms, and projecting future resilience trends across different regions of the country. Over the past 12 years, the average drought resilience level in China has risen by 14.4 %. Central and eastern coastal provinces demonstrated higher resilience levels, contrasting with the western inland regions' lower resilience. A significant positive spatial correlation was observed in China's drought resilience, with high-value clusters emerging in the southeastern and northeastern regions. Among the sub-resilience dimensions, social resilience had the most substantial impact. The prediction model suggests that the drought resilience level will increase modestly by 6.2 % across provinces, maintaining the spatial pattern of higher resilience in the eastern coastal areas and the southern and northern extremities, with lower resilience in the central region. Our findings underscore the significance of understanding regional variations in drought resilience to inform targeted and efficient policy interventions.
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BACKGROUND: Spinal cord injury patients frequently suffer from anxiety and depression, which can seriously affect their quality of life and recovery. Acupuncture, as a traditional Chinese therapy, has been used to treat anxiety and depression for more than 2000 years. The aim is to evaluate the clinical efficacy of acupuncture in the treatment of anxiety and depression in spinal cord injury patients. METHODS: The literature on acupuncture treating anxiety and depression in patients with spinal cord injury in PubMed, Embase, Cochrane Library, Chinese Biomedical Literature Database, China National Knowledge Infrastructure, Chinese Scientific Journal Data, and Wanfang data were searched through computers from the establishment of the database to May 2024. In the study, the Cochrane tool for assessing the risk of bias was used and the meta-analyses were carried out using the software package Review Manager 5.4. RESULTS: Ten trials were included in this systematic review, with 361 cases in the experimental group and 355 cases in the control group. Meta-analysis showed that compared with conventional treatment, acupuncture combined with conventional treatment was beneficial in improving the total clinical efficacy (odds ratioâ =â 3.55 [95% confidence interval {CI}: 1.34-9.37], Pâ <â .001). We found acupuncture-assisted therapy could be beneficial in improving the Modified Barthel Index (MDâ =â 10.48 [95% CI: 4.78-16.19], Pâ <â .001) and reducing anxiety or depression scores (such as the Self-Rating Anxiety Scale [MDâ =â -6.08 {95% CI: -6.85 to -5.30}, Pâ <â .001]; reducing the Self-Rating Depression Scale [MDâ =â -6.01 {95% CI: -6.95 to -5.07}, Pâ <â .001]). In addition, the study showed that the application of acupuncture treatment could improve 5-hydroxytryptamine compared to control group (MDâ =â 44.99 [95% CI: 40.04-49.95], Pâ <â .001) and reduce TNF-α compared to control group (MDâ =â -7.78 [95% CI: -8.73 to -6.83], Pâ <â .001). CONCLUSION: Acupuncture could be used as a complementary therapy to reduce anxiety and depression in spinal cord injury patients. Further original and high-quality research is needed to verify the conclusions of this study.
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Terapia por Acupuntura , Ansiedade , Depressão , Traumatismos da Medula Espinal , Humanos , Terapia por Acupuntura/métodos , Ansiedade/terapia , Ansiedade/etiologia , Depressão/terapia , Depressão/etiologia , Metanálise como Assunto , Qualidade de Vida , Projetos de Pesquisa , Traumatismos da Medula Espinal/complicações , Traumatismos da Medula Espinal/psicologia , Traumatismos da Medula Espinal/terapia , Revisões Sistemáticas como Assunto , Resultado do TratamentoRESUMO
Excess nitrogen and phosphorus inputs are the main causes of aquatic environmental deterioration. Accurately quantifying and dynamically assessing the regional nitrogen and phosphorus pollution emission (NPPE) loads and influencing factors is crucial for local authorities to implement and formulate refined pollution reduction management strategies. In this study, we constructed a methodological framework for evaluating the spatio-temporal evolution mechanism and dynamic simulation of NPPE. We investigated the spatio-temporal evolution mechanism and influencing factors of NPPE in the Yangtze River Economic Belt (YREB) of China through the pollution load accounting model, spatial correlation analysis model, geographical detector model, back propagation neural network model, and trend analysis model. The results show that the NPPE inputs in the YREB exhibit a general trend of first rising and then falling, with uneven development among various cities in each province. Nonpoint sources are the largest source of land-based NPPE. Overall, positive spatial clustering of NPPE is observed in the cities of the YREB, and there is a certain enhancement in clustering. The GDP of the primary industry and cultivated area are important human activity factors affecting the spatial distribution of NPPE, with economic factors exerting the greatest influence on the NPPE. In the future, the change in NPPE in the YREB at the provincial level is slight, while the nitrogen pollution emissions at the municipal level will develop towards a polarization trend. Most cities in the middle and lower reaches of the YREB in 2035 will exhibit medium to high emissions. This study provides a scientific basis for the control of regional NPPE, and it is necessary to strengthen cooperation and coordination among cities in the future, jointly improve the nitrogen and phosphorus pollution tracing and control management system, and achieve regional sustainable development.
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Monitoramento Ambiental , Nitrogênio , Fósforo , Rios , Análise Espaço-Temporal , Poluentes Químicos da Água , Fósforo/análise , China , Nitrogênio/análise , Rios/química , Poluentes Químicos da Água/análise , Poluição Química da Água/estatística & dados numéricosRESUMO
Real-time monitoring of biocatalytic-based processes is significantly improved and simplified when they can be visualized. Visual monitoring can be achieved by integrating a fluorescent unit with the biocatalyst. Herein, we outline the design strategies of fluorescent probes for monitoring biocatalysis: (1) probes for monitoring biocatalytic transfer: γ-glutamine is linked to the fluorophore as both a recognition group and for intramolecular charge transfer (ICT) inhibition; the probe is initially in an off state and is activated via the transfer of the γ-glutamine group and the release of the free amino group, which results in restoration of the "Donor-π-Acceptor" (D-π-A) system and fluorescence recovery. (2) Probes for monitoring biocatalytic oxidation: a propylamine is connected to the fluorophore as a recognition group, which cages the hydroxyl group, leading to the inhibition of ICT; propylamine is oxidized and subsequently ß-elimination occurs, resulting in exposure of the hydroxyl group and fluorescence recovery. (3) Probes for monitoring biocatalytic reduction: a nitro group attached to a fluorophore as a fluorescence quenching group, this is converted to an amino group by catalytic reduction, resulting in fluorescence recovery. (4) Probes for monitoring biocatalytic hydrolysis: ß-D-galactopyranoside or phosphate acts as a recognition group attached to hydroxyl groups of the fluorophore; the subsequent biocatalytic hydrolysis reaction releases the hydroxyl group resulting in fluorescence recovery. Following these 4 mechanisms, fluorophores including cyanine, coumarin, rhodamine, and Nile-red, have been used to develop systems for monitoring biocatalytic reactions. We anticipate that these strategies will result in systems able to rapidly diagnose and facilitate the treatment of serious diseases.
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Corantes Fluorescentes , Glutamina , Biocatálise , Rodaminas , PropilaminasRESUMO
Mechanical response luminescence (MRL) describes the photophysical properties triggered by mechanical stimulation. Usually, MRL can be regulated by intermolecular interactions, molecular conformation or molecular packing, to achieve the desirable optical properties. Herein, at the molecular level, this review covers the factors that influence mechanically responsive fluorescent materials, involving the single- or multifactorial modulation of aliphatic chains, donor-receptor switch, substituent adjustment, and position isomerism. According to these factors, the structure-activity strategies can be summarized as: (i) the self-recovery of optical properties, from the final to initial state, can be regulated by introducing long alkyl chains to a fluorophore. (ii) The sensitivity of MRL materials can be controlled by modifying the donor-acceptor structure via the changed ICT (intramolecular charge transfer) and intramolecular interaction. (iii) The electronic and steric effects of substituents can affect ICT and intermolecular interactions, thereby resulting in high quantum yield and high-contrast MRL materials via changing the molecular stacking of crystalline states. (iv) Intermolecular interaction is modulated by the position isomerism of the substituents, which results in switched molecular packing for the extended response toward a wide range of stimuli. It is anticipated that the molecular mechanisms of these structure-activity relationships will serve as a significant reference for developing novel, high contrast, recyclable mechanical response luminous materials.
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In this paper, a scheduling model of PVC production by a calcium carbide method is designed based on a continuous-time modeling method, and an improved mixed-integer nonlinear programming (MINLP) model for scheduling of PVC production is proposed. The optimization goal is to minimize the total cost. Considering the practical requirements of both the solution rapidity and quality, a combined algorithm is further established using both the MINLP model and approximated mixed-integer linear program (MILP) model for PVC production scheduling. The optimization result of the linear model is substituted into the original MINLP model as the initial value of variables to accelerate the solution process. Then, the optimal solution of the improved model is executed. Afterward, the effectiveness of the proposed method is verified with two actual cases. The comparative results demonstrate that the proposed algorithm can significantly accelerate the computation and obtain more accurate optimal solution.
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Despite multiple immunotherapeutic technologies that achieve potent T cell activation, effector T cells still lack efficiency because of the highly immunosuppressive conditions in the tumor microenvironment. Inspired by recent advances in nano-sized secreted vesicles known as exosomes as therapeutic agents and research revealing that circulating cancer cells have a "homing" capacity to return to the main tumor sites, we generated macrophage-tumor hybrid cells. We introduced nuclei isolated from tumor cells into activated M1-like macrophages to produce chimeric exosomes (aMT-exos). The aMT-exos were able to accumulate in both lymph nodes and diverse tumors of xenograft mice. They entered lymph nodes and primed T cell activation in both the classical antigen-presenting cellinduced immunostimulatory manner and a unique "direct exosome interaction" manner. aMT-exos also had strong "homing behavior" to tumor sites, where they ameliorated immunosuppression. They were effective in inducing tumor regression and extending survival in primary mouse models of lymphoma and breast and melanoma cancers. In addition, when combined with antiprogrammed death 1 (a-PD1) treatment, aMT-exos were able to extend survival of metastatic and postsurgical tumor recurrence mouse models. Such a coactivation of the immune response and the tumor microenvironment enabled aMT-exos to confer efficient inhibition of primary tumors, tumor metastases, and postoperative tumor recurrence for personalized immunotherapy, which warrants further exploration in the clinical setting.
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Exossomos , Neoplasias , Humanos , Imunidade , Linfonodos , Macrófagos , Microambiente TumoralRESUMO
The poor understanding of the complex multistep process taken by nanocarriers during the delivery process limits the delivery efficiencies and further hinders the translation of these systems into medicine. Here, we describe a series of six self-assembled nanocarrier types with systematically altered physical properties including size, shape, and rigidity, as well as both in vitro and in vivo analyses of their performance in blood circulation, tumor penetration, cancer cell uptake, and anticancer efficacy. We also developed both data and simulation-based models for understanding the influence of physical properties, both individually and considered together, on each delivery step and overall delivery process. Thus, beyond finding that nanocarriers that are simultaneously endowed with tubular shape, short length, and low rigidity outperformed the other types, we now have a suit of theoretical models that can predict how nanocarrier properties will individually and collectively perform in the multistep delivery of anticancer therapies.
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Therapeutic leukaemia vaccines have shown modest potency. Here, we show that the co-encapsulation of a leukaemia-associated epitope peptide highly expressed in leukaemia patients and of the immune checkpoint inhibitor anti-programmed-cell-death-protein-1 (anti-PD-1) in degradable poly(lactic acid) microcapsules resulted in the sustained release of the peptide and of the antibody, which led to the recruitment of activated antigen-presenting cells to the injection site, their uptake of the peptide and the transportation of the anti-PD-1 antibody to lymph nodes, enhancing the expansion of epitope-specific T cells and the activation of cytotoxic T cells. After single subcutaneous injections of vaccine formulations with different epitope peptides, mice bearing leukaemia xenografts derived from humanized cell lines or from primary cells from patients showed better therapeutic outcomes than mice receiving repeated injections of free antigen, antibody and a commercial adjuvant. The sustained release of a tumour-associated peptide and of anti-PD-1 may represent a generalizable strategy for boosting antitumour immune responses to leukaemia.
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Células Apresentadoras de Antígenos/imunologia , Antineoplásicos Imunológicos/química , Vacinas Anticâncer/administração & dosagem , Epitopos/química , Leucemia/terapia , Animais , Antineoplásicos Imunológicos/imunologia , Vacinas Anticâncer/farmacologia , Cápsulas , Linhagem Celular Tumoral , Preparações de Ação Retardada , Epitopos/imunologia , Feminino , Humanos , Injeções Subcutâneas , Células K562 , Leucemia/imunologia , Camundongos , Poliésteres/química , Receptor de Morte Celular Programada 1/antagonistas & inibidores , Linfócitos T Citotóxicos/imunologia , Resultado do Tratamento , Ensaios Antitumorais Modelo de XenoenxertoRESUMO
The highly immunosuppressive tumor microenvironment (TME) in solid tumors often dampens the efficacy of immunotherapy. In this study, bacterial outer membrane vesicles (OMVs) are demonstrated as powerful immunostimulants for TME reprogramming. To overcome the obstacles of antibody-dependent clearance and high toxicity induced by OMVs upon intravenous injection (a classic clinically relevant delivery mode), calcium phosphate (CaP) shells are employed to cover the surface of OMVs, which enables potent OMV-based TME reprograming without side effects. Meanwhile, the pH-sensitive CaP shells facilitate the neutralization of acidic TME, leading to highly beneficial M2-to-M1 polarization of macrophages for improved antitumor effect. Moreover, the outer shells can be integrated with functional components like folic acid or photosensitizer agents, which facilitates the use of the OMV-based platform in combination therapies for a synergic therapeutic effect.
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Adjuvantes Imunológicos/farmacologia , Membrana Externa Bacteriana/metabolismo , Biomineralização , Vesículas Extracelulares/metabolismo , Imunoterapia/métodos , Segurança , Microambiente Tumoral/imunologia , Macrófagos/efeitos dos fármacos , Macrófagos/imunologiaRESUMO
Nanovaccines have attracted booming interests in vaccinology studies, but the profound impacts of their delivery mode on immune response remain unrealized. Herein, immunostimulatory CpG-modified tumor-derived nanovesicles (CNVs) are used as a nanovaccine testbed to initially evaluate the impacts of three distinct delivery modes, including mono-pulse CNVs, staggered-pulse CNVs, and gel-confined CNVs. Fundamentally, delivery mode has enormous impacts on the immunomodulatory effects, altering the spatiotemporal distribution of nanovaccine residence and dendritic cell-T cell interaction in lymph nodes, and finally affecting subsequent T cell-mediated immune performance. As a result, the gel-confined delivery mode offers the best therapeutic performance in multiple tumor models. When extending evaluation to examine how the various delivery modes impact the performance of liposome-based nanovaccines, similar trends in intralymph node distribution and antitumor effect are observed. This work provides a strong empirical foundation that nanovaccine researchers should position delivery mode near the top of their considerations for the experimental design, which should speed up nanovaccine development and facilitate efficient selection of appropriate delivery modes in the clinic.
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Recent years have seen enormous advances in nanovaccines for both prophylactic and therapeutic applications, but most of these technologies employ chemical or hybrid semi-biosynthetic production methods. Thus, production of nanovaccines has to date failed to exploit biology-only processes like complex sequential post-translational biochemical modifications and scalability, limiting the realization of the initial promise for offering major performance advantages and improved therapeutic outcomes over conventional vaccines. A Nano-B5 platform for in vivo production of fully protein-based, self-assembling, stable nanovaccines bearing diverse antigens including peptides and polysaccharides is presented here. Combined with the self-assembly capacities of pentamer domains from the bacterial AB5 toxin and unnatural trimer peptides, diverse nanovaccine structures can be produced in common Escherichia coli strains and in attenuated pathogenic strains. Notably, the chassis of these nanovaccines functions as an immunostimulant. After showing excellent lymph node targeting and immunoresponse elicitation and safety performance in both mouse and monkey models, the strong prophylactic effects of these nanovaccines against infection, as well as their efficient therapeutic effects against tumors are further demonstrated. Thus, the Nano-B5 platform can efficiently combine diverse modular components and antigen cargos to efficiently generate a potentially very large diversity of nanovaccine structures using many bacterial species.
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Nanopartículas , Proteínas/química , Proteínas/imunologia , Vacinação , Antígenos/imunologia , Proteínas/metabolismoRESUMO
Therapeutic cancer vaccines that harness the immune system to reject cancer cells have shown great promise for cancer treatment. Although a wave of efforts have spurred to improve the therapeutic effect, unfavorable immunization microenvironment along with a complicated preparation process and frequent vaccinations substantially compromise the performance. Here, we report a novel microcapsule-based formulation for high-performance cancer vaccinations. The special self-healing feature provides a mild and efficient paradigm for antigen microencapsulation. After vaccination, these microcapsules create a favorable immunization microenvironment in situ, wherein antigen release kinetics, recruited cell behavior, and acid surrounding work in a synergetic manner. In this case, we can effectively increase the antigen utilization, improve the antigen presentation, and activate antigen presenting cells. As a result, effective T cell response, potent tumor inhibition, antimetastatic effects, and prevention of postsurgical recurrence are achieved with various types of antigens, while neoantigen was encapsuled and evaluated in different tumor models.
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Vacinas Anticâncer , Neoplasias , Cápsulas , Humanos , Imunização , Neoplasias/terapia , Microambiente Tumoral , VacinaçãoRESUMO
A novel micromachined z-axis torsional accelerometer based on the tunneling magnetoresistive effect is presented in this paper. The plane main structure bonded with permanent magnetic film is driven to twist under the action of inertial acceleration, which results in the opposite variation of the magnetic field intensity. The variation of the magnetic field is measured by two differential tunneling magnetoresistive sensors arranged on the top substrate respectively. Electrostatic feedback electrodes plated on the bottom substrate are used to revert the plane main structure to an equilibrium state and realize the closed-loop detection of acceleration. A modal simulation of the micromachined z-axis tunneling magnetoresistive accelerometer was implemented to verify the theoretical formula and the structural optimization. Simultaneously, the characteristics of the magnetic field were analyzed to optimize the layout of the tunneling magnetoresistance accelerometer by finite element simulation. The plane main structure, fabricated with the process of standard deep dry silicon on glass (DDSOG), had dimensions of 8000 µm (length) × 8000 µm (width) × 120µm (height). A prototype of the micromachined z-axis tunneling magnetoresistive accelerometer was produced by micro-assembly of the plane main structure with the tunneling magnetoresistive sensors. The experiment results demonstrate that the prototype has a maximal sensitivity of 1.7 mV/g and an acceleration resolution of 128 µg/Hz0.5 along the z-axis sensitive direction.
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Enzymatic catalysis in living cells enables the in-situ detection of cellular metabolites in single cells, which could contribute to early diagnosis of diseases. In this study, enzyme is packaged in amorphous metal-organic frameworks (MOFs) via a one-pot co-precipitation process under ambient conditions, exhibiting 5-20 times higher apparent activity than when the enzyme is encapsulated in corresponding crystalline MOFs. Molecular simulation and cryo-electron tomography (Cryo-ET) combined with other techniques demonstrate that the mesopores generated in this disordered and fuzzy structure endow the packaged enzyme with high enzyme activity. The highly active glucose oxidase delivered by the amorphous MOF nanoparticles allows the noninvasive and facile measurement of glucose in single living cells, which can be used to distinguish between cancerous and normal cells.
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Glucose Oxidase/metabolismo , Estruturas Metalorgânicas/química , Animais , Glucose/análise , Células Hep G2 , Humanos , Células MCF-7 , Camundongos , Nanocompostos/química , Nanocompostos/ultraestrutura , PorosidadeRESUMO
Although the antimonene (AM) nanomaterial is recently emerging as a new photothermal therapy (PTT) agent, its rapid degradation in physiological medium immensely limits its direct utilization. To this end, we herein engineered AM by the cooperation of dimension optimization, size control, and cell membrane (CM) camouflage. Compared with traditional AM nanosheets, the resulting AM nanoparticles (â¼55 nm) cloaked with the CM (denoted as CmNPs) exhibited significantly improved stability and increased photothermal efficacy as well as superior tumor targeting capacity. After intravenous injection, the CmNPs enabled satisfactory photoacoustic/photothermal multimodal imaging at tumor sites. Meanwhile, the PTT together with the newly explored function of photodynamic therapy (PDT) achieved a potent combination therapy with few side effects. The maximized theranostic performance thus strongly recommends CmNPs as a safe and highly reliable modality for anticancer therapy.
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A novel cancer vaccine is developed by using Fe3O4 magnetic nanoclusters (MNCs) as the core and cancer cell membranes decorated with anti-CD205 as the cloak. Because of the superparamagnetism and magnetization of MNCs, it is first achieved for the magnetic retention of vaccine in the lymph nodes with a magnetic resonance imaging (MRI) guide, which opened the time window for antigen uptake by dendritic cells (DCs). Meanwhile, the camouflaged cancer cell membranes serve as a reservoir of various antigens, enabling subsequent multiantigenic response. Additionally, the decorated anti-CD205 direct more vaccine into CD8+ DCs, facilitating the major histocompatibility complex (MHC) I cross-presentation. These unique advantages together lead to a great proliferation of T cells with superior clonal diversity and cytotoxic activity. As a result, potent prophylactic and therapeutic effects with few abnormalities are observed on five different tumor models. Therefore, such a cancer-derived magnetosome with the integration of various recent nanotechnologies successfully demonstrates its promise for safe and high-performance cancer vaccination.
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As traditional anticancer treatments fail to significantly improve the prognoses, exploration of therapeutic modalities is urgently needed. Herein, a biomimetic magnetosome is constructed to favor the ferroptosis/immunomodulation synergism in cancer. This magnetosome is composed of an Fe3O4 magnetic nanocluster (NC) as the core and pre-engineered leukocyte membranes as the cloak, wherein TGF-ß inhibitor (Ti) can be loaded inside the membrane and PD-1 antibody (Pa) can be anchored on the membrane surface. After intravenous injection, the membrane camouflage results in long circulation, and the NC core with magnetization and superparamagnetism enables magnetic targeting with magnetic resonance imaging (MRI) guidance. Once inside the tumor, Pa and Ti cooperate to create an immunogenic microenvironment, which increases the amount of H2O2 in polarized M1 macrophages and thus promotes the Fenton reaction with Fe ions released from NCs. The generated hydroxyl radicals (â¢OH) subsequently induce lethal ferroptosis to tumor cells, and the exposed tumor antigen, in turn, improves the microenvironment immunogenicity. The synergism of immunomodulation and ferroptosis in such a cyclical manner therefore leads to potent therapeutic effects with few abnormalities, which supports the engineered magnetosomes as a promising combination modality for anticancer therapy.
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Ferroptose/efeitos dos fármacos , Fatores Imunológicos/farmacologia , Nanopartículas de Magnetita/química , Neoplasias/tratamento farmacológico , Antígenos de Neoplasias/farmacologia , Sinergismo Farmacológico , Humanos , Peróxido de Hidrogênio/química , Peróxido de Hidrogênio/farmacologia , Fatores Imunológicos/química , Imunomodulação/efeitos dos fármacos , Nanopartículas de Magnetita/administração & dosagem , Magnetossomos/química , Magnetospirillum/efeitos dos fármacos , Neoplasias/patologia , Microambiente Tumoral/efeitos dos fármacosRESUMO
This paper presents the design, simulation, fabrication and experiments of a micromachined z-axis tunneling magnetoresistive accelerometer with electrostatic force feedback. The tunneling magnetoresistive accelerometer consists of two upper differential tunneling magnetoresistive sensors, a middle plane main structure with permanent magnetic films and lower electrostatic feedback electrodes. A pair of lever-driven differential proof masses in the middle plane main structure is used for sensitiveness to acceleration and closed-loop feedback control. The tunneling magnetoresistive effect with high sensitivity is adopted to measure magnetic field variation caused by input acceleration. The structural mode and mass ratio between inner and outer proof masses are optimized by the Ansys simulation. Simultaneously, the magnetic field characteristic simulation is implemented to analyze the effect of the location of tunneling magnetoresistive sensors, magnetic field intensity, and the dimension of permanent magnetic film on magnetic field sensitivity, which is beneficial for the achievement of maximum sensitivity. The micromachined z-axis tunneling magnetoresistive accelerometer fabricated by the standard deep dry silicon on glass (DDSOG) process has a device dimension of 6400 µm (length) × 6400 µm (width) × 120 µm (height). The experimental results demonstrate the prototype has a maximal sensitivity of 8.85 mV/g along the z-axis sensitive direction under the gap of 1 mm. Simultaneously, Allan variance analysis illustrate that a noise floor of 86.2 µg/Hz0.5 is implemented in the z-axis tunneling magnetoresistive accelerometer.