Effect Of Radiation Treatment Research Articles

Effects of Colchicine and 60Co-γ Radiation Treatments on the Leaf Size and Fruit Quality of Kiwifruit ‘Donghong’

Colchicine and 60Co-γ radiation are commonly used breeding techniques for kiwifruit, offering advantages such as low cost, rapid execution, and high efficiency. The buds of red-fleshed kiwifruit (Actinidia chinensis) cv. ‘Donghong’ were used as experimental material and subjected to different concentrations of colchicine and different doses of 60Co-γ radiation, respectively. Then, the buds were grafted on rootstock, and the ploidy, leaf size, and fruit quality of mutant fruit were evaluated, and principal component analysis (PCA) and simple sequence repeat markers were used to comprehensively assess and detect genetic variations, respectively. The results indicated that a total of 19 buds successfully germinated, with 13 branches successfully bearing fruit. Significant changes were observed in both leaf and fruit morphology following the mutation treatments. Most of the mutant materials showed significant increases in fruit weight, flesh firmness, and soluble sugar content, while titratable acidity and ascorbic acid content significantly decreased. Notably, the 25Gy 60Co-γ radiation (25d) treatment demonstrated outstanding results, with fruit weight increasing by 256.10%, soluble sugar content rising by 88.29%, titratable acidity decreasing by 29.86%, and ascorbic acid content increasing by 35.60%. PCA results showed that the 25d mutant had the best comprehensive traits. And, except for the 0.4c mutant, all other mutant materials exhibited significant genetic changes at the DNA level.

Effect of glass fiber hybridization and radiation treatment to improve the performance of sustainable natural fiber-based hybrid (jute/glass) composites

Effect of glass fiber hybridization and radiation treatment to improve the performance of sustainable natural fiber-based hybrid (jute/glass) composites

Enhancing the Efficacy of Radiation Therapy by Photochemical Internalization of Fibrin-Hydrogel-Delivered Bleomycin.

Although the use of radiation-sensitizing agents has been shown to enhance the effect of radiation on tumor cells, the blood-brain barrier (BBB) impedes these agents from reaching brain tumor sites when provided systemically. Localized methods of sensitizer delivery, utilizing hydrogels, have the potential to bypass the blood-brain barrier. This study examined the ability of photochemical internalization (PCI) of hydrogel-released bleomycin to enhance the growth-inhibiting effects of radiation on multi-cell glioma spheroids in vitro. Loaded fibrin hydrogel layers were created by combining thrombin, fibrinogen, and bleomycin (BLM). Supernatants from these layers were collected, combined with photosensitizer, and added to F98 glioma spheroid cultures. Following light (PCI) and radiation treatment, at increasing dosages, spheroid growth was monitored for 14 days. PCI of released BLM significantly reduced the radiation dose required to achieve equivalent efficacy compared to radiation or BLM + RT alone. Both immediate and delayed RT delivery post-BLM-PCI resulted in similar degrees of growth inhibition. Non-degraded BLM was released from the fibrin hydrogel. PCI of BLM synergistically increased the growth-inhibiting effects of radiation treatment compared to radiation and BLM, as well as radiation acting as a single treatment.

Magnetic resonance imaging techniques for monitoring glioma response to chemoradiotherapy.

Treatment response assessment for gliomas currently uses changes in tumour size as measured with T1- and T2-weighted MRI. However, changes in tumour size may occur many weeks after therapy completion and are confounded by radiation treatment effects. Advanced MRI techniques sensitive to tumour physiology may provide complementary information to evaluate tumour response at early timepoints during therapy. The objective of this review is to provide a summary of the history and current knowledge regarding advanced MRI techniques for early treatment response evaluation in glioma. The literature survey included perfusion MRI, diffusion-weighted imaging, quantitative magnetization transfer imaging, and chemical exchange transfer MRI. Select articles spanning the history of each technique as applied to treatment response evaluation in glioma were chosen. This report is a narrative review, not formally systematic. Chemical exchange saturation transfer imaging potentially offers the earliest method to detect tumour response due to changes in metabolism. Diffusion-weighted imaging is sensitive to changes in tumour cellularity later during radiotherapy and is prognostic for progression-free and overall survival. Substantial evidence suggests that perfusion MRI can differentiate between tumour recurrence and treatment effect, but consensus regarding acquisition, processing, and interpretation is still lacking. Magnetization transfer imaging shows promise for detecting subtle white matter damage which could indicate tumour invasion, but more research in this area is needed. Advanced MRI techniques show potential for early treatment response assessment, but each technique alone lacks specificity. Multiparametric imaging may be necessary to aid biological interpretation and enable treatment guidance.

EVALUATION OF THE EFFICIENCY OF PROCESSING BEEF, FISH AND FISH SEMI-FINISHED PRODUCTS USING THE ILU-10 ELECTRON ACCELERATOR, DEPENDING ON THE DOSIMETRIC PARAMETERS IN RELATION TO CLOSTRIDIUM SPP

This article presents the results of a study the effectiveness of radiation treatment using the ILU-10 electron accelerator in order to extend the shelf life of food products by controlling bacterial contamination (sulfite-reducing clostridium – Clostridium spp.). The ILU-10 device is designed for sterilization and disinfection of products without the use of chemicals. Clostridia spp. are an important indicator of microbiological control in the food industry. They are the cause of food spoilage, and some types of clostridium can cause massive disease of the human digestive system. The aim of the study was to evaluate the effectiveness of this device in reducing of Clostridium spp. with different radiation doses in the range from 3 to 9 kGr. It was found that a dose of 3 kGr is sufficient to reduce bacterial contamination of beef, fish (pike), and fish cutlets. In general, the maximum antibacterial effect was achieved at three doses.

Ultrasound-stimulated microbubbles to enhance radiotherapy: A scoping review.

Primarily used as ultrasound contrast agents, microbubbles have recently emerged as a versatile therapeutic vector that can be 'burst' to deliver payloads in the presence of suitably optimised ultrasound fields. Ultrasound-stimulated microbubbles (USMB) have recently demonstrated improvements in treatment outcomes across a variety of clinical applications. This scoping review investigates whether this potential translates into the context of radiation therapy by evaluating the application of this technology across all three phases of radiation action. Primary research articles, excluding poster presentations and conference proceedings, were identified through systematic searches of the PubMed NCBI/Medline, Embase/OVID, Web of Science and CINAHL/EBSCOhost databases, with additional articles identified via manual Google Scholar searching. Articles were dual screened for inclusion using the Covidence systematic review platform and classified against all three phases of radiation action. Overall, 57 eligible publications from a total of 1389 identified articles were included in the review, with studies dating back to 2012. Study heterogeneity prevented formal statistical analysis; however, most articles reported improved outcomes using USMB in the presence of radiation compared to that of radiation alone. These improvements appear to result from the use of USMB as either a biovascular disruptor causing tumour cell damage via indirect mechanisms, or as a localised treatment vector that directly increases tumour cell uptake of other therapeutic and physical agents designed to enhance radiation action. USMB demonstrate exciting potential to enhance the effects of radiation treatments due to their versatility and capacity to targetall three phases of radiation action.

Gd-GQDs as nanotheranostic platform for the treatment of HPV-positive oropharyngeal cancer.

In this study, we developed new gadolinium-graphene quantum dot nanoparticles (Gd-GQDs) as a theranostic platform for magnetic resonance imaging and improved the efficiency of radiotherapy in HPV-positive oropharyngeal cancer. Based on cell toxicity results, Gd-GQD NPs were nontoxic for both cancer and normal cell lines up to 25µg/ml. These NPs enhance the cytotoxic effect of radiation only on cancer cells but not on normal cells. The flow cytometry analysis indicated that cell death mainly occurred in the late phase of apoptosis. The immunocytochemical analysis was used to evaluate apoptosis pathway proteins. The Bcl-2 and p53 protein levels did not differ statistically significantly between radiation alone group and those that received irradiation in combination with NPs. In contrast, the combination group exhibited a significant increase in Bax protein expression, suggesting that cells could undergo apoptosis independent of the p53 pathway. Magnetic resonance (MR) imaging showed that Gd-GQD NPs, when used at low concentrations, enhanced T1-weighted signal intensity resulting from T1 shortening effects. At higher concentrations, the T2 shortening effect became predominant and was able to decrease the signal intensity. Gd-GQD appears to offer a novel approach for enhancing the effectiveness of radiation treatment and facilitating MR imaging for monitoring HPV-positive tumors.

Effect of Chemotherapy and Radiation Treatment on Body System among Women Suffering from Cervical Cancer.

Effect of Chemotherapy and Radiation Treatment on Body System among Women Suffering from Cervical Cancer.

Determination of correction factors and correction coefficients for calculations of the absorbed dose

The need to control the dose received by a patient during radiation therapy (RT) is dictated by the quality assurance requirements, which encompass a broad system of organizational and technical measures aimed at achieving consistency and precision in dosimetry measurements. The ultimate goal of using a quality assurance system in RT is to ensure high accuracy in delivering the dose to the tumour, reducing the irradiation volumes of normal, healthy tissues and organs near the target (tumour lesion). It has been established that to enhance the effectiveness of radiation treatment and to reduce the number of complications in subsequent periods, it is necessary to irradiate the local target in the patient’s body with a dose error no greater than ±5%. To control the calculation of the absorbed dose in water using thermoluminescent (TL) dosimeters, irradiated on a gamma therapeutic device for remote radiation therapy, it is necessary to study the influence of various factors (fading, non-linearity of indications, energy dependence, reproduction of the TL signal, presence of a holder) on the magnitude of the TL signal. We have studied and identified various corrective factors and their error values that may affect the calibration of the system (TLD-100 powder (Rexon), thermoluminescent reader PCL-3). In determining the corrective factors to account for the daily drift of the PCL-3 device, the TL signal obtained during the exposure was adjusted based on the control powder indicators. As a control powder, TLD-100 (Rexon) was used, irradiated with an absorbed dose of 2 Gy under standard conditions and aged four months to obtain a stable TL signal.

Comparative study of volatile components of soybean oil exposed to heating, ionizing and non-ionizing radiation

Heating and various radiation treatments have been widely used in the storage and processing of oilseeds. To compare the degradation effects of heating and different radiation treatments on oils, refined soybean oil was heated or radiated with γ-rays, microwave, ultraviolet and sunlight, while the oxidation indices, fatty acid composition and volatile constituents of the oils were analyzed. The results showed that all treatments had no significant effect on acid value and fatty acid composition, but oxidation indices (peroxide value, K232 and K268) were increased, especially for samples subjected to γ-rays and microwave radiation. The volatile components were analyzed using simultaneous distillation extraction combined with gas chromatography-mass spectrometry (SDE/GC-MS). A total of 82 volatile compounds were identified, including 18 alkanes, 19 alkenes, 30 aldehydes, 5 ketones, 4 alcohols, 2 furans and 4 benzenes. Principal component analysis (PCA) and hierarchical cluster analysis (HCA) showed that there were significant differences in the volatile composition profiles of the oils after different treatments. The oils treated with gamma irradiation contained more alkenes, those treated with microwave radiation were rich in aldehydes, and those treated with sunlight radiation contained more alkanes.

Tissue-Specific Quantification of Radiation-Induced Cervical Fibrosis and Correlation with Cervical Range of Motion.

Cervical fibrosis (CF) as a late consequence in patients after radiotherapy significantly impacts the long-term symptoms, functionality, and quality of life of these cancer patients due to a hardening process of different histological tissues. Modern Shear Wave Ultrasound Elastography now enables a differentiated analysis of the changes in various tissue types. In this study, tissue-specific changes in CF induced by radiation therapy in head and neck (ENT) cancer patients were quantified and correlated with cervical range of motion (CROM). 16 patients after radiation of the cervical lymphatic drainage were selected as the observation group (OG). Further, 16 people without radiation in the head and neck region were matched by gender, age, and BMI as the control group (CG). Stiffness measurements in kilopascal (kPa; 1 Pa = 1 N m-2) were performed using shear wave elastography (SWE) to assess the elasticity of muscle, fascia, and subcutaneous tissue within and surrounding the sternocleidomastoid muscle (SCM). Specific parameters of the OG were compared to the CG and correlated with functional parameters and quality of life (QoL). The OG exhibited significantly higher stiffness values (Emean, Emax, Emin) across all tissue types than the CG, suggesting a tangible effect of radiation therapy on tissue stiffness. Muscle compartment analysis revealed the most significant stiffness differences. Thickness measurements indicated changes in the muscle and skin but not in the subcutaneous tissue. CROM measurements within the OG fell within normal ranges, suggesting a possible homogenizing effect of radiation treatment on CROM variability. Strong correlations were observed between age and specific stiffness measures, particularly in the OG group, indicating a broader impact of aging or radiation therapy on physiological measures. Significant correlations between tissue stiffness and CROM were found. CF after radiotherapy occurs primarily in the muscle tissue and its fascia, with the hardening being about twice as pronounced as in the average population and becoming more pronounced with increasing age and correlates with CROM.

Effects of combined radiotherapy with immune checkpoint blockade on immunological memory in luminal-like subtype murine bladder cancer model

ABSTRACT MIBC is a highly lethal disease, and the patient survival rate has not improved significantly over the last decades. UPPL is a cell line that can be used to recapitulate the luminal-like molecular subtype of bladder cancer and to discover effective treatments to be translated in patients. Here, we investigate the effects of combinational treatments of radiotherapy and immunotherapy in this recently characterized UPPL tumor-bearing mice. We first characterized the baseline tumor microenvironment and the effect of radiation, anti-PD-L1, and combinatorial treatments. Then, the mice were re-challenged with a second tumor (rechallenged tumor) in the contralateral flank of the first tumor to assess the immunological memory. Radiation slowed down the tumor growth. All treatments also decreased the neutrophil population and increased the T cell population. Anti-PD-L1 therapy was not able to synergize with radiation to further delay tumor growth. Furthermore, none of the treatments were able to generate immune memory. The treatments were not sufficient to induce a significant and lasting pool of memory cells. We show here that anti-PD-L1 treatment added to radiotherapy was not enough to achieve T cell-mediated memory in UPPL tumors. Stronger T cell activation signals may be required to enhance radiation efficacy in luminal-like bladder cancer.

PATIENT EDUCATION: Counseling of oral cancer patients

The purpose of this manuscript is to summarize key aspects of care for patients with advanced oral cancer, metastatic to the head and neck region. Patients with advanced oral cancer are treated with multimodal treatment. Surgical intervention leads to limitation in speech and swallowing abilities while adverse effects of chemotherapy and radiation treatment can include nausea, vomiting, diarrhea, mucositis, cystitis, dehydration, nephrotoxicity, skin dermatitis, myelosuppression, and nutritional deficiencies leading to weight loss. These toxicities could be overcome through self-care measures practiced by the patient. Oncology nurses could impart knowledge about self-care measures via patient and family counseling. Keywords: advanced oral cancer, head and neck cancer, counseling, self-care measures

Abstract 3757: The development of MAGMAS as a potential therapeutic target in temozolomide-resistant glioma

Abstract Glioblastoma (GBM) is one of the most aggressive types of brain cancer and remains a significant challenge for drug development in oncology today. Temozolomide (TMZ) is the standard of care for GBM, and resistance to this drug is modulated partly by the DNA repair enzyme O6-methylguanine-DNA methyltransferase (MGMT). Clinical studies demonstrated that low MGMT expression in GBM enhances sensitivity to TMZ and prolongs survival for patients. However, recent clinical studies indicate MGMT is a discordant biomarker since the predictive value of MGMT methylation is relatively low and there is a lack of modalities to inhibit MGMT expression. Furthermore, glioma stem cells (GSC) are another contributing factor for resistance due to tumor heterogeneity, self-renewal capacity and activation of DNA repair responses to overcome the effect of radiation and TMZ treatment. These resistance mechanisms contribute to tumor recurrence and present major impediments for the development of effective treatments. MAGMAS, 13.8 kDa mitochondria protein, is a translocase of the inner mitochondrial membrane and regulates oxidative phosphorylation. Specifically, MAGMAS regulates the ATP stimulatory activity of DNAJC19 on mtHSP70 that drives the movement of peptides through the TIM23 complex into the mitochondrial matrix. Recent evidence suggests that MAGMAS can regulate oxidative phosphorylation via interactions with the respiratory complexes present in the inner mitochondrial membrane. Previously, our lab has shown MAGMAS overexpression in malignant glioma tissues of patients and murine intracranial xenografts. Additionally, pharmacological inhibition of MAGMAS with the small molecule BT9 promoted cytotoxicity and impaired respiratory functions in malignant glioma cells demonstrating that MAGMAS is a promising potential target for GBM patients. However, further studies are needed to investigate the role of MAGMAS across the spectrum from initial tumorigenesis to disease progression and to further determine how MAGMAS is implicated during the development of treatment resistance. This study is designed to investigate the role of MAGMAS in GSCs and their contribution to TMZ resistance. We observed temozolomide-resistant (TR) U251-TR and D54 MG-TR GBM cell lines expressed significantly higher levels of MAGMAS and several stem cell markers than their drug-sensitive (S) parental cell lines. Therefore, we hypothesized that silencing MAGMAS re-sensitizes TR GBM cell lines to TMZ. We found that MAGMAS knockdown in D54-MG and U251 S/TR cells in the presence of escalating TMZ concentrations, caused enhanced sensitivity to TMZ. Consistent with these results, inhibition of MAGMAS with the novel BT9 inhibitor enhances the TMZ sensitivity in the TMZ-resistant cell lines. Additional studies of patient-derived cell lines are being utilized further to validate MAGMAS as it is an attractive target in TMZ-resistant GBM patients. Citation Format: Jennifer D. Tran, Javier J. Lepe, Maria C. Kenney, Bhaskar C. Das, Daniela A. Bota. The development of MAGMAS as a potential therapeutic target in temozolomide-resistant glioma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 3757.

Synthetic Curcumin Analogs in the Treatment of Cancer: A Literature Review.

Treatment of cancer, one of the most fatal diseases in the present century, has become a topic of global concern. Unfavorable unintentional effects of chemotherapy and radiation treatments have been the main reasons for the research on the discovery of drugs with a broader spectrum of effectiveness and efficiency, with minimal side effects. Curcumin (diferuloylmethane) is a naturally occurring phenolic structure with anticancer properties through its inhibition of cell multiplication, metastasis, and prolongation of cell cycle suppression of apoptosis in various tumor cells. The primary restriction regarding the use of curcumin in cancer treatment is related to poor bioavailability and unfavorable pharmacokinetic profiles of curcumin due to its poor absorption rate, fast metabolism, and systemic elimination. A variety of ways have been proposed to overcome these limitations. With this background, the present study focuses on providing a comprehensive overview of the anticancer properties of curcumin derivatives and the synthesis of curcumin analogs with application to different types of cancers. The regulation of various target and signaling pathways is considered in various cancers, including breast, gastrointestinal, pancreatic, prostate, skin, and lung cancers. A review of the literature indicates that modifying the structure of curcumin through the substitution of the phenyl group and unsaturated carbon branch around the two main sites of oxygen can result in the improvement of physical and chemical properties, as well as the enhancement of physiological activities of the curcumin molecule and the anti-cancer activities of this polyphenol. Curcumin analogs demonstrate anticancer properties at multiple targets at different cell stages and by various signaling biochemical pathways. These include cytokines, transcription factors, growth factors, and modulation of genes involved in cellular proliferation and apoptosis in breast, gastrointestinal, skin, prostate, and lung cancers, thereby mitigating tumor progression.

Effect of UV-C Radiation and Thermal Treatment on Volatile Compounds, Physicochemical, Microbiological and Phytochemical Parameters on Apple Juice (Malus domestica) with Raspberry (Rubus idaleus L.)

Volatile compounds contribute to aroma and flavor, these being the main sensory attributes in food acceptance. This work addresses the physicochemical, volatile compounds, polyphenols, and flavonoids content and, antioxidant activity of apple-raspberry (90/10%) juice treated by thermal and ultraviolet radiation (UV-C) alone or in combination with moderate heat-treatment. Nineteen volatile compounds were identified which experienced changes depending on the treatment. Compounds such as α-ionone and β-ionone, that contribute to raspberries characteristic aroma, were present in a greater concentration in the UV-C treatment and lower in the thermal treatment. Likewise, 2-methyl butyl acetate, which give a fruity-sweet aroma typical of apples was present in a greater concentration in the UV-C treatment. Regarding polyphenol content, control and combined treatment presented the greater concentrations. However, after twenty days of storage, control and combined treatment presented the lower flavonoid concentration. Nevertheless, at this time, treatments showed no variations in antioxidant activity. Yeast and mold and total aerobic mesophilic and psychrophilic counts were reduced in the heat and combined treatments. In conclusion, UV-C and moderate heat might successfully be used to process a stable apple-raspberry juice while maintaining its quality and safety.

Review effects of radiation treatment on HPV-related vulvar cancer: a meta-analysis and systematic review.

Vulvar carcinoma exhibits a robust correlation alongside HPV infection; however, the impact of HPV rank on the prognostic outcomes of radiation therapy within vulvar malignancies stays ambiguous. In the present study, we performed a comprehensive examination as well as meta-analysis to assess the influence of infection with HPV upon the long-term outlook as well as sensitivity of individuals with vulvar cancer undergoing radiation therapy. A meticulous examination of the existing research was conducted in accordance with the guidelines outlined in the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement. A thorough search was conducted in the PubMed, Embase, Web of Science, as well as Cochrane Library databases, covering the entire available literature till April 1, 2023. The studies that met the inclusion criteria contained data about HPV infection and oncological outcomes in patients with vulvar cancer who received radiation therapy. This study was registered in PROSPERO (CRD42023417957). We identified 12 retrospective studies meeting our inclusion criteria, which included a total of 3967 patients. Patients with HPV-associated vulvar cancer achieved a better overall survival rate after radiotherapy (HR=0.71, 95%CI: 0.54-0.93, P=0.01), and showed a significant improvement in disease-free survival (HR=0.75, 95%CI: 0.58-0.97, P=0.09) and progression-free survival (HR=0.31, 95%CI: 0.22-0.45, P,<0.01). Meanwhile, the complete remission rate after radiotherapy was higher for HPV-associated vulvar cancer patients (M-H=4.02, 95% CI: 1.87-8.61, P=0.0003), and the local control rate was better (HR=1.90, 95% CI: 1.15-3.15, P=0.01), exhibiting a reduced incidence of relapse within the field of study (HR=0.21, 95% CI: 0.10-0.42, P<0.001). In comparison to HPV-independent vulvar squamous cell carcinoma, patients with HPV-associated vulvar cancer exhibit higher sensitivity to radiotherapy, with a significant difference in prognosis. Further research should investigate the mechanisms underlying this high sensitivity to radiotherapy caused by HPV, and should be evaluated using high-quality randomized controlled trials.

Effect of phytosanitary radiation treatments on storage quality and microbiological safety of fresh table apricots (Prunus armeniaca L) Cv. CITH-2

Matured table apricots harvested at commercial maturity were irradiated in the dose range of 0.25-1.0 kGy and stored under refrigerated (3±1 0C, RH 85 %) conditions. The fruits were evaluated at intervals of 5 days for various physico-chemical parameters. Studies revealed that phytosanitary irradiation treatment maintained the storage quality of table apricots under refrigerated conditions. Positive correlations (r = 0.89) existed between irradiation treatment and firmness retention, whereas an inverse correlation (r = –0.86) existed between radiation and water-soluble pectin. Color scores revealed that L, a and b values increased by 13.1%, 68.9% and 21.5% in un-irradiated apricots compared to 6.1%, 44.9% and 14.1% in samples irradiated at 1.0 kGy, after 30 days of storage. During storage, ascorbic acid decreased by 86.8% in control compared to 56.2% in 1.0 kGy treated apricots. Phytosanitary radiation treatment at 1.0 kGy caused a significant (p ? 0.05) increase (7.5%) in total phenolics, besides minimizing subsequent degradation of phenols during storage. Microbial analysis indicated that in samples irradiated at 0.75 kGy and 1.0 kGy, no microbial load was detected up to 10 and 20 days of storage and resulted in about 1.0 log reduction in microbial load after 30 days of storage.

Radiation processing of dried Ker (Capparis deciduas): Effect on microbial safety and nutritional quality

Radiation processing of fresh and market (0-6 months old) dried ker at different doses of 2.5, 5.0 and 7.0 kGy was investigated. The effect of radiation treatment on total bacterial counts and nutritional quality parameters like moisture, protein, fat, ash, fibre, total sugar and starch contents were determined over a storage period of 3 months at ambient temperature. The findings of the study indicated that the radiation treatment reduces total bacterial counts in both fresh and market-dried ker at all doses. However, a dose of 5 kGy eliminated total bacterial counts in samples after storage. No significant changes were found in the proximate composition of both fresh and market-dried ker. On the contrary, total sugar content was observed to be increased in both control as well as irradiated samples during storage. Thus, radiation processing with 5.0 kGy did not affect significantly the nutritional quality of fresh and market-dried ker samples.

Metabolomics analysis of pathways underlying radiation-induced salivary gland dysfunction stages.

Salivary gland hypofunction is an adverse side effect associated with radiotherapy for head and neck cancer patients. This study delineated metabolic changes at acute, intermediate, and chronic radiation damage response stages in mouse salivary glands following a single 5 Gy dose. Ultra-high performance liquid chromatography-mass spectrometry was performed on parotid salivary gland tissue collected at 3, 14, and 30 days following radiation (IR). Pathway enrichment analysis, network analysis based on metabolite structural similarity, and network analysis based on metabolite abundance correlations were used to incorporate both metabolite levels and structural annotation. The greatest number of enriched pathways are observed at 3 days and the lowest at 30 days following radiation. Amino acid metabolism pathways, glutathione metabolism, and central carbon metabolism in cancer are enriched at all radiation time points across different analytical methods. This study suggests that glutathione and central carbon metabolism in cancer may be important pathways in the unresolved effect of radiation treatment.