Site Of Disease Research Articles

In situ‐crosslinked Zippersomes enhance cardiac repair by increasing accumulation and retention

AbstractMesenchymal stem cell (MSC)‐derived extracellular vesicles (EVs) are a promising treatment for myocardial infarction (MI), but their therapeutic efficacy is limited by inefficient accumulation at the target site. A minimally invasive MSC EV therapy that enhances EV accumulation at the disease site and extends EV retention could significantly improve post‐infarct cardiac regeneration. Here, we show that EVs decorated with the next‐generation of high‐affinity (HiA) heterodimerizing leucine zippers, termed HiA Zippersomes, amplify targetable surface areas through in situ crosslinking and exhibited ~7‐fold enhanced accumulation within the infarcted myocardium in mice after 3 days and continued to be retained up to Day 21, surpassing the performance of unmodified EVs. After MI in mice, HiA Zippersomes increase the ejection fraction by 53% and 100% compared with unmodified EVs and phosphate‐buffered saline (PBS), respectively. This notable improvement in cardiac function played a crucial role in restoring healthy heart performance. HiA Zippersomes also robustly decrease infarct size by 52% and 60% compared with unmodified EVs and PBS, respectively, thus representing a promising platform for minimally invasive vesicle delivery to the infarcted heart compared to intramyocardial injections.

Rapid in situ forming PEG hydrogels for mucosal drug delivery.

In situ gelling polymeric biomaterials have proven useful as drug delivery vehicles to enable sustained release at sites of disease or injury. However, if delivered to mucosal tissues, such as the eyes, nose, gastrointestinal, and cervicovaginal tract, these gels must also possess the ability to adhere to an epithelium coated in mucus. Towards this end, we report a new rapid in situ gelling polyethylene glycol-based hydrogel. Unlike other chemistries that enable rapid gel formation which form via irreversible covalent bonds, we use a bio-reducible linker allowing the gels to be naturally degraded over several days once administered. We identified a set of 6 lead formulations, which rapidly form into disulfide-linked PEG hydrogels in 30 seconds or less. These rapidly forming PEG hydrogels were also able to conform and adhere to mucosal tissues via PEG-mucin entanglements and hydrogen bonding. Controlled release of protein-based cargoes from the PEG gels was achieved over several hours whereas 40 nm nanoparticle-based cargos were retained over 24 hours. We also found these rapid in situ forming PEG gels were well-tolerated by mammalian cells. These studies support further testing and development of rapid in situ forming PEG gels for drug delivery to improve therapeutic retention and efficacy at mucosal sites.

Long-term patient-reported values following cancer surgery: A global survey study.

We evaluated the long-term quality of life (QOL) and priorities of an international cohort of cancer surgery survivors. Patients were surveyed through online support groups. We utilized the Short Form-12 questionnaire to evaluate QOL and a novel survey to assess the relative importance of longevity, experience, and costs. A total of 592 patients from six continents responded. They were 58 ± 12 years old, 70% female, and 92% White. Patients averaged 37 months from their initial cancer diagnosis, with a maximum survivorship of 46 years. Across 17 disease sites, respondents generally ranked longevity, functional independence, and emotional well-being most important, while treatment experience and costs were ranked least important (W = 33.6%, p < 0.001). However, a subset of respondents ranked costs as significantly important. There were no differences in QOL based on demographics, except patients with higher education and income reported better QOL scores. Despite improvements in QOL throughout survivorship, both physical-QOL (41.1 ± 11.1 at 1 year vs. 42.3 ± 12.6 at 5 years, p = 0.511) and mental-QOL (41.3 ± 13.4 at 1 year vs. 44.6 ± 13.9 at 5 years, p = 0.039) remained below that of the general population (50 ± 10; both p < 0.001). Cancer survivors experience enduring physical and mental impairment throughout survivorship. Future efforts should aim to provide sustained support across varied socioeconomic groups, ensuring equitable care and enhancement of QOL postcancer treatment.

Nucleic Acid Armor: Fortifying RNA Therapeutics through Delivery and Targeting Innovations for Immunotherapy.

RNA is a promising nucleic acid-based biomolecule for various treatments because of its high efficacy, low toxicity, and the tremendous availability of targeting sequences. Nevertheless, RNA shows instability and has a short half-life in physiological environments such as the bloodstream in the presence of RNAase. Therefore, developing reliable delivery strategies is important for targeting disease sites and maximizing the therapeutic effect of RNA drugs, particularly in the field of immunotherapy. In this mini-review, we highlight two major approaches: (1) delivery vehicles and (2) chemical modifications. Recent advances in delivery vehicles employ nanotechnologies such as lipid-based nanoparticles, viral vectors, and inorganic nanocarriers to precisely target specific cell types to facilitate RNA cellular entry. On the other hand, chemical modification utilizes the alteration of RNA structures via the addition of covalent bonds such as N-acetylgalactosamine or antibodies (antibody-oligonucleotide conjugates) to target specific receptors of cells. The pros and cons of these technologies are enlisted in this review. We aim to review nucleic acid drugs, their delivery systems, targeting strategies, and related chemical modifications. Finally, we express our perspective on the potential combination of RNA-based click chemistry with adoptive cell therapy (e.g., B cells or T cells) to address the issues of short duration and short half-life associated with antibody-oligonucleotide conjugate drugs.

Structure-Based Computational Scanning of Chemical Modification Sites in Biologics.

To address the challenges of short half-life, immunogenicity, and nonspecific distribution, chemical modifications of peptide and protein-based drugs have emerged as a versatile strategy for improving their therapeutic efficacy. One such modification involves the derivatization of peptides and proteins with fatty acids, which can protract their half-life, modify their biodistribution, and potentially enable targeted delivery to specific tissues or disease sites of interest. However, the present strategies for the synthesis of such synthetically modified biologics require numerous rounds of experimental testing and often yield unstable, inactive, or heterogeneous products. To address the inefficiencies in designing modified biologics, we developed a hybrid computational workflow that integrates RosettaMatch from the Rosetta suite of protein modeling tools with molecular dynamics (MD) simulations. This approach not only reduces the number of amino acid positions that need to be experimentally tested by targeting only the most promising candidates for modification but also expedites the design of chemically modified biologics with the desired properties, ensuring a rapid and cost-effective development cycle. Although we demonstrate the utility of our method on a peptide therapeutic, GLP-1, with different fatty acid derivatizations, this straightforward approach has the potential to streamline the design process of a diverse range of chemically modified therapeutics, enabling tailored enhancements to their pharmacokinetic properties.

Improving the clinical meaning of surrogate endpoints: An empirical assessment of clinical progression in phase III oncology trials.

Disease progression in clinical trials is commonly defined by radiologic measures. However, clinical progression may be more meaningful to patients, may occur even when radiologic criteria for progression are not met, and often requires a change in therapy in clinical practice. The objective of this study was to determine the utilization of clinical progression criteriawithin progression-based trial endpoints among phase III trials testing systemic therapies for metastatic solid tumors. The primary manuscripts and protocols of phase III trials were reviewed for whether clinical events, such as refractory pain, tumor bleeding, or neurologic compromise, could constitute a progression event. Univariable logistic regression computed odds ratios (OR) and 95% CI for associations between trial-level covariates and clinical progression. A total of 216 trials enrolling 148,190 patients were included, with publication dates from 2006 through 2020. A major change in clinical status was included in the progression criteria of 13% of trials (n = 27), most commonly as a secondary endpoint (n = 22). Only 59% of trials (n = 16) reported distinct clinical progression outcomes that constituted the composite surrogate endpoint. Compared with other disease sites, genitourinary trials were more likely to include clinical progression definitions (16/33 [48%] vs. 11/183 [6%]; OR, 14.72; 95% CI, 5.99 to 37.84; p < .0001). While major tumor-related clinical events were seldom considered as disease progression events, increased attention to clinical progression may improve the meaningfulness and clinical applicability of surrogate endpoints for patients with metastatic solid tumors.

Systemic treatment post curative-intent intervention based on tumor-informed circulating tumor DNA result for oligometastatic colorectal cancer.

84 Background: Local therapies potentially offer a curative approach for patients with oligometastatic colorectal cancer (CRC). The effectiveness of systemic chemotherapy following definitive local treatment in this setting is not well-defined. Tumor-informed circulating tumor DNA (ctDNA) might guide management strategies after curative-intent local treatment. Methods: This is a single institution retrospective study of patients with CRC who underwent curative-intent local therapy to an isolated site of metastatic disease and had post-intervention tumor-informed ctDNA (Signatera) testing. The study was approved by the institutional review board. Clinical characteristics, including ctDNA results, were collected and evaluated. Kaplan-Meier method and log-rank test were used to calculate and compare disease-free survival (DFS). Factors associated with DFS were analyzed using multivariate Cox proportional hazards model. Results: 45 patients were included with median age of 59 years, 62% being male, 91% white, and 53% with stage IV disease at diagnosis. 37% of the patients had RAS mutations, no patient had BRAF mutation, and 2.2% patient had mismatch repair deficient disease. Isolated liver metastases were present in 80% of patients, lung metastases in 11% and other sites in 9%. 44 patients received chemotherapy prior to definitive treatment, with a median treatment duration of 16 weeks. ctDNA tests were done prior to local therapy in 23 patients, with 14 cases (61%) testing positive. Definitive treatment included resection (58%), ablation (13%), radiotherapy (4%), and multimodality (25%). Post-definitive treatment chemotherapy was administered to 24 (53%) patients. ctDNA positivity following definitive therapy was observed in 10 patients (22%), which was associated with a poorer prognosis, with a median DFS of 5.3 months compared to 21.3 months for the ctDNA-negative group (p&lt;0.001). These findings were confirmed on multivariate analysis. In patients who had negative ctDNA after definitive local treatment, median DFS was 14.9 months for those who received post-intervention chemotherapy versus 21.3 months for those without post-intervention chemotherapy (p=0.835). Conclusions: Patients with negative ctDNA results following definitive local therapy for isolated metastatic CRC have better prognosis. Post-intervention chemotherapy in this group of patients was not associated with improved DFS. ctDNA guided omission of post-intervention chemotherapy following curative-intent local treatment of oligometastatic CRC warrants further study. [Table: see text]

Factors influencing timely diagnosis in neurolymphomatosis.

Neurolymphomatosis refers to infiltration of the peripheral nervous system (PNS) by non-Hodgkin lymphoma (NHL). Diagnostic intervals in neurolymphomatosis and factors delaying diagnosis have not been evaluated. We therefore aimed to analyze diagnostic intervals in a large cohort. The quality control database at Yale Cancer Center, Section of Neuro-Oncology, was searched for neurolymphomatosis cases diagnosed between 2001 and 2021. Univariate analyses were performed to identify parameters influencing diagnostic intervals. We identified 22 neurolymphomatosis cases including 7 with primary and 15 with secondary disease, which occurred a median (range: 4-144) of 16 months after initial NHL diagnosis. Patients typically presented with painful polyneuropathy (73%), that was asymmetrical and rapidly progressive. Diagnosis was based on PNS biopsy (50%) or integration of neuroimaging findings (50%) with NHL history and diagnostic cerebrospinal fluid examinations. Median interval from symptom onset to diagnosis was 3 months (range: 1-12). Secondary neurolymphomatosis compared to primary disease (median 2 vs. 6 months, p = 0.02), and cases with rapidly-progressive asymmetrical neuropathy as opposed to other presentations (median 2 vs. 6 months; p < 0.001) were diagnosed earlier. Upfront conventional CT compared to other modalities (median 2 vs. 5 months p = 0.04) and nerve root localization as opposed to other disease sites (median 1.5 vs. 4 months; p = 0.04) delayed diagnosis. NL type and localization, neuropathy course and distribution, and imaging modality selected for initial evaluation influence diagnostic intervals in neurolymphomatosis. Knowledge of this rare entity is critical for early suspicion, and diagnosis.

Fluorescent cyclopropyl ester probes are efficiently cleaved by endogenous carboxylesterase in mouse blood: implications for preclinical fluorescence imaging

ABSTRACT Prior studies have shown that fluorescent molecular probes based on cyclopropyl esters are good substrates for butyrylcholine esterase (BChE), which is a biomarker of several human diseases. We tested two fluorescent cyclopropyl ester derivatives as BChE-activated fluorogenic probes. One was a known fluorescein probe, and the other was a newly designed near-infrared probe based on a heptamethine cyanine dye. As expected, both probes were good substrates for BChE, but they were also good substrates for carboxylesterase (CE). The probes were efficiently cleaved in mouse blood and serum which contains high levels of CE, but they were not cleaved in human serum which contains negligible CE. There are two major implications of these results. One is a cautionary note that esterase levels in different organisms can vary substantially. Researchers developing fluorescent cyclopropyl ester probes for BChE imaging should anticipate high levels of background signal in preclinical mouse models due to ester cleavage by the abundant CE in mouse blood. However, there is very little cleavage of fluorescent cyclopropyl ester probes in human blood, which contains low levels of CE. Therefore, fluorescent cyclopropyl ester probes should be viable in humans as imaging agents that identify disease sites with overexpressed levels of CE or BChE.

Nanomedicines for Dry Eye Syndrome: Targeting Oxidative Stress with Modern Nanomaterial Strategies.

Dry eye syndrome (DES) is a dynamic, chronic disease of the ocular surface and ocular appendages caused by inflammation. The most common symptoms include redness, itching, and blurred vision, resulting from dysfunction of the meibomian glands and impaired tear-film production. Factors contributing to the development of DES include environmental elements, such as UV radiation, and internal elements, such as hormonal imbalances. These factors increase oxidative stress, which exacerbates inflammation on the surface of the eye and accelerates the development of DES. In recent years, the incidence of DES has risen, leading to a greater need to develop effective treatments. Current treatments for dry eye are limited and primarily focus on alleviating individual symptoms, such as reducing inflammation of the ocular surface. However, it is crucial to understand the pathomechanism of the disease and tailor treatment to address the underlying causes to achieve the best possible therapeutic outcomes. Therefore, in this review, we analyzed the impact of oxidative stress on the development of DES to gain a better understanding of its pathomechanism and examined recently developed nanosystems that allow drugs to be delivered directly to the disease site.

Unusual “Mini-Rugby Ball” Pattern Solitary Lung Metastasis in Relapsed Ewing's Sarcoma

AbstractEwing's sarcoma (ES) is a mesenchymal origin malignant neoplasm that affects children and adolescents. It is the second most common type of bone sarcoma and accounts for approximately 1.5% of all childhood cancers with an annual incidence of 1 to 3 cases per million children under 16 years of age. In this article, we present the case of a 16-year-old adolescent girl. Lung metastasis at the initial diagnosis of ES is relatively uncommon but carries significant prognostic implications. Lung metastases in ES can vary significantly in size, ranging from small nodules (just a few millimeters in size) to the largest reported case being 15 cm. The size of the metastases impacts the choice of therapeutic strategies and the prognosis. Approximately 30% of patients with ES experience a relapse, with the lungs being a common site for metastatic disease. Relapsed lung metastasis on follow-up is a critical concern in the long-term management of ES. We describe a relapsed case of ES in a 16-year-old adolescent girl who presented with a solitary large metastatic right lung mass, with the longest dimension of 16 cm on craniocaudal measurement. The primary site of the tumor was the left distal femur, for which the patient received six cycles of neoadjuvant chemotherapy, followed by en bloc tumor excision and rotationplasty of the left distal femur, after which the patient received seven cycles of adjuvant chemotherapy. Subsequent 5 years of regular follow-up was asymptomatic. Later, the patient presented with back pain and cough, and was diagnosed with a solitary large right lung mass. Computed tomography (CT) guided biopsy of the right lung mass revealed a metastatic ES, for which she underwent chemoradiotherapy. This case highlights the large size of solitary lung metastases in relapsed ES.

Cell-specific gene networks and drivers in rheumatoid arthritis synovial tissues.

Rheumatoid arthritis (RA) is a common autoimmune and inflammatory disease characterized by inflammation and hyperplasia of the synovial tissues. RA pathogenesis involves multiple cell types, genes, transcription factors (TFs) and networks. Yet, little is known about the TFs, and key drivers and networks regulating cell function and disease at the synovial tissue level, which is the site of disease. In the present study, we used available RNA-seq databases generated from synovial tissues and developed a novel approach to elucidate cell type-specific regulatory networks on synovial tissue genes in RA. We leverage established computational methodologies to infer sample-specific gene regulatory networks and applied statistical methods to compare network properties across phenotypic groups (RA versus osteoarthritis). We developed computational approaches to rank TFs based on their contribution to the observed phenotypic differences between RA and controls across different cell types. We identified 18 (fibroblast-like synoviocyte), 16 (T cells), 19 (B cells) and 11 (monocyte) key regulators in RA synovial tissues. Interestingly, fibroblast-like synoviocyte (FLS) and B cells were driven by multiple independent co-regulatory TF clusters that included MITF, HLX, BACH1 (FLS) and KLF13, FOSB, FOSL1 (B cells). However, monocytes were collectively governed by a single cluster of TF drivers, responsible for the main phenotypic differences between RA and controls, which included RFX5, IRF9, CREB5. Among several cell subset and pathway changes, we also detected reduced presence of Natural killer T (NKT) cells and eosinophils in RA synovial tissues. Overall, our novel approach identified new and previously unsuspected Key driver genes (KDG), TF and networks and should help better understanding individual cell regulation and co-regulatory networks in RA pathogenesis, as well as potentially generate new targets for treatment.

74 Unraveling the Complexities of Obesity in Clear Cell Renal Cell Carcinoma Carcinogenesis

Abstract Background Obesity has been identified as an established risk factor in the development of clear cell renal cell carcinoma (ccRCC). ccRCC arises from the proximal convoluted tubule (PCT) of the kidney which is also the site of obesity-associated chronic kidney disease. Obesity can lead to chronic cellular insults which may lead to DNA injury and whether these mechanisms are critical to cancer initiation in the kidney is unclear. One potential way that obesity can lead to cancer is by altering lipid metabolism, including increasing circulating saturated fatty acids. In particular, palmitic acid is known to be lipotoxic to proximal tubules of the kidney. Understanding how free fatty acids initiate cancer is critical to understanding the role of obesity in cancer initiation and development. We hypothesize that chronic injury and repair due to excess FFA exposure could lead to ccRCC carcinogenesis and aim to define the metabolic phenotype of obesity associated ccRCC. Methods Using publicly available data from The KIRC Cancer Genome Atlas Program (TCGA) and clinicopathologic data, we compared the RNAseq profiles of obese (BMI &amp;gt;= 30) to normal weight (BMI =&amp;lt; 25) sample origins. Of the 337, a total of 333 had BMI available for analysis. We evaluated differences in Hallmark and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways. Using DESeq, we adjusted for age and sex. In vitro, HK PCT cells were cultured in DMEM+10%FBS treated with bovine serum albumin (BSA)-palmitic acid complex for 48 hrs. We measured cell viability using Alamar Blue. Results were normalized to controls with BSA only. We extracted protein and performed western blots to identify DNA damage (pATM, H2AX) and endoplasmic reticulum stress (ATF4, eFI2alpha). Results Most of the patients in our clinical data cohort are male (64.4%), while 45.4% of patients are categorized by BMI as obese and 33.2% are categorized as normal. We utilized 333 individuals from the Kyoto Encyclopedia of Genes and Genomes (KEGG) to link genomic information to pathways associated with fatty acid metabolism as well as other cancer-associated hallmark metabolic pathways. We confirmed that excess free fatty acid supplementation leads to decreased cell viability in renal proximal tubule cells and renal embryonal cells and aim to assess differences in gene expression and metabolomic variation with fatty acid supplementation. Conclusions Through the investigation of these questions, we hope to improve understanding of obesity associated ccRCC and ultimately impact oncological outcomes for patients with this cancer. Understanding changes in lipid metabolism around ccRCC initiation will help identify novel pathways for pharmacologic intervention at earlier stages of the disease. DOD CDMRP Funding: yes

Management and Outcomes of Children with Malignant Germ Cell Tumor.

To assess the clinico-pathological features, management and outcomes, amongst extracranial malignant germ cell tumors (MGCTs) in children treated primarily at a tertiary care center in a resource-challenged nation. The prospectively maintained data for children below 14 y of age treated for extracranial MGCT from May 1994 to January 2023 was analyzed for patient characteristics, management, event-free survival (EFS) and overall survival (OS) and factors effecting survival. Events was defined as death, recurrence and progression. Multivariate logistic regression analysis was performed to identify the factors independently predicting unfavorable outcomes. One hundred and seventy-seven children (37% males) with a median (IQR) age at presentation of 30 mo (range 2-168 mo) were included. The cohort consisted of 87 (49%) extra-gonadal and 90 (51%) gonadal cases. Disease was metastatic at presentation in 48 (27%) with lungs being the most common site. Neoadjuvant chemotherapy (NACT) was given to 119 (67%) and finally 162/177 (92%) had undergone resection of the primary tumor. Endodermal sinus tumor (EST) was the commonest histological subtype in 141 children (73%). Twenty-two (12%) patients had died giving a 5-y OS of 84.7% (95% CI 78.3- 91.1). Recurrence occurred in 25 patients, and an additional 5 patients had progression giving a 5-y EFS of 69.9% (95% CI 62.5- 77.3). Stage III (p = 0.05), Stage IV (p = 0.006) and extra-gonadal site (p = 0.05) were significantly associated with poorer EFS. Children with MGCT have a favorable outcome with 5-y OS of 84.7% and EFS of 69.9%. Stage III and IV disease and extra-gonadal sites were independent predictors of a poor outcome.

Deep learning architecture with shunted transformer and 3D deformable convolution for voxel-level dose prediction of head and neck tumors.

Intensity-modulated radiation therapy (IMRT) has been widely used in treating head and neck tumors. However, due to the complex anatomical structures in the head and neck region, it is challenging for the plan optimizer to rapidly generate clinically acceptable IMRT treatment plans. A novel deep learning multi-scale Transformer (MST) model was developed in the current study aiming to accelerate the IMRT planning for head and neck tumors while generating more precise prediction of the voxel-level dose distribution. The proposed end-to-end MST model employs the shunted Transformer to capture multi-scale features and learn a global dependency, and utilizes 3D deformable convolution bottleneck blocks to extract shape-aware feature and compensate the loss of spatial information in the patch merging layers. Moreover, data augmentation and self-knowledge distillation are used to further improve the prediction performance of the model. The MST model was trained and evaluated on the OpenKBP Challenge dataset. Its prediction accuracy was compared with three previous dose prediction models: C3D, TrDosePred, and TSNet. The predicted dose distributions of our proposed MST model in the tumor region are closest to the original clinical dose distribution. The MST model achieves the dose score of 2.23 Gy and the DVH score of 1.34 Gy on the test dataset, outperforming the other three models by 8%-17%. For clinical-related DVH dosimetric metrics, the prediction accuracy in terms of mean absolute error (MAE) is 2.04% for , 1.54% for , 1.87% for , 1.87% for , 1.89% for , respectively, superior to the other three models. The quantitative results demonstrated that the proposed MST model achieved more accurate voxel-level dose prediction than the previous models for head and neck tumors. The MST model has a great potential to be applied to other disease sites to further improve the quality and efficiency of radiotherapy planning.

Prostate-Specific Membrane Antigen PET/CT-Guided, Metastasis-Directed Radiotherapy for Oligometastatic Castration-Resistant Prostate Cancer.

Systemic treatments for metastatic castration-resistant prostate cancer (mCRPC) include androgen deprivation therapy, androgen receptor pathway inhibitors, chemotherapy, and radiopharmaceuticals, all of which have associated toxicity. Prostate-specific membrane antigen (PSMA) PET/CT allows for higher sensitivity in detecting metastatic disease than is possible with conventional imaging. We hypothesized that PSMA PET/CT-guided, metastasis-directed radiotherapy may offer durable disease control with low toxicity rates in patients with mCRPC who have a limited number of metastases. Methods: We retrospectively screened 5 prospective PSMA PET/CT studies for patients with mCRPC who had up to 5 sites of oligorecurrent or oligoprogressive disease on PSMA PET/CT and subsequently received definitive-intent, metastasis-directed radiotherapy to all new or progressing sites with concurrent androgen deprivation therapy. Progression-free survival, freedom from new lines of systemic therapy, and overall survival (OS) were calculated from the start of metastasis-directed radiotherapy using Kaplan-Meier analysis. Biochemical response was defined as at least a 50% decrease in prostate-specific antigen 6 mo after the start of treatment. Toxicity was graded using the Common Terminology Criteria for Adverse Events, version 5. Results: Twenty-four patients met the inclusion criteria with a median follow-up of 33.8 mo (interquartile range, 27.6-45.1 mo). Between October 2017 and April 2023, 11 patients (45.8%) had 1 treated site, 10 patients (41.7%) had 2, and 3 patients (12.5%) had 3. Five sites were prostate or prostate bed, 15 were nodal, 19 were osseous, and 1 was visceral. Seventeen patients (70.8%) continued their preexisting systemic therapy, whereas 7 (29.2%) started a new systemic therapy. Median progression-free survival was 16.4 mo (95% CI, 9.8-23.0 mo). The biochemical response rate was 66.7%. Median freedom from a new line of systemic therapy was 29.0 mo (95% CI, 7.6-50.4 mo). Median OS was not reached. The 2- and 4-y OS rates were 91.1% (95% CI, 79.3%-100%) and 68.8% (95% CI, 45.1%-92.5%), respectively. Grade 2 and grade 3 or higher toxicity rates were 4.2% and 0%, respectively. Conclusion: PSMA PET/CT-guided, metastasis-directed radiotherapy appears to offer durable disease control with low toxicity rates for oligometastatic castration-resistant prostate cancer. Further prospective studies are needed to compare metastasis-directed radiotherapy with systemic therapy versus systemic therapy alone and PSMA PET/CT-guided versus conventional imaging-guided radiotherapy.

Addressing disparities in health outcomes for patients with advanced pancreatic cancer and limited English proficiency.

There are significant challenges and a lack of data related to culturally and linguistically diverse (CALD) cancer patients. We compared patient characteristics, treatment patterns, and outcomes of patients with advanced pancreatic cancer that required an interpreter. Registry data was extracted for advanced pancreatic cancer patients from a single health institution with a comprehensive Transcultural and Language Service (TALS). Demographic and clinicopathologic characteristics were compared. Kaplan-Meier survival estimates with log-rank testing, and univariate and multivariable regression analysis were performed to compare the group with limited English proficiency (LEP) to theEnglish proficient (EP)group. Of 155 patients, 32.9% (n=51) required the TALS. TheLEP group had a higher mean age (71.2vs. 76.8 years; p=0.005) and received less chemotherapy (42.3%vs. 31.4%, p=0.220). Univariate analysis revealed a shorter median overall survival (OS) in the LEP group (3.6vs. 5.0 months), with a hazard ratio [HR] of 1.51 (95% confidence interval [CI]: 1.03-2.21, p=0.033). Upon multivariable analysis, adjusting for Eastern Cooperative Oncology Group (ECOG) performance scale, the number of sites of metastatic disease and chemotherapy use, the strength of association between LEP and OS reduced marginally (HR 1.42, 95% CI: 0.93-2.16), and was no longer statistically significant (p=0.103). In patients with advanced pancreatic cancer utilizing a comprehensive TALS, there was a trend to poorer survival with limited English proficiency, although this association was not statistically significant. An ongoing research commitment to the CALD experience is necessary to build a granular understanding of this population and ensure equitable outcomes.

Psoriasis with Leg Involvement as the New Difficult-To-Treat Area: A Cohort Study of Patients Treated With Risankizumab.

Historically, difficult-to-treat areas in psoriasis included face, scalp, folds, genitalia, nails, and palmoplantar region. Recent studies have found that lower limbs behave like a "new" difficult-to-treat area as they can be the only site of residual disease even in patients undergoing biologic therapies. We aimed to evaluate whether legs had different response rates and response times to treatment with a new biologic drug, risankizumab, compared to other body sites. We conducted a real-life, observational, retrospective, multicenter study including patients affected by moderate-to-severe psoriasis with leg involvement and undergoing biological therapy with risankizumab for more than 16 weeks. The Psoriasis Area Severity Index (PASI) and Leg-PASI were collected at T0 and at weeks 16, 28, 40, 52, 64, and 76. Statistical analysis using Student's t test and linear regression analysis were performed. A total of 124 patients were included. The difference between the improvement percentage compared to baseline was statistically significant at weeks 16 and 28, demonstrating that Leg-PASI improved less than PASI. From the linear regression it was deduced that the slope is statistically less steep for Leg-PASI than for overall PASI, confirming that this site responds more slowly to the therapy. Leg response to risankizumab appears to differ significantly from other body sites in the first weeks of treatment, even if after 28 weeks, statistical significance is lost. Our preliminary finding suggests that risankizumab can be considered an effective treatment for leg psoriasis but with longer response times than other areas, demonstrating the relative nature of resistance to treatment of this district.

Folic Acid-Functionalized β-Cyclodextrin for Delivery of Organelle-Targeted Peptide Chemotherapeutics in Cancer.

Recent emphasis on the design of drug delivery systems typically involves the effective transport of a pharmaceutical substance to the disease site with the desired therapeutic efficacy and minimal cytotoxicity. Organelle-targeted peptides have become an integral part of designing an important class of prodrug/prodrug assemblies for new supramolecular therapeutics owing to their favorable biocompatibility, synthetic ease, tunability of their aggregation behavior, and desired functionalization for site-specificity. However, it is still limited due to the low selectivity. We designed a folic acid-functionalized β-cyclodextrin (FA-CD) as a delivery platform for specific and selective delivery of organelle-targeted (such as microtubule, lysosome, and mitochondria) peptide chemotherapeutics to the folate receptor (FR) overexpressing cancer cell lines. Low toxicity was found for the FA-CD and organelle-targeted peptide inclusion complex in FR-negative normal cells, but superior inhibition of tumor growth with no in vivo toxicity was found for the inclusion complex in the xenograft tumor model.

DNA aptamer-conjugated lipid nanoparticle for targeted PTEN mRNA delivery to prostate cancer cells

The use of messenger RNA (mRNA) as a cancer vaccine and gene therapy requires targeted vehicle delivery to the site of disease. Here, we designed a mRNA-encapsulating lipid nanoparticle (LNP) conjugated with anti-programmed death-ligand 1 (PD-L1) DNA aptamer that delivers mRNA encoding a tumor suppressor gene, namely phosphatase and tensin homolog (PTEN), to castration-resistant prostate cancer (CRPC) cells expressing PD-L1 on the cell surface. The DNA aptamer-conjugated LNP-based mRNA delivery system (Apt-LNP[PTEN mRNA]) mediated efficient mRNA delivery and transfection in CRPC cells than LNPs without targeting ligands. Cancer-targeted PTEN mRNA delivery using Apt-LNPs achieved significantly higher PTEN expression via aptamer-mediated endocytosis in target cancer cells compared with non-targeted LNP delivery, resulting in significant downregulation of AKT phosphorylation. This enhanced PI3K/AKT pathway regulation, and in turn reduced cell migration after two days along with a 70 % decrease in cell viability, leading to effective apoptotic cell death. In a CRPC xenograft model, Apt-LNP[PTEN mRNA] led to an approximate 60 % reduction in tumor growth, which was attributable to the effective PTEN restoration and PI3K/AKT signaling pathway regulation. PTEN expression was significantly enhanced in CRPC tumor tissues, which abolished cancer cell tumorigenicity. These findings demonstrated the potential of Apt-LNPs for targeted mRNA delivery to cancer cells, thus providing a promising tool for targeted mRNA delivery to a range of cancers and tissues using a conventional LNP systems.