Comprehensive Next-generation Sequencing Research Articles

Abstract B039: Clinical liquid biopsy testing for detecting actionable genomic alterations in children and young adults with advanced solid tumors

Abstract Introduction: Given the paucity of data regarding circulating tumor DNA (ctDNA) as a modality to guide diagnosis and treatment for children with solid tumors, we conducted a prospective study to determine the frequency of diagnostic and targetable genomic variants identified by clinical ctDNA testing. Methods: GAIN is a prospective, multi-center molecular profiling study that was amended to include clinical ctDNA testing starting in January 2022. Patients were eligible if they were <30 years old with a refractory, recurrent, newly diagnosed with 2-year EFS <50%, or rare solid tumor and had measurable or evaluable disease. Paired tumor and blood samples underwent next generation sequencing (NGS) in CLIA-certified laboratories, with return of results to clinicians. Serial ctDNA samples were analyzed by F1LCDx (FoundationOne® Liquid Companion Diagnostic), an FDA-approved clinical ctDNA test that includes hybrid capture sequencing of a 300+ gene panel, comprehensive multi-omics ctDNA tumor fraction (TF) assessment, tumor mutational burden, and microsatellite instability status. We analyzed comprehensive NGS tissue-based and F1LCDx sequencing data for each participant to compare findings from each sample. The detection of alterations was stratified by ctDNA burden as assessed by ctDNA TF. We calculated the prevalence of ctDNA in our cohort, overall and by disease type. Chart review provided additional patient characteristic, diagnostic, therapeutic, and disease assessment data. The clinical impact of ctDNA results was qualitatively described. Results: The cohort included 35 patients, with a total of 70 F1LCDx samples (range 1-6 samples per patient). There were 16 unique tumor types represented, most commonly osteosarcoma (n = 8), neuroblastoma (n = 8), and Ewing sarcoma (n = 4). 77% of patients had metastatic disease at time of first ctDNA sample collection. 51% of patients had detectable ctDNA TF in at least one sample. Overall, 60% of patients had at least one actionable genomic alteration (range 0-14 variants per patient) identified in liquid biopsy samples, including 3 patients with actionable variants identified with undetectable ctDNA TF. We observed case vignettes in which ctDNA results informed clinical decisions, including disease assessment and treatment guidance. An illustrative example was the identification of ALK variants in relapse blood samples of two patients with neuroblastoma that were not identified in baseline tissue, which were targeted in both instances. Data collection and analyses as described in the methods are ongoing. Conclusion: In this prospective cohort of children and young adults with advanced solid tumors, ctDNA was detectable across a wide range of diagnoses and 60% of patients had at least one diagnostic or potentially targetable alteration identified. These data demonstrate that liquid biopsy yields actionable genomic variants, particularly when ctDNA burden is elevated. We will determine the association of these variants with those identified in tissue samples and their clinical implications in ongoing analyses. Citation Format: Holly J Roberts, Hannah Comeau, Steven G Dubois, Katerina Hoskova, Douglas I Lin, Brian D Crompton, Katherine A Janeway, David S Shulman. Clinical liquid biopsy testing for detecting actionable genomic alterations in children and young adults with advanced solid tumors [abstract]. In: Proceedings of the AACR Special Conference: Liquid Biopsy: From Discovery to Clinical Implementation; 2024 Nov 13-16; San Diego, CA. Philadelphia (PA): AACR; Clin Cancer Res 2024;30(21_Suppl):Abstract nr B039.

Clinical and Technical Validation of OncoIndx® Assay-A Comprehensive Genome Profiling Assay for Pan-Cancer Investigations.

Comprehensive next-generation sequencing (NGS) assays enable the identification of clinically relevant mutations, enhancing the capability for targeted therapeutic interventions. In addition, genomic alterations driving the oncogenic roadmap and leading to resistance mechanisms are reshaping precision oncology. We report the workflow and clinical and technical validation of the OncoIndx® NGS platform-a comprehensive genomic profiling (CGP)-based assay for pan-cancer investigation. We evaluated the concordance between the OncoIndx® test findings and clinically established hotspot detection using SeraSeq reference standards. OncoIndx is a hybridization capture-based NGS assay for the targeted deep sequencing of all exons and selected introns of 1080 cancer-related genes. We show the outcome in the form of tier I and tier II single nucleotide variants (SNVs), copy number alterations (CNAs), and specific gene fusions. OncoIndx® also informs genome-wide tumor mutational burden (TMB), microsatellite instability (MSI), homologous recombination deficiency (HRD), and genomic loss of heterozygosity (gLOH). A total of 63 samples were utilized for validation with reference standards, clinical samples, and orthogonal assessment for genomic alterations. In addition, 49 cross-laboratory samples were validated for microsatellite instability (MSI), and for the tumor mutation burden (TMB), 18 samples as reference standards, 6 cross-laboratory samples, and 29 TCGA samples were utilized. We show a maximum clinical sensitivity of 98% and a positive predictive value (PPV) of 100% for the clinically actionable genomic variants detected by the assay. In addition, we demonstrate analytical validation with the performance of the assay, limit of detection (LoD), precision, and orthogonal concordance for various types of SVs, CNAs, genomic rearrangements, and complex biomarkers like TMB, MSI, and HRD. The assay offers reliable genomic predictions with the high-precision detection of actionable variants, validated by established reference standards.

Genomic Landscape of Advanced Solid Tumors in Middle East and North Africa Using Circulating Tumor DNA in Routine Clinical Practice

Introduction: Next-generation sequencing (NGS) of tumor DNA can detect actionable drivers and help guide therapy for patients with advanced-stage cancers. While tissue-based genotyping is considered a standard of care, blood-based genotyping is emerging as a valid alternative. Tumor genomic profiles may vary by region, and data from the Middle East and North Africa (MENA) are not widely available. This study elucidates the genomic landscape of advanced solid cancers in patients from the MENA region by retrospectively analyzing results from NGS circulating tumor DNA (ctDNA) testing. Methods: In routine clinical practice, 926 plasma samples from 767 patients with advanced cancers from the MENA region were profiled using a comprehensive NGS assay (Guardant360®). We conducted a pan-cancer analysis and sub-analyses focusing on lung, breast, and colorectal cancers. Results: In the pan-cancer group, TP53 (58.5%), EGFR (20.4%), and KRAS (18.9%) were the most frequently mutated genes. EGFR (10.2%), FGFR1 (4.9%), and PIK3CA (4.9%) showed the most amplifications, while fusions were observed in 2.7% of patients, including ALK, FGFR2, and RET. For lung adenocarcinoma, EGFR (30.5%), KRAS (19.3%), and ERBB2 (4.6%) were the most frequently identified alterations among the genes recommended for evaluation by the National Comprehensive Cancer Network (NCCN). In patients with breast cancer, PIK3CA (35.3%), ESR1 (21.7%), and BRCA1/2 (13.3%) had the most prevalent alterations among NCCN-recommended genes. In colorectal cancer, KRAS (39.0%), NRAS (8.0%), and BRAF (V600E, 4.0%) were the most observed mutations among genes recommended by the NCCN. Comparing this cohort to publicly available Western and Eastern datasets also indicated similarities (including PIK3CA in breast cancer) and variances (including EGFR in lung adenocarcinoma) in key genes of interest in the analyzed cancer types. Conclusion: Overall, our findings provide insight into the genomic landscape of individuals with advanced solid organ malignancies from the MENA region and support the role of ctDNA in guiding therapeutic decisions.

Registry of Genetic Alterations of Taiwan Non-Small Cell Lung Cancer by Comprehensive Next-Generation Sequencing: A Real-World Cohort Study-Taiwan Cooperative Oncology Group T1521.

Tissue-based next-generation sequencing (NGS) analysis is highly recommended for patients with advanced/metastatic non-small cell lung cancer (NSCLC). We investigated a specific patient population with NSCLC that required tissue-based NGS analysis. We enrolled 500 patients with advanced/metastatic (1) epidermal growth factor receptor (EGFR) mutations or anaplastic large-cell lymphoma kinase (ALK) rearrangement-positive NSCLC who had failed at minimum one line of tyrosine kinase inhibitor (TKI) therapy, (2) EGFR-/ALK-negative nonsquamous, and (3) non- or light-smoker patients with squamous NSCLC who were treatment-naïve or had failed at maximum two lines of systemic treatment. These patients were divided into five cohorts. Comprehensive tissue-based NGS testing (ACTOnco+) was conducted. Cohort 1: EGFR TKI-pretreated EGFR-mutated population (50.0%, n = 250), cohort 2: ALK inhibitor-pretreated ALK-positive population (1.6%, n = 8), cohort 3: treatment-naïve EGFR-/ALK-negative population (28.2%, n = 141), cohort 4: pretreated EGFR-/ALK-negative population (16.8%, n = 84), and cohort 5: squamous cell carcinoma (3.4%, n = 17). In cohort 1, 11.2% (28/250) of the patients had MET amplification, 32.4% (81/250) had been treated with osimertinib, and EGFR C797S was detected in 6.2% (5/81) of these patients. In cohort 2, resistance ALK mutation was detected in 37.5% (3/8) of the patients. In cohorts 3 and 4, targetable genetic alterations, including EGFR mutation (13.3%), ERBB2 mutation (9.3%), MET exon 14 skipping (5.3%), KRAS G12C mutation (4.4%), ROS1 fusion (2.7%), RET fusion (1.8%), and BRAF V600E mutation (1.3%), were detected. In cohort 5, MET exon 14 skipping was detected in 29.4% (5/17) of the patients. This multicenter registration study investigated tissue-based NGS for a specific patient population with NSCLC in Taiwan.

COMPREHENSIVE MOLECULAR PROFILING OF UVEAL MELANOMA EVALUATED WITH GENE EXPRESSION PROFILING, PREFERENTIALLY EXPRESSED ANTIGEN IN MELANOMA EXPRESSION, AND NEXT-GENERATION SEQUENCING.

To determine the association between gene-expression profiling (GEP), next-generation sequencing (NGS), preferentially expressed antigen in melanoma (PRAME) features, and metastatic risk in patients with uveal melanoma (UM). A retrospective analysis of patients with UM treated by brachytherapy or enucleation by a single ocular oncologist was conducted from November 2020 and July 2022. Clinicopathologic features, patient outcomes, GEP classification, NGS, and PRAME results were recorded. Comprehensive GEP, PRAME, and NGS testing was performed on 135 UMs. The presence of eukaryotic translation initiation factor 1A, X-chromosomal and splicing factor 3B subunit 1 mutations was significantly associated with GEP class 1A and GEP class 1B, respectively. The presence of BRCA- associated protein-1 mutation was significantly associated with GEP class 2. The average largest basal diameter for tumors with eukaryotic translation initiation factor 1A, X-chromosomal mutations was significantly smaller than those with splicing factor 3B subunit 1 mutations and BRCA1-associated protein-1 mutations. Class 2 tumors metastasized sooner than GEP class 1 tumors. Tumors with splicing factor 3B subunit 1 and/or BRCA1-associated protein-1 mutations metastasized sooner compared with tumors that had either no driver mutation or no mutations at all. Tumors with splicing factor 3B subunit 1 did not have a significantly different time to metastasis compared with tumors with BRCA1-associated protein-1 (P value = 0.97). Forty tumors (30%) were PRAME positive, and the remaining 95 tumors (70%) were PRAME negative. Tumors with PRAME-positive status did not have a significantly different time to metastasis compared with tumors without PRAME-positive status (P value = 0.11). GEP, NGS, and PRAME expression analysis help determine different levels of metastatic risk in UM. Although other prognostic tests exist, the following study reports on the use of NGS for metastatic prognostication in UM. However, limitations of NGS exist, especially with small lesions that are technically difficult to biopsy.

Next-generation sequencing-based evaluation of the actionable landscape of genomic alterations in solid tumors: the "MOZART" prospective observational study.

The identification of the most appropriate targeted therapies for advanced cancers is challenging. We performed a molecular profiling of metastatic solid tumors utilizing a comprehensive next-generation sequencing (NGS) assay to determine genomic alterations' type, frequency, actionability, and potential correlations with PD-L1 expression. A total of 304 adult patients with heavily pretreated metastatic cancers treated between January 2019 and March 2021 were recruited. The CLIA-/UKAS-accredit Oncofocus assay targeting 505 genes was used on newly obtained or archived biopsies. Chi-square, Kruskal-Wallis, and Wilcoxon rank-sum tests were used where appropriate. Results were significant for P < .05. A total of 237 tumors (78%) harbored potentially actionable genomic alterations. Tumors were positive for PD-L1 in 68.9% of cases. The median number of mutant genes/tumor was 2.0 (IQR: 1.0-3.0). Only 34.5% were actionable ESCAT Tier I-II with different prevalence according to cancer type. The DNA damage repair (14%), the PI3K/AKT/mTOR (14%), and the RAS/RAF/MAPK (12%) pathways were the most frequently altered. No association was found among PD-L1, ESCAT, age, sex, and tumor mutational status. Overall, 62 patients underwent targeted treatment, with 37.1% obtaining objective responses. The same molecular-driven treatment for different cancer types could be associated with opposite clinical outcomes. We highlight the clinical value of molecular profiling in metastatic solid tumors using comprehensive NGS-based panels to improve treatment algorithms in situations of uncertainty and facilitate clinical trial recruitment. However, interpreting genomic alterations in a tumor type-specific manner is critical.

Profiling Cell-Free DNA from Malignant Pleural Effusion for Oncogenic Driver Mutations in Patients with Treatment-Naive Stage IV Adenocarcinoma: A Multicenter Prospective Study.

Comprehensive next-generation sequencing (NGS) of non-small-cell lung cancer specimens can identify oncogenic driver mutations and their corresponding targeted therapies. Plasma cell-free DNA (cfDNA) genotyping is easy to perform; however, false negatives cannot be overlooked. We explored malignant pleural effusion (MPE), a rich source of cfDNA, as a non-inferior alternative to tumor tissues for genotyping. We conducted a prospective trial including 39 patients with newly diagnosed stage IV lung adenocarcinoma who presented with MPE. Tissue tests matching hotspot variants, including EGFR, ALK, and ROS1, were compared with the AlphaLiquid100 of PE-cfDNA. Among the 39 PE-cfDNA samples successfully sequenced, 32 (82.1%) had a PE cell-block tumor content of <10%. Standard tissue or cell-block testing for EGFR, ALK, and ROS1 identified 20 mutations (51.3%), whereas PE cfDNA identified 25 mutations (64.1%). Five EGFR mutations were observed in PE cfDNA but not in Cobas EGFR owing to coverage or insufficient tumor content issues. The overall rate of oncogenic mutations identified in the PE cfDNA was 92.3%, and the mutation distribution was as follows: even with a very low cfDNA input, high detection rates could be achieved. Otherwise, most patients harbored co-mutations. Comparison of pleural fluid NGS with traditional testing revealed differences in accuracy. We also followed up with patients with EGFR-sensitizing mutations who had a treatment response rate of 97.2% after 3 months. Genotyping of MPE supernatant cfDNA is feasible in clinical practice, in addition to plasma and tumor testing, to improve diagnostic yield and extend patients' benefit from targeted therapies.

Hereditary breast cancer next-generation sequencing panel evaluation in the south region of Brazil: A novel BRCA2 candidate pathogenic variant is reported.

In this article, we delineate a loosely selected cohort comprising patients with a history of early-onset breast cancer and/or a familial occurrence of cancer. The aim of this study was to gain insights into the presence of breast cancer-related gene variants in a population from a micro-region in southern Brazil, specifically the Metropolitan Region of Curitiba. This area exhibits a highly genetically mixed population, mirroring the general characteristics of the Brazilian people. Comprehensive next-generation sequencing (NGS) multigene panel testing was conducted on 12 patients from the region, utilizing three different library preparation methods. Two pathogenic variants and one candidate pathogenic variant were identified: BRCA2 c.8878C>T, p.Gln2960Ter; CHEK2 c.1100del, p.Thr367Metfs15, and BRCA2 c.3482dup, p.Asp1161Glufs3. BRCA2 c.3482dup, a novel candidate pathogenic variant, previously unpublished, is reported. The prevalence of pathogenic variants in this small cohort is similar to that described in the literature. All different library preparation methods were equally proficient in enabling the detection of these variants.

Next-generation sequencing has diagnostic utility in challenging small/flat urothelial lesions

Small/flat urothelial lesions are challenging and currently available ancillary immunohistochemistry testing often cannot reliably distinguish between reactive lesions and urothelial carcinoma (UCa). UCa has a characteristic molecular profile, but small/flat urothelial lesions are typically considered too small to perform next generation sequencing (NGS). Herein, we present our institution's experience with utilizing comprehensive DNA-based NGS to evaluate small/flat urothelial lesions (n = 13 cases). NGS was ordered on 7/13 small/flat urothelial lesions initially diagnosed as urothelial atypia, ordered by the pathologist to aid in further diagnosis; the remaining 6/13 cases were diagnosed as urothelial carcinoma in situ (uCIS), ordered by a treating oncologist. The test was considered as adding value if it yielded pathogenic or likely pathogenic alterations previously associated with urothelial carcinoma in the literature. Macroscopic dissection was determined necessary in all cases and obtained either by scraping (7), punch biopsy (5) or scooping (1) of paraffin tissue blocks. In 4/13 cases, tumor content was considered low (<25%); in 2/13 cases, DNA quantity yield was considered below optimal (<250 ng); all cases met required DNA quantity for testing (>50 ng). Mean target coverage ranged: 498 to 985 (optimal >500 reads). NGS testing identified mutations compatible with urothelial carcinoma in all 7 cases initially diagnosed as atypical; and in one case, the tumor recurred as a lung metastasis. All 6 uCIS had NGS testing results concordant with UCa. In conclusion, despite small sample quantity with low tumor content and DNA concentration yield, NGS testing with appropriate methodology can be considered in the setting of small/flat urothelial lesions to aid in diagnosis or per oncologist request and yield interpretable results.

Comparison of genomic profiling of patient-matched primary colorectal and surgical resected distant metastatic (stage IV) colorectal carcinoma for drug actionability

It is often difficult to obtain adequate tissue for genomic study from distant metastases for assessment of targeted therapy in colorectal carcinomas. The study aims to explore the genomic differences between matched distant metastatic colorectal carcinomas (mCRC) and primary carcinoma using surgical specimens of both with adequate tissue. Thirty-four paired primary and distant metastatic colorectal carcinoma samples (liver, ovary, and lung) were obtained from surgical excisions (not small biopsies) and are microsatellite stable. They were subjected to DNA sequencing using comprehensive next-generation sequencing. This included mutation concordance analysis and mutational signature analysis. The mutation concordance analysis showed 49.6% shared mutations between primary and metastatic tumours, with 23.0% mutations exclusive to primary tumours and 27.4% mutations exclusive to distant metastases. While many patients with KRAS/BRAF mutations had shared mutations, two cases had unique KRAS mutations in the primary tumours only. Additionally, TMB (tumour mutational burden) analysis revealed that half of the TMB-high (≥7.5 mutations/Mb) metastatic colorectal carcinomas had a low TMB (<7.5 mutations/Mb) in the primary tumours. The mutational signature analysis identified de novo signatures consistent with known single base substitution patterns such as SBS11 (alkylation agents) and SBS30 (base excision repair deficiency) post-chemotherapy. To conclude, this study demonstrates significant genomic variations in resected distant metastasis when compared to primary colorectal carcinomas when adequate tissue is available. This finding underscores the importance of considering these differences and selecting tissue for mutation analysis in planning targeted and effective treatment strategies for mCRC.

Changes in non-small cell lung cancer (NSCLC) next-generation sequencing (NGS) rates after electronic health record (EHR) integration using large-scale, multi-institutional, real-world data.

e13619 Background: NSCLC treatment guidelines recommend comprehensive NGS testing to detect genomic alterations and gene expression in key biomarkers that are relevant in diagnosis, therapy selection, prognosis, and clinical trials. While 70% of patients with NSCLC will have biomarker alterations related to therapeutic options, a large minority of patients still do not receive biomarker testing. Clinical workflow challenges outside the EHR ecosystem, like paper requisitions and faxed results, have been cited as barriers to adoption. To reduce sequencing barriers, Tempus deploys NGS through direct result EHR connection. To evaluate whether integrating comprehensive NGS ordering and resulting into the EHR would improve testing rates, we retrospectively analyzed NSCLC NGS orders from 29 clinical networks which represent over 1500 medical oncologists, before and after EHR integration. Methods: Clinical networks that partnered with Tempus to perform an NGS EHR integration were identified. Only networks with at least 6 months of pre- and post-integration unique patient NGS orders were included. De-identified patient information from these sites were obtained from the Tempus laboratory information management system. NSCLC diagnosis was determined through ICD9/10 codes. NGS tests ordered were limited to xT/xR (solid tumor DNA and RNA), xE (solid tumor whole exome), or xF (circulating tumor DNA). Aggregate unique patients with orders were summated on a per site basis. Descriptive statistics were used to characterize the findings. Results: From May 2019 to July 2023, 29 clinical cancer networks (48% academic medical center, 45% regional health system) that underwent a Tempus NGS EHR integration were identified. Of the 29 networks considered, 3 were excluded due to insufficient data. Of the evaluable 26 networks, Epic EHR was used in the majority (24 of 26). In aggregate, a total of 1825 NSCLC patients were sequenced pre-integration as compared to 2796 patients sequenced post-integration, representing a 53% increase. Academic medical centers experienced a higher increase versus regional health systems (65% v 48%). When examined on a per network basis, the median and mean increase in NSCLC patients sequenced were 49% and 118%, respectively. Conclusions: In this retrospective analysis, Tempus EHR integrations increased ordering of comprehensive NSCLC NGS by 53%. Despite study limitations such as the incomplete resolution into internal alternate sequencing workflows, this large-scale analysis provides further evidence that EHR-based workflow improvements reduce the barrier to appropriate sequencing.

Comparative analysis of actionable gene reporting in targeted panels versus comprehensive NGS testing for solid tumor samples.

11185 Background: The landscape of actionable genes significantly influences clinical decisions in cancer diagnosis, prognosis, and treatment planning. In a clinical context, the selection of NGS panels hinges on striking a balance among informative data, insurance coverage, and the preferences of patients and healthcare providers. Molecular pathology reference laboratories commonly employ large-scale next-generation sequencing (NGS) testing, curating smaller, disease-specific targeted panels. This study investigates the prevalence of unreported actionable genes in real-world clinical samples subjected to disease-specific panels. Methods: We analyzed SNV/InDel DNA variants in 795 clinical solid tumor samples using the Illumina TSO 500 platform for comprehensive NGS panel testing of 517 genes. Comprehensive NGS panel-tested samples were intersected with disease-specific targeted NGS panels for breast (54 genes), brain (62 genes), colorectal (36 genes), and lung (44 genes). An artificial filter was applied to align targeted panels with patient disease. Variants were classified based on pathogenicity, and benign variants were filtered out. Detected variants were assessed for actionable mutations as defined by the FDA recognized OncoKB actionable gene database criteria. Additionally, 1484 lung patient samples tested with a lung-specific targeted panel were de-identified and unmasked to the comprehensive NGS tumor profiling to investigate the prevalence of actionable alteration beyond those covered by the disease-specific panel. Results: The study revealed that 3.2% of breast, 0% of brain, 66.2% of colorectal, and 2.7% of lung samples had additional actionable mutations undisclosed by the targeted panels. The number of actionable genes beyond those included in the targeted panels were 14 for breast, 2 for brain, 25 for lung, and 41 for colorectal cancer. This underscores the importance of comprehensive testing to fully capture each patient tumor’s actionable mutation profile. Conclusions: Our findings detect masked actionable mutations in down-sampled targeted panels and highlight the need for comprehensive testing to accurately identify actionable mutations in various cancer types. Reporting actionable mutations can significantly influence clinical decision-making, emphasizing the importance of NGS test selection in routine molecular diagnostics as well as the impact of integrating comprehensive NGS testing.

The TAC-GReD trial: The combination of talazoparib and carboplatin in DNA damage repair deficient recurrent high-grade glioma.

2047 Background: Recurrent high-grade glioma (rHGG) has a dismal prognosis with limited treatment options. Given that a high proportion of these gliomas harbor deficiencies in the DNA damage repair (DDRd) pathway, this genomic occurrence may confer synergistic lethality and sensitivity to poly (ADP-ribose) polymerase (PARP) inhibitors. Therefore, we hypothesize that DDRd rHGG may be sensitive to the combination of a PARP inhibitor, talazoparib, and carboplatin. Methods: This is a prospective phase II, single-arm open-label biomarker stratified single-institution trial conducted in Hong Kong (NCT04740190). Tumor tissue was sent for comprehensive next-generation sequencing (C-NGS) to screen for genomic aberrations associated with the DDRd pathway. Patients with rHGG (WHO grade III-IV) and at least one pathogenic mutation in the DDR pathway were deemed eligible. Patients were initially treated with whole-brain radiotherapy (2 Gy/1 Fr) on C1D1. Starting at dose level 0, talazoparib (0.75mg on Days 1-4) and carboplatin (AUC 1.5 on Day 1), were administered weekly for a total of 18 cycles, followed by maintenance talazoparib. The primary endpoint was the 6-month progression-free survival (PFS-6). Results: 61 patients were screened and 33 patients with DDRd rHGG were enrolled, 23 males, 10 females, and a median age of 55 years (range: 29-70 years). 73% (n=24) had a baseline ECOG PS of 0-1. Among the recruited patients, 12% (n=4) were classified as WHO grade III, while the remaining 88% (n=29) were WHO grade IV. Dose level escalation was achieved in 27% (n=9) of the cohort. The 6-PFS was 29% (95% CI 16.2-51.9%) and the median PFS was 3.5 months (95% CI: 2.4-6.3 months). The OS at 3 and 12 months were 90.4% (95% CI 80.7-100%) and 30% (95% CI 17-53%), respectively. The most common grade 3-4 toxicities were neutropenia (21.2%, n=7), thrombocytopenia (18.2%, n=6) and anemia (9.1%, n=3). One patient developed a grade 4 thromboembolic event. Dose level reduction was implemented in 54% (n=18) of patients and treatment was terminated in 6.1% (n=2) due to toxicity. Conclusions: Talazoparib and carboplatin in a DDRd-enriched rHGG is feasible and tolerable. Additional analysis including correlation of biomarkers with long-term outcomes is underway. Clinical trial information: NCT04740190 .

Utilizing comprehensive next-generation sequencing to determine the clinical significance of copy number variation in advanced/metastatic non-small cell lung cancer.

e15174 Background: Large population-based comprehensive tumor genomic profiling using next-generation sequencing (NGS) technology offers insight into the detection of copy number variation (CNV) in advanced/metastatic solid cancers. However, the significance and role of CNV in advanced-stage non-small cell lung cancer (NSCLC) is limited. In this analysis, we investigated the incidence and impact of CNV on patient outcomes. Methods: Patients were recruited as part of an ongoing real-world multicentre prospective NSCLC Precision Oncology Programme in Hong Kong. All patients underwent tissue and liquid NGS using Foundation One CDx and Foundation One Liquid CDx, respectively. Patients were classified into two groups based on CNV status: group 1 (CNV+) was defined as tumors with CNV reported; group 2 (CNV-) was defined as tumors with no CNV reported. The association of clinical factors with CNV was reported using Chi-square tests. The overall survival (OS) was calculated from the date of diagnosis of advanced-stage cancer to the date of death or the last follow-up date. Survival analysis was estimated using the Kaplan-Meier method with the log-rank test. Results: 353 patients were included in this analysis. NGS was performed in 216 (61%) tumor tissues, and 137 (39%) liquid specimens. 37% (n = 129) were female, and 50% (n = 175) were ever-smoker. 63% (n = 223) of our patient cohort harbored druggable mutations. The detection rate of CNV was 74% in tissue and 14% in liquid specimens. Patients with brain, liver, or bone metastasis (p = 0.018) and/or TMB-high (TMB-H) (p = 0.0014) were associated with CNV+. Next, we assessed the impact of CNV on treatment outcomes. Among patients who received immunotherapy ± chemotherapy, CNV+ was associated with a median OS of 20.4 months compared to 31.4 months in the CNV- group (HR:2.09, 95% CI: 1.05-4.16, p = 0.034). In contrast, there was no statistically significant difference in OS among the CNV+ and CNV- patient groups treated with chemotherapy alone. Although not significant, there was a trend towards poorer OS to immunotherapy ± chemotherapy in the TMB-H CNV+ cohort (23.6 months versus 31.4 months; p = 0.082). Conclusions: We demonstrate the significance of CNV as a prognostic tool for the prediction of survival outcomes among lung cancer patients. Our data suggests that CNV represents a distinct entity in advanced/metastatic NSCLC, associated with poorer survival outcomes to immunotherapy.

IMPRESS-Norway: improving public cancer care by implementing precision medicine in Norway; inclusion rates and preliminary results.

In Norway, comprehensive molecular tumour profiling is implemented as part of the public healthcare system. A substantial number of tumours harbour potentially targetable molecular alterations. Therapy outcomes may improve if targeted treatments are matched with actionable genomic alterations. In the IMPRESS-Norway trial (NCT04817956), patients are treated with drugs outside the labelled indication based on their tumours molecular profile. IMPRESS-Norway is a national, prospective, non-randomised, precision cancer medicine trial, offering treatment to patients with advanced-stage disease, progressing on standard treatment. Comprehensive next-generation sequencing, TruSight Oncology 500, is used for screening. Patients with tumours harbouring molecular alterations with matched targeted therapies available in IMPRESS-Norway, are offered treatment. Currently, 24 drugs are available in the study. Primary study endpoints are percentage of patients offered treatment in the trial, and disease control rate (DCR) defined as complete or partial response or stable disease in evaluable patients at 16 weeks (W16) of treatment. Secondary endpoint presented is DCR in all treated patients. Between April 2021 and October 2023, 1,167 patients were screened, and an actionable mutation with matching drug was identified for 358 patients. By the data cut off 186 patients have initiated treatment, 170 had a minimum follow-up time of 16 weeks, and 145 also had evaluable disease. In patients with evaluable disease, the DCR was 40% (58/145). Secondary endpoint analysis of DCR in all treated patients, showed DCR of 34% (58/170). Precision cancer medicine demonstrates encouraging clinical effect in a subset of patients included in the IMPRESS-Norway trial.

Successive next-generation sequencing strategy for optimal fusion gene detection in non-small-cell lung cancer in clinical practice

Metastatic non-small-cell lung cancer (NSCLC) displays various molecular alterations in the RAS-MAPK pathway. In particular, NSCLCs show high rates of targetable gene fusion in ALK, RET, ROS1, NRG1 and NTRK, or MET exon 14 skipping. Rapid and accurate detection of gene fusion in EGFR/KRAS/BRAF mutations is important for treatment selection especially for first-line indications. RNA-based next-generation sequencing (NGS) panels appear to be the most appropriate as all targets are multiplexed in a single run. While comprehensive NGS panels remain costly for daily practice, optimal sequencing strategies using targeted DNA/RNA panel approaches need to be validated. Here, we describe our lung cancer screening strategy using DNA and RNA targeted approaches in a real-life cohort of 589 NSCLC patients assessed for molecular testing. Gene fusions were analysed in 174 patients negative for oncogene driver mutations or ALK immunohistochemistry in a two-step strategy. Targetable alterations were identified in 28% of contributive samples. Non-smokers had a 63.7% probability to have a targetable alteration as compared to 21.5% for smokers. Overall survival was significantly higher (p=0.03) for patients who received a molecularly matched therapy. Our study shows the feasibility in routine testing of NSCLC DNA/RNA molecular screening for all samples in a cost- and time-controlled manner. The significant high fusion detection rate in patients with wild-type RAS-MAPK tumours highlights the importance of amending testing strategies in NSCLC.

Screening of premature ovarian insufficiency associated genes in Hungarian patients with next generation sequencing

BackgroundPremature ovarian insuffiency (POI) is one of the main cause behind infertility. The genetic analysis of POI should be part of the clinical diagnostics, as several genes have been implicated in the genetic background of it. The aim of our study was to analyse the genetic background of POI in a Hungarian cohort.MethodsThe age of onset was between 15 and 39 years. All patients had the 46,XX karyotype and they were prescreened for the most frequent POI associated FMR1 premutation. To identify genetic alterations next-generation sequencing (NGS) of 31 genes which were previously associated to POI were carried out in 48 unrelated patients from Hungary.ResultsMonogenic defect was identified in 16.7% (8 of 48) and a potential genetic risk factor was found in 29.2% (14 of 48) and susceptible oligogenic effect was described in 12.5% (6 of 48) of women with POI using the customized targeted panel sequencing. The genetic analysis identified 8 heterozygous damaging and 4 potentially damaging variants in POI-associated genes. Further 10 potential genetic risk factors were detected in seven genes, from which EIF2B and GALT were the most frequent. These variants were related to 15 genes: AIRE, ATM, DACH2, DAZL, EIF2B2, EIF2B4, FMR1, GALT, GDF9, HS6ST2, LHCGR, NOBOX, POLG, USP9X and XPNPEP2. In six cases, two or three coexisting damaging mutations and risk variants were identified.ConclusionsPOI is characterized by heterogenous phenotypic features with complex genetic background that contains increasing number of genes. Deleterious variants, which were detected in our cohort, related to gonadal development (oogenesis and folliculogenesis), meiosis and DNA repair, hormonal signaling, immune function, and metabolism which were previously associated with the POI phenotype. This is the first genetic epidemiology study targeting POI associated genes in Hungary. The frequency of variants in different POI associated genes were similar to the literature, except EIF2B and GALT. Both of these genes potential risk factor were detected which could influence the phenotype, although it is unlikely that they can be responsible for the development of the disease by themselves. Advances of sequencing technologies make it possible to aid diagnostics of POI Since individual patients show high phenotypic variance because of the complex network controlling human folliculogenesis. Comprehensive NGS screening by widening the scope to genes which were previously linked to infertility may facilitate more accurate, quicker and cheaper genetic diagnoses for POI. The investigation of patient’s genotype could support clinical decision-making process and pave the way for future clinical trials and therapies.

Agnostic Administration of Targeted Anticancer Drugs: Looking for a Balance between Hype and Caution.

Many tumors have well-defined vulnerabilities, thus potentially allowing highly specific and effective treatment. There is a spectrum of actionable genetic alterations which are shared across various tumor types and, therefore, can be targeted by a given drug irrespective of tumor histology. Several agnostic drug-target matches have already been approved for clinical use, e.g., immune therapy for tumors with microsatellite instability (MSI) and/or high tumor mutation burden (TMB), NTRK1-3 and RET inhibitors for cancers carrying rearrangements in these kinases, and dabrafenib plus trametinib for BRAF V600E mutated malignancies. Multiple lines of evidence suggest that this histology-independent approach is also reasonable for tumors carrying ALK and ROS1 translocations, biallelic BRCA1/2 inactivation and/or homologous recombination deficiency (HRD), strong HER2 amplification/overexpression coupled with the absence of other MAPK pathway-activating mutations, etc. On the other hand, some well-known targets are not agnostic: for example, PD-L1 expression is predictive for the efficacy of PD-L1/PD1 inhibitors only in some but not all cancer types. Unfortunately, the individual probability of finding a druggable target in a given tumor is relatively low, even with the use of comprehensive next-generation sequencing (NGS) assays. Nevertheless, the rapidly growing utilization of NGS will significantly increase the number of patients with highly unusual or exceptionally rare tumor-target combinations. Clinical trials may provide only a framework for treatment attitudes, while the decisions for individual patients usually require case-by-case consideration of the probability of deriving benefit from agnostic versus standard therapy, drug availability, associated costs, and other circumstances. The existing format of data dissemination may not be optimal for agnostic cancer medicine, as conventional scientific journals are understandably biased towards the publication of positive findings and usually discourage the submission of case reports. Despite all the limitations and concerns, histology-independent drug-target matching is certainly feasible and, therefore, will be increasingly utilized in the future.

Abstract 2524: Molecular and clinicopathologic landscape of HER2 positive breast cancer: A single institution study

Abstract Background: Human epidermal growth factor receptor 2 (HER2) is a transmembrane tyrosine kinase that is encoded by the ERBB2 gene, located on chromosome 17. Expression levels of HER2 are a key pathogenic and treatment-associated factor in breast carcinomas, with HER2 expression reported as per the ASCO/CAP scoring guidelines. Outside the intense focus on the HER2 overexpression few studies currently exist that look at the comprehensive molecular profile of these aggressive tumors. Design: Our institutional pathology database was searched for patients with breast carcinoma diagnosed between 2009 and 2013 and with HER2 scored as 3+ based on immunohistochemistry, or HER2 2+ with confirmatory positive FISH results. Comprehensive next-generation sequencing (NGS) was performed using the Illumina TruSight Oncology 523 gene panel, and clinicopathologic data were gathered from the institutional electronic health record system. A CoMutation plot was made using the CoMut python library. Results: The mean age of the patients at time of diagnosis was 56.1±12.7 years. The tumors were overwhelmingly high-grade, with 26/30 being grade 3 and the remaining 4/30 being grade 2 and a mean size of 2.6 cm. All were histologically invasive ductal carcinoma, and 26/30 were scored as HER2 3+ on IHC while 4/30 were HER2 2+ with positive FISH. ER was positive in 30% of cases (9/30), PR was positive in 23.3% (7/30), p53 was positive by IHC in 53.3% (16/30), and the mean Ki-67 proliferative index was 47.1%. 20 of the 30 (66%) cases meeting the inclusion criteria had pathogenic mutations detected by NGS testing. Several distinct molecular subgroups were seen on the CoMutation plot (figure 1). The mean tumor mutational burden (TMB) was 14.1 mutations per megabase. A significant subset of the tumors 70% (14/20) showed TP53 mutations, and 30% (6/20) show PIK3CA mutations. Of interest, only 1/14 tumors showed a co-occurring homologous recombination repair gene mutation and one tumor (1/20) showed mutations in 2 homologous recombination pathway genes (FANCA and BRCA1) as well as numerous additional mutations (tumor mutational burden of 65.3 mutations per megabase). Conclusion: Overall the mean TMB was 14.1 mutations/megabase in this HER2-positive breast cancer study set. Over 2/3 of our HER2-positive breast cancer cases also had TP53 mutations. In addition, 1/3 had PIK3CA mutations, suggesting that a subset of HER2-positive carcinomas also harbor other potentially actionable mutations which may increase the effectiveness of our existing interventions. Additional studies are needed to further subclassify genetically distinct subsets of HER2-positive breast cancers and to further understand clinical, pathologic and treatment-related differences in this aggressive breast cancer subset. Citation Format: Gokce Deniz Ardor, Zachary M. Coty-Fattal, Luis Z. Blanco, Kalliopi Siziopikou. Molecular and clinicopathologic landscape of HER2 positive breast cancer: A single institution study [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 2524.

Abstract 317: Using the Biomek NGeniuS Next Generation Library Prep System to automate the Illumina TruSight Oncology 500 assay

Abstract Cancer researchers using next generation sequencing (NGS) need reliable sample preparation methodologies that generate high-quality, sequence-ready libraries from often-challenging samples. This process can be aided using automated liquid handling systems. The Biomek NGeniuS Next Generation Library Prep System from Beckman Coulter Life Sciences is a reliable, easy-to-use, purpose-built liquid handler for NGS library preparation ideal for laboratories requiring more flexibility and less hands-on time. The user-friendly software requires no programming skills, making it easy to set up and run. Biomek NGeniuS Next Generation Library Prep System’s hardware features include an on-deck thermal cycler, gripper, temperature-controlled reagent storage, and high-density tip storage which reduces user interventions and enables more walkaway time. An extensive and growing library of complimentary demonstrated NGS sample prep protocols allows the user to select from a variety of applications for NGS workflows. One such workflow is Illumina TruSight Oncology 500 assay, which represents a comprehensive NGS assay targeting the full coding regions of 523 genes implicated in the pathogenesis of solid tumors. Using enrichment-based library preparation techniques for use with formalin-fixed, paraffin-embedded (FFPE) samples, the Illumina TruSight Oncology 500 assay, when running the DNA Only workflow, can detect single nucleotide variants (SNVs), indels, amplifications, and multinucleotide variants (MNVs) in a single sequencing run. The Illumina TruSight Oncology 500 assay also detects immunotherapy biomarkers for tumor mutational burden (TMB) and microsatellite instability (MSI) in DNA samples. The Illumina TruSight Oncology 500 assay also offers a combined RNA/DNA workflow that also allows for the assessment of fusion events. In this poster, we show the utility of the Biomek NGeniuS Next Generation Library Prep System to perform the Illumina TruSight Oncology 500 assay, which saves researchers valuable hands-on time and offers a highly streamlined setup process for users new to liquid handling automation. Confidential - Company Proprietary Citation Format: Zach Smith. Using the Biomek NGeniuS Next Generation Library Prep System to automate the Illumina TruSight Oncology 500 assay [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 317.