ABSTRACT
A novel human recombinant antibody for prophylactic treatment against SARS-CoV-2 was formulated in a nasal solution comprising chitosan as mucoadhesive polymer. Two levels of protein concentration have been assessed and formulations loaded into Aptar VP3 nasal pump. The formulations produced showed values of pH (6.2- 6.3) and osmolality (414 and 421 mosm/kg) suitable to prevent precipitation of the antibody in the final solution and for nasal administration. Assay of the protein after formulation manufacturing showed a lower dimeric fraction than the reference standard and hydrodynamic diameter of the final formulations was also comparable to the unprocessed antibody solution (10 nm). Zeta-potential values were higher than 25mV, indicating colloidal stability against aggregation due to charge stabilization for the formulations obtained. Spray performance did not evidence any difference between protein levels in the final formulations when combined with VP3 nasal pump. Particularly, droplet size distribution (mean volume diameter of 55.13 lm for the low dose formulation and 57.21 lm for the high dose), spray pattern and plume geometry resulted to be applicable for nasal delivery. Finally, for both solutions sprayed antibody content was within 75-125% of the target delivered dose with a very low variability on ten consecutive shots (5%). Future studies will assess the formulations stability under refrigerated and ambient storage conditions of the combination product and of the antibody comprised in the formulation,whereas in vivo studieswill define pharmacokinetics and pharmacodynamics profile of these final formulations. Key Message: The possibility to deliver to the nose a novel human antibody for prophylactic treatment against SARS-CoV-2 employing Aptar VP3 pump was assessed. Spray performance of the formulations manufactured was characterized and no protein agglomeration was observed in the formulations and after spraying, indicating favourable results in applying this system for delivery of antibodies to the nose.
ABSTRACT
Background: Most patients with pancreatic cancer (PC) and biliary tract cancer (BTC) present with advanced disease. In confirmed cases, circulating tumour DNA (ctDNA) may be detected through liquid biopsy in 80-90%. Obtaining a diagnostic biopsy can be technically challenging, require complex invasive procedures and may not be feasible due to comorbidity. Reduction in capacity of aerosol generating diagnostic procedures in many healthcare systems due to COVID19 has highlighted the unmet need for simple, noninvasive diagnostic tools. We piloted the use of ctDNA to support the diagnostic pathway in patients with suspected cancer across 6 tumour types, here we present its use in PC/BTC. Methods: This single centre prospective cohort pilot trial was conducted at the Royal Marsden from June 2020 to August 2021. 16 patients were planned each in the PC and BTC cohorts. Eligibility included radiologically suspicious PC/BTC without histological diagnosis, patients with prior non-diagnostic biopsy and inaccessible tumours. Liquid biopsy for ctDNA was collected for plasma based next generation sequencing, using a custom 59 gene panel of common variants in PC/BTC tumours, including analysis for somatic, copy number and structural variants. Clonal haematopoiesis of indeterminate potential (CHIP) and germline variants were identified and subtracted. A molecular tumour board (MTB) reviewed results for interpretation and clinical context. Primary outcome was the proportion of patients with a ctDNA result consistent with a diagnosis of malignancy following MTB discussion. Results: 32 patients with suspected PC (n= 16) and BTC (n=16) were recruited. Baseline characteristics are shown in table. ctDNA was detected in 69% off, 23 patients had a subsequent biopsy. The sensitivity and specificity of ctDNA as a diagnostic tool was 80% (90% CI 49.3-96.3) and 100% (90% CI 36.8-100) for PC respectively, and 100% (90% CI 60.7-100) and 75% (90% CI 24.9- 98.7) for BTC respectively. There were 2 false negatives in the PC cohort subsequently diagnosed with PC, and 1 false positive in the BTC cohort subsequently diagnosed with oesophageal cancer. Conclusions: ctDNA can be used to support a diagnosis of cancer in patients with radiologically suspected PC/BTC. A blood first, tissue second strategy in the diagnosis of PC/BTC could improve diagnostic efficiency, speed, and add resilience to the current diagnostic pathway.