Your search keyword '"Fagereng GL"' showing total 10 results

1. Protein core-dependent glycosaminoglycan modification and glycosaminoglycan-dependent polarized sorting in epithelial Madin–Darby canine kidney cells

Author

Hafte, TT, Fagereng, GL, Prydz, K, Grøndahl, F, and Tveit, H

Published

2011

2. Acta Oncologica Nordic Precision Cancer Medicine Symposium 2023 - merging clinical research and standard healthcare.

Author

Bjørgo E, Fagereng GL, Russnes HG, Smeland S, Taskén K, and Helland Å

Subjects

Humans, Biomedical Research, Scandinavian and Nordic Countries, Delivery of Health Care standards, Congresses as Topic, Precision Medicine methods, Neoplasms therapy, Neoplasms drug therapy, Medical Oncology methods

Published

2024

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

Author

Puco K, Fagereng GL, Brabrand S, Niehusmann P, Støre Blix E, Samdal Steinskog ES, Haug Å, Fredvik Torkildsen C, Oppedal IA, Meltzer S, Flobak Å, Johansson KAM, Bjørge L, Hjortland GO, Dalhaug A, Lund JÅ, Gilje B, Grønlie Cameron M, Hovland R, Falk RS, Smeland S, Giercksky Russnes HE, Taskén K, and Helland Å

Subjects

Humans, Norway, Prospective Studies, Male, Female, Middle Aged, Aged, High-Throughput Nucleotide Sequencing, Molecular Targeted Therapy methods, Adult, Patient Selection, Precision Medicine methods, Neoplasms genetics, Neoplasms therapy, Neoplasms drug therapy

Abstract

Background and Purpose: 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., Patients and Methods: 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., Results: 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)., Interpretation: Precision cancer medicine demonstrates encouraging clinical effect in a subset of patients included in the IMPRESS-Norway trial.

Published

2024

4. PCM4EU and PRIME-ROSE: Collaboration for implementation of precision cancer medicine in Europe.

Author

Taskén K, F Haj Mohammad S, Fagereng GL, Sørum Falk R, Helland Å, Barjesteh van Waalwijk van Doorn-Khosrovani S, Steen Carlsson K, Ryll B, Jalkanen K, Edsjö A, Russnes HG, Lassen U, Hallersjö Hult E, Lugowska I, Blay JY, Verlingue L, Abel E, Lowery MA, Krebs MG, Staal Rohrberg K, Ojamaa K, Oliveira J, Verheul HMW, Voest EE, and Gelderblom H

Subjects

Humans, Europe, European Union, Drug Repositioning, Clinical Trials as Topic organization & administration, Precision Medicine methods, Neoplasms therapy

Abstract

Background: In the two European Union (EU)-funded projects, PCM4EU (Personalized Cancer Medicine for all EU citizens) and PRIME-ROSE (Precision Cancer Medicine Repurposing System Using Pragmatic Clinical Trials), we aim to facilitate implementation of precision cancer medicine (PCM) in Europe by leveraging the experience from ongoing national initiatives that have already been particularly successful., Patients and Methods: PCM4EU and PRIME-ROSE gather 17 and 24 partners, respectively, from 19 European countries. The projects are based on a network of Drug Rediscovery Protocol (DRUP)-like clinical trials that are currently ongoing or soon to start in 11 different countries, and with more trials expected to be established soon. The main aims of both the projects are to improve implementation pathways from molecular diagnostics to treatment, and reimbursement of diagnostics and tumour-tailored therapies to provide examples of best practices for PCM in Europe., Results: PCM4EU and PRIME-ROSE were launched in January and July 2023, respectively. Educational materials, including a podcast series, are already available from the PCM4EU website (http://www.pcm4eu.eu). The first reports, including an overview of requirements for the reimbursement systems in participating countries and a guide on patient involvement, are expected to be published in 2024., Conclusion: PCM4EU and PRIME-ROSE were launched in January and July 2023, respectively. Educational materials, including a podcast series, are already available from the PCM4EU website (http://www.pcm4eu.eu). The first reports, including an overview of requirements for the reimbursement systems in participating countries and a guide on patient involvement, are expected to be published in 2024., Conclusion: European collaboration can facilitate the implementation of PCM and thereby provide affordable and equitable access to precision diagnostics and matched therapies for more patients.

Published

2024

5. The impact of level of documentation on the accessibility and affordability of new drugs in Norway.

Author

Fagereng GL, Morvik AM, Reinvik Ulimoen S, Ringerud AM, Dahlen Syversen I, and Sagdahl E

Abstract

Introduction: Over the preceding decade, an increasing number of drugs have been approved by the European Medicines Agency (EMA) with limited knowledge of their relative efficacy. This is due to the utilization of non-randomized, single-arm studies, surrogate endpoints, and shorter follow-up time. The impact of this trend on the accessibility and affordability of newly approved drugs in Europe remains uncertain. The primary objective of this study is to provide insights into the issues of accessibility and affordability of new drugs in the Norwegian healthcare system. Method: The presented study entails an analysis of all reimbursement decisions for hospital drugs in Norway spanning 2021-2022. The included drugs were approved by the EMA between 2014 and 2022, with the majority (91%) receiving approval between 2018 and 2022. The drugs were categorized based on the level of documentation of relative efficacy. Approval rates and costs (confidential net-prices) were compared. Results: A total of 35% (70/199) of the reimbursement decisions were characterized by limited certainty regarding relative efficacy and as a consequence the Norwegian Health Technology Assessment (HTA) body did not present an incremental cost-effectiveness ratio (ICER) in the HTA report. Within this category, a lower percentage of drugs (47%) gained reimbursement approval compared to those with a higher certainty level, which were presented with an ICER (58%). On average, drugs with an established relative efficacy were accepted with a 4.4-fold higher cost (confidential net-prices). These trends persisted when specifically examining oncology drugs. Conclusion: Our study underscores that a substantial number of recently introduced drugs receive reimbursement regardless of the level of certainty concerning relative efficacy. However, the results suggest that payers prioritize documented over potential efficacy. Given that updated information on relative efficacy may emerge post-market access, a potential solution to address challenges related to accessibility and affordability in Europe could involve an increased adoption of market entry agreements. These agreements could allow for price adjustments after the presentation of new knowledge regarding relative efficacy, potentially resolving some of the current challenges., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Fagereng, Morvik, Reinvik Ulimoen, Ringerud, Dahlen Syversen and Sagdahl.)

Published

2024

6. [Raising the quality of cancer treatment].

Author

Helland Å, Steinskog ESS, Blix ES, Flobak Å, Brabrand S, Puco K, Niehusmann P, Meltzer S, Oppedal IA, Haug Å, Torkildsen CF, Randen U, Gilje B, Lønning PE, Gjertsen BT, Hovland R, Russnes HG, Fagereng GL, Smeland S, and Tasken K

Published

2024

7. Correction to: Improving public cancer care by implementing precision medicine in Norway: IMPRESS-Norway.

Author

Helland Å, Russnes HG, Fagereng GL, Al-Shibli K, Andersson Y, Berg T, Bjørge L, Blix E, Bjerkehagen B, Brabrand S, Cameron MG, Dalhaug A, Dietzel D, Dønnem T, Enerly E, Flobak Å, Fluge S, Gilje B, Gjertsen BT, Grønberg BH, Grønås K, Guren T, Hamre H, Haug Å, Heinrich D, Hjortland GO, Hovig E, Hovland R, Iversen AC, Janssen E, Kyte JA, von der Lippe Gythfeldt H, Lothe R, Lund JÅ, Meza-Zepeda L, Munthe-Kaas MC, Nguyen OTD, Niehusmann P, Nilsen H, Puco K, Ree AH, Riste TB, Semb K, Steinskog ESS, Stensvold A, Suhrke P, Tennøe Ø, Tjønnfjord GE, Vassbotn LJ, Aas E, Aasebø K, Tasken K, and Smeland S

Published

2022

8. Improving public cancer care by implementing precision medicine in Norway: IMPRESS-Norway.

Author

Helland Å, Russnes HG, Fagereng GL, Al-Shibli K, Andersson Y, Berg T, Bjørge L, Blix E, Bjerkehagen B, Brabrand S, Cameron MG, Dalhaug A, Dietzel D, Dønnem T, Enerly E, Flobak Å, Fluge S, Gilje B, Gjertsen BT, Grønberg BH, Grønås K, Guren T, Hamre H, Haug Å, Heinrich D, Hjortland GO, Hovig E, Hovland R, Iversen AC, Janssen E, Kyte JA, von der Lippe Gythfeldt H, Lothe R, Lund JÅ, Meza-Zepeda L, Munthe-Kaas MC, Nguyen OTD, Niehusmann P, Nilsen H, Puco K, Ree AH, Riste TB, Semb K, Steinskog ESS, Stensvold A, Suhrke P, Tennøe Ø, Tjønnfjord GE, Vassbotn LJ, Aas E, Aasebø K, Tasken K, and Smeland S

Subjects

Humans, Medical Oncology, Precision Medicine, Prospective Studies, Antineoplastic Agents therapeutic use, Neoplasms diagnosis, Neoplasms genetics, Neoplasms therapy

Abstract

Background: Matching treatment based on tumour molecular characteristics has revolutionized the treatment of some cancers and has given hope to many patients. Although personalized cancer care is an old concept, renewed attention has arisen due to recent advancements in cancer diagnostics including access to high-throughput sequencing of tumour tissue. Targeted therapies interfering with cancer specific pathways have been developed and approved for subgroups of patients. These drugs might just as well be efficient in other diagnostic subgroups, not investigated in pharma-led clinical studies, but their potential use on new indications is never explored due to limited number of patients., Methods: In this national, investigator-initiated, prospective, open-label, non-randomized combined basket- and umbrella-trial, patients are enrolled in multiple parallel cohorts. Each cohort is defined by the patient's tumour type, molecular profile of the tumour, and study drug. Treatment outcome in each cohort is monitored by using a Simon two-stage-like 'admissible' monitoring plan to identify evidence of clinical activity. All drugs available in IMPRESS-Norway have regulatory approval and are funded by pharmaceutical companies. Molecular diagnostics are funded by the public health care system., Discussion: Precision oncology means to stratify treatment based on specific patient characteristics and the molecular profile of the tumor. Use of targeted drugs is currently restricted to specific biomarker-defined subgroups of patients according to their market authorization. However, other cancer patients might also benefit of treatment with these drugs if the same biomarker is present. The emerging technologies in molecular diagnostics are now being implemented in Norway and it is publicly reimbursed, thus more cancer patients will have a more comprehensive genomic profiling of their tumour. Patients with actionable genomic alterations in their tumour may have the possibility to try precision cancer drugs through IMPRESS-Norway, if standard treatment is no longer an option, and the drugs are available in the study. This might benefit some patients. In addition, it is a good example of a public-private collaboration to establish a national infrastructure for precision oncology. Trial registrations EudraCT: 2020-004414-35, registered 02/19/2021; ClinicalTrial.gov: NCT04817956, registered 03/26/2021., (© 2022. The Author(s).)

Published

2022

9. A national precision cancer medicine implementation initiative for Norway.

Author

Taskén K, Russnes HEG, Aas E, Bjørge L, Blix ES, Enerly E, Fagereng GL, Flobak Å, Gilje B, Gjertsen BT, Guren TK, Heix J, Hovig E, Hovland R, Lønning PE, Meza-Zepeda LA, Mæhle PM, Nilsen HL, Thoresen SØ, Widerberg K, Smeland S, and Helland Å

Subjects

Humans, Norway, Neoplasms genetics, Neoplasms therapy, Precision Medicine

Published

2022

10. A secretory Golgi bypass route to the apical surface domain of epithelial MDCK cells.

Author

Tveit H, Akslen LK, Fagereng GL, Tranulis MA, and Prydz K

Subjects

Animals, Biological Transport, Brefeldin A metabolism, Brefeldin A pharmacology, Cell Line, Cell Polarity, Culture Media, Serum-Free, Dogs, Dose-Response Relationship, Drug, Glycoproteins metabolism, Green Fluorescent Proteins metabolism, Models, Biological, Protein Transport drug effects, Proteoglycans metabolism, Transfection, Vesicular Transport Proteins metabolism, Epithelial Cells metabolism, Golgi Apparatus metabolism

Abstract

Proteins leave the endoplasmic reticulum (ER) for the plasma membrane via the classical secretory pathway, but routes bypassing the Golgi apparatus have also been observed. Apical and basolateral protein secretion in epithelial Madin-Darby canine kidney (MDCK) cells display differential sensitivity to Brefeldin A (BFA), where low concentrations retard apical transport, while basolateral transport still proceeds through intact Golgi cisternae. We now describe that BFA-mediated retardation of glycoprotein and proteoglycan transport through the Golgi apparatus induces surface transport of molecules lacking Golgi modifications, possessing those acquired in the ER. Low concentrations of BFA induces apical Golgi bypass, while higher concentrations were required to induce basolateral Golgi bypass. Addition of the KDEL ER-retrieval sequence to model protein cores allowed observation of apical Golgi bypass in untreated MDCK cells. Basolateral Golgi bypass was only observed after the addition of BFA or upon cholesterol depletion. Thus, in MDCK cells, an apical Golgi bypass route can transport cargo from pre-Golgi organelles in untreated cells, while the basolateral bypass route is inducible.

Published

2009