CDK Inhibitor Patent Landscape 2009

리서치사	France Innovation Scientifique et Transfert (FIST SA)
발행일	2009년 11월	상품코드	103038
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한글목차
영문목차
관련자료

영문목차

Abstract

Regulating cell function by controlling cell pathways is an important strategy in the development of agents for the treatment of cancer and numerous other diseases. Protein kinases are a family of enzymes involved in the regulation of almost all cell processes. Scientists have identified 518 kinases encoded by the human genome. By adding phosphate groups to substrate proteins, these enzymes control the activity, the location, the association of these substrate proteins with other proteins and their function. Thus kinases play an essential role in signal transduction and the coordination of complex functions in particular the cell cycle.

Because alterations in protein phosphorylation are frequently associated with human disease, investment in the development of pharmacological inhibitors of protein kinases has grown exponentially. About 30% of existing drug discovery programs in the pharmaceutical industry target a protein kinase (reviewed in Cohen, Nature reviews drug discovery, 2002; Fischer & Gianella Borradori, Exp. Opin. Investig. Drugs, 2005; Grant, Cell. Mol. Life Sci., 2009). Today, dozens of kinase inhibitors are on the market to treat cancer and the cumulated sales of the blockbuster drug Gleevec (tyrosine kinase inhibitor, Novartis) was $3.7 billion in 2008 (Novartis annual report 2008). However, no pharmacological cyclin-dependent kinase inhibitors (CDK, serine/threonine protein kinases), a key kinase sub-family, have yet reached the market. Although this sub-family includes 20 members (and 25 cyclins) in humans, a more limited number has been identified. To constitute active protein kinase complexes (see figure 1), CDKs are regulated by transient association with a regulatory partner (cyclins), go through various post-translational modifications (e.g. phosphorylation) and transient association with a natural inhibitory protein (Cip1, Kip1/2 or Ink4A-D).

This family is of particular interest because of its essential involvement in neuronal cell physiology (CDK5), pain signalling (CDK5), apoptosis (CDK1, CDK2, CDK5), transcription (CDK7, CDK8, CDK9), RNA splicing (CDK11), differentiation (CDK2, CDK5, CDK6, CDK9) and especially cell cycle control (CDK1, CDK2, CDK3, CDK4, CDK6, CDK7, CDK10; see figure 2). In addition P. Nurse, L. Artwell and T. Hunt were awarded the Nobel Prize in Physiology/Medicine in 2001 for their work in the discovery of the role of cyclins and CDK in the control of the cell cycle.

METHODOLOGY

INTRODUCTION

1. BRIEF OUTLINE OF THE PIPELINE

2. PROTECTION STRATEGIES

2.1. Evolution of patent filings over time
2.2. Priority filings
2.3.Extensions
2.4. Analysis of industrial patents over time
2.5. Study of the granting of US patents
2.6. Study of the granting of European patents
2.7. Evolution in the number of applicants

3. TOPOLOGY OF PATENTS IN THE SECTOR

3.1. Breakdown of patents into classes of CDK inhibitors
3.2. Breakdown of patents into types of targeted CDK
3.3. Cross analysis of the categories "classes of CDK inhibitors" and "types of targeted CDK"

4. ANALYSIS OF THE MAIN APPLICANTS

4.1. Main applicants
4.2. Filings by main applicants over time
4.3. Focus on the global strategy of the major industrial applicants
4.4. Topics protected
4.5.Collaborations
4.6. Citations between applicants
4.7. Emerging applicants

5. ANALYSIS OF THE MAIN INVENTORS

5.1. Main inventors
5.2. Topics protected
5.3. Research teams
5.4. Experts
5.5. Emerging inventors

CONCLUSION

APPENDIX 1: APPLICANTS WITH ACTIVE CLINICAL TRIALS AND THEIR NUMBER OF PATENT FILINGS

APPENDIX 2: PATENT FILINGS OF APPLICANTS BY MAIN TOPICS

APPENDIX 3: NUMBER OF PATENT FILINGS PER APPLICANTS

List of Figures

FIGURE 1 - SCHEMATIC REGULATION OF THE CDK-CYCLIN COMPLEX
FIGURE 2 - THE CELL CYCLE AND ITS REGULATION BY CDK
FIGURE 3 - CDK INHIBITORS UNDER DEVELOPMENT BY CLASS OF COMPOUNDS (AUGUST 2009)
FIGURE 4 - EVOLUTION IN PATENT FILINGS
FIGURE 5 - GEOGRAPHIC DISTRIBUTION OF PRIORITY FILINGS
FIGURE 6 - GEOGRAPHIC DISTRIBUTION OF EXTENSIONS
FIGURE 7 - EVOLUTION OF THE BREAKDOWN OF INDUSTRIAL PATENTS
FIGURE 8 - EVOLUTION OF AVERAGE GRANT TIME FOR US PATENTS
FIGURE 9 - EVOLUTION OF THE GRANTING OF US PATENTS
FIGURE 10 - EVOLUTION OF AVERAGE GRANT TIME FOR EUROPEAN PATENTS
FIGURE 11 - EVOLUTION OF AVERAGE GRANT TIME FOR EUROPEAN PATENTS
FIGURE 12 - EVOLUTION OF THE NUMBER OF APPLICANTS
FIGURE 13 - BREAKDOWN OF THE PORTFOLIO BY CLASSES OF COMPOUNDS
FIGURE 14 - BREAKDOWN OF THE PORTFOLIO BY TYPES OF TARGETED CDK
FIGURE 15 - CROSS-ANALYSIS OF THE CATEGORIES "CLASSES OF CDK INHIBITORS" AND "TYPES OF TARGETED CDK"
FIGURE 16 - MAIN APPLICANTS IN THE ENTIRE PORTFOLIO
FIGURE 17 - BREAKDOWN OF THE MAIN PATENT PORTFOLIOS
FIGURE 18 - EXTENSION POLICY FOR THE FIVE MAJOR INDUSTRIAL PLAYERS
FIGURE 19 - CLASSES OF CDK INHIBITORS BY MAIN APPLICANTS
FIGURE 20 - TYPES OF TARGETED CDK BY MAIN APPLICANTS
FIGURE 21 - MAIN PLAYERS POSITIONED ON THE DEVELOPMENT OF SCREENING METHODS, COMBINATIONS AND OLIGONUCLEOTIDES (>3 FILINGS)
FIGURE 22 - MAJOR COLLABORATIONS AND JOINT-FILINGS
FIGURE 23 - MAP OF CITATIONS BETWEEN APPLICANTS
FIGURE 24 - CLASSES OF CDK INHIBITORS BY MAIN INVENTORS
FIGURE 25 - TYPES OF TARGETED CDK BY MAIN INVENTORS
FIGURE 26 - MAIN RESEARCH TEAM
FIGURE 27 - LIST OF EXPERT

List of Tables

TABLE 1 - CYCLIN DEPENDENT KINASES INVOLVED IN DISEASES OR REPRODUCTION
TABLE 2 - EVOLUTION OF PRIORITY FILINGS
TABLE 3 - EVOLUTION OF EXTENSIONS
TABLE 4 - DESCRIPTION OF THE CLASSES OF COMPOUNDS USED TO BREAK DOWN THE PORTFOLIO
TABLE 5 - BREAKDOWN BY CLASSES OF CDK INHIBITORS OVER TIME
TABLE 6 - BREAKDOWN BY SCREENING METHODS, COMBINATIONS AND OLIGONUCLEOTIDES OVER TIME
TABLE 7 - BREAKDOWN BY CLASSES OF CDK INHIBITORS OVER TIME
TABLE 8 - BREAKDOWN OF FILINGS BY MAIN APPLICANTS OVER TIME
TABLE 9 - EMERGING APPLICANTS
TABLE 10 -LIST OF THE MAIN INVENTORS
TABLE 11 -EMERGING INVENTORS