Brain exposure can affect drug development success for all diseases. For neuroscience therapeutics, a leading area of pharmaceutical research, development, and product portfolios in pharmaceutical companies and research institutions, insufficient brain exposure leaves many central nervous system (CNS) diseases untreated or without optimum drugs, despite the vast resources applied to the problem. Researchers working to treat CNS diseases were stymied by the blood–brain barrier (BBB), but, in recent years, experience led to improved drug exposure at brain targets. Conversely, researchers working on peripheral diseases encountered CNS side effects owing to brain exposure at unintended CNS targets, but they are increasingly successful at reducing brain exposure. These advances on brain exposure came as pharmaceutical science uncovered the intricacies of drug molecule interactions at the BBB and within brain tissue. Newly discovered interactions provide an opportunity to overcome previous project disappointments, understand previously unexplained observations, and enable new tools for successful drug development.

This book comprises the contributions of experts regarding the complex interactions encountered by drug molecules that affect brain exposure and their successful solution in drug discovery, development, and clinical studies, including the following:

A primary cause of the disappointment in developing CNS disease treatments is that the brain is a difficult organ for drug therapy. In past years, a high percentage of promising CNS drug candidates have failed. A major cause of this failure is the restricted access of many drug candidates circulating in the blood to penetrate into the brain owing to the BBB. Chapters 2 and 4 discuss the physiology of the BBB and differences among species and disease states. For most organs, drug molecules freely move between the blood and tissue via open junctions between capillary cells, but the BBB presents greater restrictions via tight junctions that reduce drug molecule access to brain tissue. Thus, molecules that do not have facile passive transcellular diffusion (e.g., acids, biologics) are restricted. In addition, efflux transporters (e.g., Pgp, BCRP), actively pump the molecules of some compounds out of the brain. These barriers to BBB permeation and the general characteristics of compounds that are efflux substrates are detailed in Chapters 5 and 6. These barriers effectively reduce the concentration, and therefore the efficacy, of some potentially therapeutic drug molecules to brain cells.

Another component of brain exposure restriction is binding of drug molecules to blood and brain tissue components. This restricts the free drug concentration that is available to bind to the therapeutic target protein molecules. In past years, the concentration of drug molecules that are available to bind to the brain target was assumed to be the total concentration measured in the brain tissue. However, in recent years, there has been a major shift in acceptance and application of the Free Drug Hypothesis, which states that only the unbound drug molecules are available to bind to the target to produce efficacy. Binding varies with the structure and physicochemical properties of each compound. This recognition has solved many previously unexplained failures in translation from in vitro activity to in vivo efficacy. The primary role of free drug concentration in determining in vivo efficacy is now being widely applied to CNS research and is reviewed in Chapter 3.

Many drug candidates for peripheral therapeutic targets have minimal restrictions in penetrating the BBB and affecting brain targets. For example, they may have high passive diffusion through the BBB endothelial cells and not be efflux substrates. These drugs penetrate into the brain and may interact with CNS targets to cause difficult side effects for patients. Such effects lead to research project cancelation, regulatory rejection, drug product use restrictions, reduction of patient administration compliance, and long-term toxicities. For these reasons, drug researchers and developers need to investigate whether a new drug candidate causes unfavorable CNS effects in vivo. Chapters 20 and 21 explain this issue for peripheral drugs and how it may be overcome.

As the interactions affecting brain exposure are elucidated, in silico, in vitro, and in vivo methods for these interactions are developed. In addition, these interactions are included in methods for in vivo projection. Such methods allow drug researchers to screen for potential problems, measure specific interactions (e.g., Pgp efflux), and quantitate how they affect drug tissue concentrations in vivo. These tools provide reliable information for lead selection and optimization to benefit drug research projects throughout their progress. Chapter 9 discusses the development and state of the art of in silico BBB predictions. BBB permeability is often predicted using in vitro artificial and cell membrane assays (Chapters 10 and 11). Another component of brain exposure assessment is in vitro assays for brain binding, as discussed in Chapter 12. This information is typically used in combination with in vivo brain exposure studies (Chapter 13) to determine the free drug concentration in brain tissue. Direct measurement of free drug concentration using microdialysis is reviewed in Chapter 16. Another important advance in the field of brain exposure is the replacement of the Log BB and B/P parameters by the more valuable K_p,uu, the free drug distribution coefficient between brain and plasma, as discussed in Chapters 2, 3, 4, and 18. There is an increasing sophistication in PBPK modeling for the BBB (Chapter 14) and PK/PD model...