A balanced evaluation of the evidence for adult neurogenesis in humans: implication for neuropsychiatric disorders.

There is a widespread belief that neurogenesis exists in adult human brain, especially in the dentate gyrus, and it is to be maintained and, if possible, augmented with different stimuli including exercise and certain drugs. Here, we examine the evidence for adult human neurogenesis and note important limitations of the methodologies used to study it. A balanced review of the literature and evaluation of the data indicate that adult neurogenesis in human brain is improbable. In fact, in several high-quality recent studies in adult human brain, unlike in adult brains of other species, neurogenesis was not detectable. These findings suggest that the human brain requires a permanent set of neurons to maintain acquired knowledge for decades, which is essential for complex high cognitive functions unique to humans. Thus, stimulation and/or injection of neural stem cells into human brains may not only disrupt brain homeostatic systems, but also disturb normal neuronal circuits. We propose that the focus of research should be the preservation of brain neurons by prevention of damage, not replacement.

New Insight into the Dietary Cause of Atherosclerosis: Implications for Pharmacology.

At present, the guideline approach to the medical treatment and prevention of atherosclerotic cardiovascular disease (ASCVD) is to classify patients by risk and treat the known risk factors (contributory causes), e.g., hypertension, diabetes, obesity, smoking, and poor diet, as appropriate. All high-risk patients should receive statins. This approach has had substantial success but ASCVD still remains the number one cause of death in the United States. Until recently, the underlying cause of ASCVD remained unknown, although a potential dietary cause was suggested by the fact that vegetarians, especially vegans, have a much lower incidence of ASCVD than animal flesh eaters. Recently, consistent with the vegetarian data, substantial evidence for a cause of ASCVD in animals and humans has been discovered. Trimethylamine (TMA)-containing dietary compounds in meat, milk, and other animal foods (e.g., lecithin, choline, and carnitine) are converted by closely related gut bacterial TMA lyases to TMA, which is absorbed and converted predominantly by flavin mono-oxygenase 3 to the toxic trimethylamine N-oxide (TMAO). TMAO causes atherosclerosis in animals and is elevated in patients with coronary heart disease. Inhibition of bacterial lyases in mice prevents TMA and secondarily TMAO formation and atherosclerosis, strong evidence for the TMAO hypothesis. At present, the challenge for the pharmaceutical industry is to discover and develop a potent "broad spectrum" bacterial lyase inhibitor that, along with diet and exercise, could, if the TMAO hypothesis is correct, revolutionize the preventive treatment of ASCVD.

Dehydroascorbic acid for the treatment of acute ischemic stroke.

In animal models of acute ischemic stroke, intravenous dehydroascorbic acid (DHAA), unlike ascorbic acid (AA), readily enters brain and is converted in both normal and ischemic brain into protective ascorbic acid. When given parenterally DHAA minimizes infarct volume and facilitates functional recovery. I hypothesize the same effect will occur in humans with acute ischemic stroke. Efficacy in reducing infarct volume is demonstrable in mice and rats even when DHAA is infused three hours after the experimental infarct. Moreover, there is fivefold mechanistic rational for DHA beside excellent pharmacokinetics and rapid penetration of brain and conversion to protective AA: (1) in ischemic brain, there is a precipitous decline in AA which can be reversed by intravenous DHAA; (2) after reduction of DHAA to AA in both normal and ischemic brain, AA can reduce oxidized vitamin E and glutathione, other protectors of brain against damaging reactive oxygen species which build up in ischemic brain; (3) AA itself can protect brain against damaging reactive oxygen species; (4) AA is an essential cofactor for several enzymes in brain including ten-eleven translocase-2 which upregulates production of protective molecules like brain-derived neurotrophic factor; and (5) DHAA after conversion to AA prevents both lipid oxidation and presumably oxidation of other labile substances (e.g., dopamine) in ischemic brain. In terms of safety, based on all available animal information, DHAA is safe in the proposed dosing regimen. For human clinical trials, the methodology for conducting the proposed animal safety, clinical pharmacology and phase II efficacy studies is straightforward. Finally, if DHAA preserved brain substance and function in humans, it could be employed in pre-hospital stroke patients.

A balanced view of the cerebrospinal fluid composition and functions: Focus on adult humans.

In this review, a companion piece to our recent examination of choroid plexus (CP), the organ that secretes the cerebrospinal fluid (CSF), we focus on recent information in the context of reliable older data concerning the composition and functions of adult human CSF. To accomplish this, we define CSF, examine the methodology employed in studying the CSF focusing on ideal or near ideal experiments and discuss the pros and cons of several widely used analogical descriptions of the CSF including: the CSF as the "third circulation," the CSF as a "nourishing liquor," the similarities of the CSF/choroid plexus to the glomerular filtrate/kidney and finally the CSF circulation as part of the "glymphatic system." We also consider the close interrelationship between the CSF and extracellular space of brain through gap junctions and the paucity of data suggesting that the cerebral capillaries secrete a CSF-like fluid. Recently human CSF has been shown to be in dynamic flux with heart-beat, posture and especially respiration. Functionally, the CSF provides buoyancy, nourishment (e.g., vitamins) and endogenous waste product removal for the brain by bulk flow into the venous (arachnoid villi and nerve roots) and lymphatic (nasal) systems, and by carrier-mediated reabsorptive transport systems in CP. The CSF also presents many exogenous compounds to CP for metabolism or removal, indirectly cleansing the extracellular space of brain (e.g., of xenobiotics like penicillin). The CSF also carries hormones (e.g., leptin) from blood via CP or synthesized in CP (e.g., IGF-2) to the brain. In summary the CP/CSF, the third circulation, performs many functions comparable to the kidney including nourishing the brain and contributing to a stable internal milieu for the brain. These tasks are essential to normal adult brain functioning.

A balanced view of choroid plexus structure and function: Focus on adult humans.

Recently tremendous progress has been made in studying choroid plexus (CP) physiology and pathophysiology; and correcting several misconceptions about the CP. Specifically, the details of how CP, a locus of the blood-CSF barrier (BCSFB), secretes and purifies CSF, generates intracranial pressure (ICP), maintains CSF ion homeostasis, and provides micronutrients, proteins and hormones for neuronal and glial development, maintenance and function, are being understood on a molecular level. Unequivocal evidence that the CP secretory epithelium is the predominant supplier of CSF for the ventricles comes from multiple lines: uptake kinetics of tracer (22)Na and (36)Cl penetration from blood to CSF, autoradiographic mapping of rapid (22)Na and (36)Cl permeation (high permeability coefficients) into the cerebroventricles, CSF sampling from several different in vivo and in vitro CP preparations, CP hyperplasia that increases CSF formation and ICP; and in vitro analysis of CP ability to transport molecules (with expected directionality) and actively secrete fluid against an hydrostatic fluid column. Furthermore, clinical support for this CP-CSF model comes from neurosurgical procedures to remove lateral ventricle CPs in hydrocephalic children to reduce CSF formation, thereby relieving elevated ICP. In terms of micronutrient transport, ascorbic acid, folate and other essential factors are transported by specific (cloned) carriers across CP into ventricular CSF, from which they penetrate across the ependyma and pia mater deeply into the brain to support its viability and function. Without these choroidal functions, severe neurological disease and even death can occur. In terms of efflux or clearance transport, the active carriers (many of which have been cloned and expressed) in the CP basolateral and apical membranes perform regulatory removal of some metabolites (e.g. choline) and certain drugs (e.g. antibiotics like penicillin) from CSF, thus reducing agents such as penicillin to sub-therapeutic levels. Altogether, these multiple transport and secretory functions in CP support CSF homeostasis and fluid dynamics essential for brain function.

The nexus of vitamin homeostasis and DNA synthesis and modification in mammalian brain.

The purpose of this review is to discuss the implications of the 2009 discovery of the sixth deoxyribonucleoside (dN) [5-hydroxymethyldeoxycytidine (hmdC)] in DNA which is the most abundant in neurons. The concurrent discovery of the three ten-eleven translocation enzymes (TET) which not only synthesize but also oxidize hmdC in DNA, prior to glycosylase removal and base excision repair, helps explain many heretofore unexplained phenomena in brain including: 1) the high concentration of ascorbic acid (AA) in neurons since AA is a cofactor for the TET enzymes, 2) the requirement for reduced folates and the dN synthetic enzymes in brain, 3) continued DNA synthesis in non-dividing neurons to repair the dynamic formation/removal of hmdC, and 4) the heretofore unexplained mechanism to remove 5-methyldeoxycytidine, the fifth nucleoside, from DNA. In these processes, we also describe the important role of choroid plexus and CSF in supporting vitamin homeostasis in brain: especially for AA and folates, for hmdC synthesis and removal, and methylated deoxycytidine (mdC) removal from DNA in brain. The nexus linking AA and folates to methylation, hydroxymethylation, and demethylation of DNA is pivotal to understanding not only brain development but also the subsequent function.

Sustained choroid plexus function in human elderly and Alzheimer's disease patients.

We and other investigators have postulated deterioration of essential choroid plexus (CP) functions in some elderly and especially Alzheimer's disease patients based on apparent anatomical, histological and pathological changes in CP. We have termed this putative phenomenon CP failure. By focusing on four essential energy-requiring CP functions, specifically ascorbic acid (AA) and folate transport from blood into CSF, transthyretin synthesis and secretion into CSF, and electrolyte/acid-base balance in CSF, we were able to evaluate the hypothesis of CP failure by reviewing definitive human data. In both healthy elderly and Alzheimer's disease patients, the CP functions normally to transport AA and folates actively from blood into CSF, synthesize and secrete transthyretin into CSF, and maintain CSF acid-base balance and ion concentrations. These human CSF compositional data provide no support for the notion of CP failure in elderly humans and Alzheimer's disease patients.

Statins for secondary prevention of cardiovascular disease: the right dose.

Since the publication of the 4S trial in 1994, there has emerged a consensus that statins save lives and decrease myocardial infarctions and strokes in coronary artery disease (CAD) patients irrespective of baseline serum cholesterol. However, there is controversy over the correct dose and the utility of the treatment-to-goal (cholesterol, low-density lipoprotein) approach. To answer remaining questions about the optimal statin dose in CAD patients, we have performed simple and meta-analyses of 3 large long-term (approx. 5 years) dose-clinical response studies (TNT, IDEAL, and SEARCH) and compared the results with older data including long-term safety data. The results show that raising the dose of simvastatin or atorvastatin to 80 mg confers no mortality advantage, an increase in adverse reactions and only a slight decrease in myocardial infarctions and stroke versus a lower dose. These results suggest a cost-effective approach of a single safe dose (40 mg of inexpensive generic simvastatin or atorvastatin) for almost all CAD patients and makes treatment-to-goal and cholesterol monitoring (except to check for medication compliance) unnecessary; moreover, it is likely to improve the weakness in statin use - medication compliance.

Choroid plexus failure in the Kearns-Sayre syndrome.

The Kearns-Sayre syndrome is a mitochondrial disorder (generally due to mitochondrial DNA deletions) that causes ophthalmoplegia, retinopathy, ataxia and brain abnormalities such as leukoencephalopathy. In this syndrome, the choroid plexus epithelial cells, unlike brain cells, are greatly enlarged and granular, consistent with their inability to adequately transport folate from blood into cerebrospinal fluid (CSF), and homovanillic acid (a dopamine metabolite) from CSF into blood. This inability to transport folates from blood into CSF (and brain) adequately, causes cerebral folate deficiency that can be partially reversed by very high doses of reduced folates. The Kearns-Sayre syndrome is a disease that interferes with key choroid plexus functions and is a cause of generalized choroid plexus failure.

Vectorial ligand transport through mammalian choroid plexus.

In the last decade, there has been substantial progress in understanding vectorial ligand transport through rodent and human choroid plexus (CP), the locus of the blood-CSF interface. In this Review, we enumerate the experimental data required to establish vectorial transport through CP and describe transporters involved in vectorial transport across CP. We also note how these transporters differ from those at the blood-brain barrier. The ligand (substrate) examples presented are methyltetrahydrofolate, methotrexate, leukotriene C(4), nucleosides, thiamine monophosphate, prostaglandins, and digoxin. Our focus is on more definitive experiments, including animal and human transporter "knock-outs." Finally, we discuss the neurochemical implications of vectorial transport through CP and the clinical implications of transporter polymorphisms and knockouts. Examples include descriptions of how vectorial transport through the CP for several micronutrients (e.g., methyltetrahydrofolate) nourishes the brain and how knowledge of CP vectorial transport can lead to important treatments.

Nature and consequences of mammalian brain and CSF efflux transporters: four decades of progress.

In the last 40 years, especially with the application of new neurochemical and molecular biological techniques, there has been explosive progress in understanding how certain ligands and drugs are transported across the blood-brain barrier and choroid plexus out of brain and CSF. In the CNS, there are several separate efflux transporters with very broad specificity that are responsible for much of the efflux transport. This review focuses on three such transporters: organic acid transporter-3, peptide transporter-2 and P-glycoprotein for which there is substantial new information including 'knockout' models in mice and, in one case, dogs. Moreover, the structural biology and transport mechanism of P-glycoprotein at 3.8 angstroms is described. The overall objective is to show how this new knowledge provides a more thorough understanding (e.g., of molecular mechanisms) of efflux transport and in several cases leads to clinically relevant information that allows better treatment of certain CNS disorders (e.g., meningitis and brain cancer).

Nutrient transport systems in brain: 40 years of progress.

In the last 40 years, especially with the application of new neurochemical and molecular biologic techniques, there has been an explosive progress in understanding how nutrients are transported across the blood-brain barrier and choroid plexus into brain and CSF, and how nutrient homeostasis in brain is achieved. In most cases, there are separate transporters, or in a few cases, systems that transport related substances (e.g., biotin, lipoic, and pantothenic acids). This review focuses on three crucial nutrients (glucose, ascorbic acid, and folates) for which there is substantial new information including 'knock down' and 'knockout' models in mice and/or humans. The overall objective is to show that this new knowledge leads not just to a more thorough understanding (e.g., of 'why' questions like: why do neurons require up to 10 mM ascorbic acid intracellulary?); but in some cases leads to clinically important predictions that allow treatment of heretofore devastating neurologic disorders.

Vitamin transport and homeostasis in mammalian brain: focus on Vitamins B and E.

With the application of genetic and molecular biology techniques, there has been substantial progress in understanding how vitamins are transferred across the mammalian blood-brain barrier and choroid plexus into brain and CSF and how vitamin homeostasis in brain is achieved. In most cases (with the exception of the sodium-dependent multivitamin transporter for biotin, pantothenic acid, and lipoic acid), the vitamins are transported by separate carriers through the blood-brain barrier or choroid plexus. Then the vitamins are accumulated by brain cells by separate, specialized systems. This review focuses on six vitamins (B(1), B(3), B(6), pantothenic acid, biotin, and E) and the newer genetic information including relevant 'knockdown' or 'knockout' models in mice and humans. The overall objective is to integrate this newer information with previous physiological and biochemical observations to achieve a better understanding of vitamin transport and homeostasis in brain. This is especially important in view of the newly described non-cofactor vitamin roles in brain (e.g. of B(1), B(3), B(6), and E) and the potential roles of vitamins in the therapy of brain disorders.

The origin of deoxynucleosides in brain: implications for the study of neurogenesis and stem cell therapy.

Detection of DNA synthesis in brain employing ((3)H)thymidine (((3)H)dT) or bromo deoxyuridine (BrdU) is widely used as a measure of the "birth" of cells in brain development, adult neurogenesis and neuronal stem cell replacement strategies. However, recent studies have raised serious questions about whether this methodology adequately measures the "birth" of cells in brain either quantitatively or in an interpretable way in comparative studies, or in stem cell investigations. To place these questions in perspective, we review deoxynucleoside synthesis and pharmacokinetics focusing on the barriers interfacing the blood-brain (cerebral capillaries) and blood-cerebrospinal fluid (choroid plexus), and the mechanisms, molecular biology and location of the deoxynucleoside transport systems in the central nervous system. Brain interstitial fluid and CSF nucleoside homeostasis depend upon the activity of concentrative nucleoside transporters (CNT) on the 'central side' of the barrier cells and equilibrative nucleoside transporters (ENT) on their 'plasma side.' With this information about nucleoside transporters, blood/CSF concentrations and metabolic pathways, we discuss the assumptions and weaknesses of using ((3)H)dT or BrdU methodologies alone for studying DNA synthesis in brain in the context of neurogenesis and potential stem cell therapy. We conclude that the use of ((3)H)dT and/or BrdU methodologies can be useful if their limitations are recognized and they are used in conjunction with independent methods.

Micronutrient and urate transport in choroid plexus and kidney: implications for drug therapy.

With application of molecular biology techniques, there has been rapid progress in understanding how many drugs and micronutrients (e.g., vitamins) are transferred across the choroid plexus (CP), the main transport locus of the blood-cerebrospinal fluid (CSF) barrier, and the renal tubular epithelial cells. In many cases, these molecules are transported by separate, specific carriers or receptors on the apical and/or basal side of the CP or renal epithelial cells. This commentary focuses on four micronutrient transport systems in CP (ascorbic acid, folate, inositol, and riboflavin), all of which have been recently cloned, expressed and for which knockout mice models were developed and transporter localization studies performed. Also reviewed is the recently cloned uric acid transport system in human kidney in which there exists a human "knockout" model. The implications of these transport systems for drug therapy of central nervous system and renal disorders are discussed, especially with regard to methods to circumvent the blood-brain and blood-CSF barriers to deliver drugs to the brain.

Pharmacology and statistics: recommendations to strengthen a productive partnership.

Critical to the discovery, development and rational use of drugs and vaccines are the foundational principles and proper application of statistics. However, in too many cases, there has been misuse of statistics and/or overemphasis on statistical significance (p < 0.05), as though this criterion possessed truth-guaranteeing properties. To clarify confusion about the proper use of statistics in pharmacology, we summarize briefly the foundational principles of probability; the role of statistics in assessment of causality; the three basic uses of statistical methods, especially those employed in hypothesis testing; and current statistical issues in pharmacological research. We then review and provide examples of the meaning of statistical significance, the consequences of lack of randomization in epidemiology/observation studies, the criteria for measurement instrument validation, the problems with subgroup analyses, the need for multiple comparison statistical methods, and how to handle dropouts and missing data. Finally, based on sound experimental and statistical principles, we make a series of recommendations to both experimentalists and journal editors to improve published pharmacological experiments. These include widespread use of blinding and randomization and/or random selection of subjects in both basic and clinical pharmacology, mandatory use of rigorous evidentiary criteria in epidemiology/observation studies claiming causal associations, proper interpretation of statistical versus clinical/pharmacological significance, appropriate interpretation of meta-analyses, meaningful validation of methods, and a more rational statistical approach to subgroup analyses and genetic association studies.

The heart of drug discovery and development: rational target selection.

Critical to the discovery and development of drugs and vaccines is the rational selection of biochemical, immunologic or molecular targets. To understand the rationale for target selection, we review strengths and weaknesses of the four main approaches: whole animal disease models; molecular targeting; epidemiology/observation studies, and genomics. After classifying diseases into those with a relatively stable pathophysiology (e.g., hypertension and gout) versus those with an unstable pathophysiology (e.g., AIDS and influenza) to aid in understanding target selection, we provide examples of successful and unsuccessful selection of drug and vaccine targets, focusing on the molecular and epidemiological/observational approaches. We discuss the reasons that molecular targeting has led to successful control of many diseases, whereas the epidemiological/observational approach has had a checkered history. We also assess the potential power of the genomic approach, specifically the curative versus controlling/preventive strategies. With combined genetic and molecular approaches and judicious use of whole animal models and properly performed epidemiology/observation studies to select the appropriate targets, the future for controlling, preventing and even curing many diseases is very bright indeed.

The power of pharmacological sciences: the example of proton pump inhibitors.

Critics have questioned the foundational principles of pharmacological sciences and modern drug therapy; they also claim that drug therapy is often too expensive or of uncertain value. Contemporaneously, alternative medicine has bloomed. Yet the US government began to pay for drug therapy under Medicare in 2006, an explicit recognition of the value of modern drug therapy. To clarify this confusion, we review the philosophical and scientific foundations of pharmacology, drug discovery and development, the attendant strategies and successful results. We also review and answer the major attacks on the philosophical and scientific foundations of modern pharmacology and drug therapy. Finally, we define the characteristics of an ideal drug. As an example of the principles and strategies of modern pharmacological sciences and their successful application, we focus on the discovery and development of proton pump inhibitors (PPIs) of stomach acid production. This class of drugs approaches the ideal and exemplifies successful application of modern pharmacological principles to drug discovery and development. Moreover, the use of PPIs as a pharmacological tool allowed the resolution of important scientific questions, e.g., the role of stomach acid in peptic diseases of the stomach, duodenum and esophagus.

Which studies of therapy merit credence? Vitamin E and estrogen therapy as cautionary examples.

A vast and continuously growing amount of material on drugs exists in the literature to read and evaluate. Frequently, the papers and their recommendations are conflicting and contradictory. Readers are faced with the dilemma of deciding what to believe. The need for evidence-based medicine as a foundation for optimal clinical research and patient care requires application of the best scientific methods. Various methods are discussed. Generally, the most powerful method to test a clinical hypothesis is the randomized, controlled clinical trial. By contrast, epidemiology/observation studies have certain inherent weaknesses that can lead to erroneous conclusions. The examples of estrogen therapy in postmenopausal women and of vitamin E therapy to reduce cardiovascular risk are discussed extensively to provide historical perspective and to demonstrate erroneous conclusions reached using epidemiology/observation studies. The sociology of journal publication is briefly described, and an attempt is made to assess who benefits and who is harmed when leading medical journals publish erroneous results. Types of bias and confounding issues leading to errors are discussed, and the need is emphasized for publication of rigorous studies after careful evaluation by editors to avoid repetition of past mistakes and to ensure publication of correct medical information.