Microdialysis in mice for drug delivery research

Intracerebral microdialysis was first performed in the mouse at the end of the 1980s. Most microdialysis studies on mice were confined to neuropharmacology and changes in neurotransmitter concentrations up to 1995, although pharmacological studies were done on other tissues like the skin, kidney and implanted tumors. The use of microdialysis in mice for pharmacokinetic and drug delivery studies owes much to the recent availability of genetically engineered mice, such as mice in which the genes encoding multiple drug resistance have been knocked out. The quantitative microdialysis of blood and various tissue fluids of the mouse is now feasible and the recent development of specific microdialysis devices for use in mice should facilitate its use in these small animals. This review covers the technical aspects of microdialysis in the mouse and includes references to many of the published studies on pharmacokinetics and drug delivery.     

Microdialysis in neurointensive care

Microdialysis is a technique for sampling the chemistry of the interstitial fluid of tissues and organs in animal and man. It is minimally invasive and simple to perform in a clinical setting. Although microdialysis samples essentially all small molecular substances present in the interstitial fluid the use of microdialysis in neurointensive care has focused on markers of ischemia and cell damage. The lactate/pyruvate ratio is a well-known marker of changes in the redox state of cells caused by ischemia Glycerol is an integral component of cell membranes. Loss of energy due to ischemia eventually leads to an influx of calcium and a decomposition of cell membranes, which liberates glycerol into the interstitial fluid. Thus the lactate/pyruvate ratio and glycerol have become the most important markers of ischemia and cell membrane damage. While the primary insult at the site of the accident is beyond our control, secondary insults during intensive care should be avoided by all means. Therefore, the single most important finding from microdialysis studies is the dramatic difference in the vulnerability of the penumbra surrounding a lesion as compared to normal brain tissue allowing early detection of secondary insults after traumatic brain injury as well as the onset of vasospasm after subarachnoid hemorrhage.     

Microdialysis in drug discovery

Microdialysis has been developed during the last 25 years by several authors primarily to study brain function and changes in levels of endogenous compounds such as neurotransmitters or metabolites. The development of microdialysis for the purpose of measuring drugs was initiated during the late eighties. This technique provides a means of continuous plasma sampling without repeated blood sampling and the applicability to the study of drug metabolism and pharmacokinetics in experimental animals and human. Also, the microdialysis technique allows the study of plasma protein binding and the saturation of protein binding. The implantation of the microdialysis probe in other tissues and organs, like central nervous system, adipose tissue and heart, allows the study of drug distribution. On the other hand, the measurement of endogenous substances using the microdialysis technique permits the study of the effect of drugs on neurotransmission and metabolism. Moreover, as this technique allows the simultaneous determination of different physiological parameters such as blood pressure, locomotor and convulsive activity, it is a suitable tool for pharmacokinetic-pharmacodynamic studies of drugs and pharmacokinetic-pharmacodynamic (PK-PD) modeling. Lastly, the reverse microdialysis is a powerful technique for the study of local actions of drugs in different tissues such as specific brain nuclei, myocardium, liver or skeletal muscle. So, this article reviewed the vast applications of the microdialysis technique for the study of pharmacokinetic and pharmacodynamic properties of drugs.     

Microdialysis in peripheral tissues

The objective of this review is to survey the recent literature regarding the applications of microdialysis in pharmacokinetic studies and facilitating many other studies in peripheral tissues such as muscle, subcutaneous adipose tissue, heart, lung, etc. It has been reported extensively that microdialysis is a useful technique for monitoring free concentrations of compounds in extracellular fluid (ECF), and it is gaining popularity in pharmacokinetic and pharmacodynamic studies, both in experimental animals and humans. The first part of this review discusses the use of microdialysis technique for ECF sampling in peripheral tissues in animal studies. The second part of the review describes the use of microdialysis for ECF sampling in peripheral tissues in human studies. Microdialysis has been applied extensively to measure both endogenous and exogenous compounds in ECF. Of particular benefit is the fact that microdialysis measures the unbound concentrations in the peripheral tissue fluid which have been shown to be responsible for the pharmacological effects. With the increasing number of applications of microdialysis, it is obvious that this method will have an important place in studying drug pharmacokinetics and pharmacodynamics.     

Dermal Microdialysis Sampling in Vivo

Microdialysis sampling of the dermis in vivo was accomplished using a linear microdialysis probe. In contrast to previous studies using a commercial cannula-style microdialysis probe, the linear probe had no effect on the flux of drug through the skin in vitro. The extent of tissue damage in vivo due to probe implantation was evaluated by histological examination and microdialysis delivery studies. Tissue damage due to implantation of the linear probe was minimal with no bleeding or edema observed. Infiltration of lymphocytes into the tissue was observed beginning 6 hours after probe implantation with scar tissue beginning to form after approximately 32 hours. The infiltration of lymphocytes had no effect on the behavior of implanted microdialysis probes. Delivery of 5-fluorouracil was between 20 and 25% for six different probes implanted in six different animals demonstrating good probe-to-probe and implantation-to-implantation reproducibility. Constant delivery was maintained for at least 24 hours in all cases indicating that experiments of at least 24 hour duration are feasible. The dermal concentration of topically applied 5-FU cream, Efudex^®, was continuously monitored by an implanted microdialysis probe demonstrating the feasibility of this technique as for monitoring skin drug levels in vivo. The dermal concentration of 5-FU following topical application was approximately 40-fold higher for in vitro excised skin than for in vivo intact skin.     

Human experimental pain models in drug development: translational pain research

Human experimental pain models require standardized stimulation and quantitative assessment of the evoked responses. This approach can be applied to healthy volunteers and pain patients before and after pharmacological interventions. Standardized stimuli of different modalities (ie, mechanical, chemical, thermal or electrical) can be applied to the skin, muscles and viscera for a differentiated and comprehensive assessment of various pain pathways and mechanisms. Using a multi-modal, multi-tissue approach, new and existing analgesic drugs can be profiled by their modulation of specific biomarkers. It has been shown that biomarkers, for example, those related to the central integration of repetitive nociceptive stimuli, can predict efficacy of a given drug in neuropathic pain conditions. Human experimental pain models can bridge animal and clinical pain research, and act as translational research providing new possibilities for designing successful clinical trials. Proof-of-concept studies provide cheap, fast and reliable information on dose-efficacy relationships and how pain sensed in the skin, muscles and viscera are inhibited.     

Microdialysis of large molecules

Microdialysis has been used in many tissues, including skin, brain, adipose tissue, muscle, kidney, and gastrointestinal tract, to recover low-molecular mass endogenous mediators, metabolites, and xenobiotics from the interstitial space. Recently, molecules of larger molecular mass, such as plasma proteins, cytokines, growth factors, and neuropeptides, have also been recovered successfully using larger-pore membranes. Microdialysis recovery of large molecules offers the opportunity to identify patterns of protein expression in a variety of tissue spaces and to evaluate clinically useful biomarkers of disease. From this may develop a better understanding of the disease process and its diagnosis and more targeted approaches to therapy.     

Microdialysis in clinical drug delivery studies

The introduction of in vivo microdialysis (MD) to clinical pharmacological studies has opened the opportunity to obtain previously inaccessible information about the drug distribution process to the clinically relevant target site. The aim of this review is to provide a comprehensive overview of the current literature about MD in drug delivery studies from a clinical perspective. In particular the application of MD in clinical--antimicrobial, oncological and transdermal--and neurological research will be described and the scope of MD in pharmacokinetic-pharmacodynamic (PK-PD) studies will be discussed. It is concluded that MD has a great potential for both academic and industrial research, and may become the method of choice for drug distribution studies in humans.     

微透析技术在药动-药效学结合研究中的应用

微透析技术能直接、有效地对作用部位细胞外液中的内源性及外源性化合物进行持续检测,是药动-药效学结合研究的重要工具,具有不可替代的作用及广阔的应用前景。本文概述了微透析技术的基本原理及特点,并重点介绍了其在药动-药效学结合研究中的应用。     

Application of Microdialysis in Pharmacokinetic Studies

The objective of this review is to survey the recent literature regarding the various applications of microdialysis in pharmacokinetics. Microdialysis is a relatively new technique for sampling tissue extracellular fluid that is gaining popularity in pharmacokinetic and pharmacodynamic studies, both in experimental animals and humans. The first part of this review discusses various aspects of the technique with regard to its use in pharmacokinetic studies, such as: quantitation of the microdialysis probe relative recovery, interfacing the sampling technique with analytical instrumentation, and consideration of repeated procedures using the microdialysis probe. The remainder of the review is devoted to a survey of the recent literature concerning pharmacokinetic studies that apply the microdialysis sampling technique. While the majority of the pharmacokinetic studies that have utilized microdialysis have been done in the central nervous system, a growing number of applications are being found in a variety of peripheral tissue types, e.g. skin, muscle, adipose, eye, lung, liver, and blood, and these are considered as well. Given the rising interest in this technique, and the ongoing attempts to adapt it to pharmacokinetic studies, it is clear that microdialysis sampling will have an important place in studying drug disposition and metabolism.     

Microdialysis for pharmacokinetic-pharmacodynamic studies

Microdialysis (MD) has become one of the major tools to sample endogenous and exogenous substances in extracellular spaces. It is more suitable for pharmacokinetic-pharmacodynamic (PK-PD) studies than other techniques. This review aims to give an overview of MD for PK-PD (MD/PK-PD) studies, including PK-PD studies, three aspects (principles, recovery, advantages) of MD/PK-PD, and application examples of MD/PK-PD organized by types of drugs and information collected. It can be concluded that MD offers an unique opportunity, to study simultaneously pharmacokinetic (PK) behavior of a drug and its effect on the extracellular levels of endogenous compounds, which may facilitate proof-of-concept demonstrations for target modulation, enhance the rational selection of an optimal drug dose and schedule. In addition, MD/PK-PD can also minimize uncertainties associated with predicting drug safety and efficacy, reduce the high levels of drug attrition during development, accelerate drug approval, and decrease the overall costs of drug development.     

微透析技术及在药学中的应用进展

本文介绍了微透析技术的原理和组成,对微透析技术用于体内药物分析时的回收率测定方法的优缺点以及应用进展进行了综述,展望了微透析技术用于药学分析领域的应用前景。     

Probe Calibration in Transient Microdialysis In Vivo

Purpose. We examine the theoretical basis for calibrating microdialysis probes in vivo for pharmacokinetic experiments in which the extracellular analyte concentrations vary in time. Methods. A software package, MICRODIAL, was used to simulate microdialysis for illustrative transient situations with linear concentration dependence. Results. For a constant distant extracellular analyte concentration, the calibration factor (extraction fraction, E _d) exhibits a mass transfer transient associated with the development of spatial concentration profiles within the tissue and the probe. Processes clearing the analyte from the extracellular fluid (ECF) strongly influence the rapidity of approach to steady-state and affect the magnitude of the steady-state calibration factor, E _d ^ss . For situations in which the distant ECF concentration varies in time as a result of exchange with the plasma compartment, different time profiles of the distant ECF and plasma concentrations yield different transient E _d . For the linear, transient cases examined, the area-under-the-curve (AUC _0-) time integral of the distant ECF concentration was found to be proportional to the outflow dialysate concentration-time integral with E _d ^ss being the proportionality constant. Conclusions. The options for calibrating microdialysis probes in solid tissues appear limited under non-steady state conditions; however, AUC integrals for linear systems may be determined by continuous microdialysis sampling and steady-state probe calibration approaches.     

Microdialysis of triamcinolone acetonide in rat muscle

The objective of this study was to compare plasma and muscle concentrations of triamcinolone acetonide (TA) in the rat by microdialysis. Microdialysis experiments were carried out at steady state in rats after an initial I.V. bolus 50 mg/kg of the phosphate ester of TA (TAP) followed by 23 mg/kg/h infusion. In vivo recovery was calculated by retrodialysis. The concentration determined at steady state in microdialysate, corrected for recovery, was 2.73 +/- 0.42 microg/mL compared to 21.9 +/- 2.3 microg/mL in plasma. The pharmacokinetics of TA in plasma was described by an open two-compartment model with a terminal half-life of 2.7 h. The clearance of TA in rats determined by compartmental analysis was 0.94 L/h/kg. The measured microdialysate levels of TA in muscle, corrected for recovery, were comparable to the predicted free drug levels in the peripheral compartment. Protein binding in rat plasma, measured by ultrafiltration, was 90.1%. The microdialysis in vivo recovery in muscle was similar to the in vitro recovery under stirred conditions. The results show the applicability of microdialysis to measure free tissue concentrations of TA in rats.     

微透析技术在体内药物分析中的应用

论述微透析技术在体内药物分析中的应用研究，着重介绍微透析系统的基本结构与操作步骤、微透析技术用于定量分析及影响回收率的因素以及微透析技术与其他技术的联用。     

Microdialysis as a tool in local pharmacodynamics

In many cases the clinical outcome of therapy needs to be determined by the drug concentration in the tissue compartment in which the pharmacological effect occurs rather than in the plasma. Microdialysis is an in vivo technique that allows direct measurement of unbound tissue concentrations and permits monitoring of the biochemical and physiological effects of drugs throughout the body. Microdialysis was first used in pharmacodynamic research to study neurotransmission, and this remains its most common application in the field. In this review, we give an overview of the principles, techniques, and applications of microdialysis in pharmacodynamic studies of local physiological events, including measurement of endogenous substances such as acetylcholine, catecholamines, serotonin, amino acids, peptides, glucose, lactate, glycerol, and hormones. Microdialysis coupled with systemic drug administration also permits the more intensive examination of the pharmacotherapeutic effect of drugs on extracellular levels of endogenous substances in peripheral compartments and blood. Selected examples of the physiological effects and mechanisms of action of drugs are also discussed, as are the advantages and limitations of this method. It is concluded that microdialysis is a reliable technique for the measurement of local events, which makes it an attractive tool for local pharmacodynamic research.     

The Use of Microdialysis in Pharmacokinetics and Pharmacodynamics

Microdialysis is a new in vivo sampling technology applied to the study of pharmacokinetics and drug metabolism in the blood and soft tissues of living systems. A small-diameter probe containing a dialysis membrane is implanted into tissue and perfused with a suitable fluid. Low-molecular-weight substances passively diffuse through the semipermeable membrane along a concentration gradient, resulting in the collection of purified dialysate samples. The advantage of this approach over blood sampling and dissection of tissues is the ability to sample blood and extracellular fluid with minimal tissue damage or alteration of fluid balance. Sampling several tissues simultaneously and continuously in animal models allows data to be obtained that more directly reflect interactions of drugs at their sites of activity and detoxification. Techniques such as this will have a tremendous impact on preclinical and clinical pharmacologic research.