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Pain and the blood–brain barrier: obstacles to drug delivery
Advanced Drug Delivery Reviews 55 (2003) 987–1006 www.elsevier.com / locate / addr
Pain and the blood–brain barrier: obstacles to drug delivery Anne M. Wolka, Jason D. Huber, Thomas P. Davis* Department of Pharmacology, University of Arizona College of Medicine, P.O. Box 245050, 1501 N. Campbell Avenue, Tucson, AZ 85724, USA Received 18 April 2003; accepted 8 May 2003
Abstract Delivery of drugs across the blood–brain barrier has been shown to be altered during pathological states involving pain. Pain is a complex phenomenon involving immune and centrally mediated responses, as well as activation of the hypothalamic–pituitary–adrenal axis. Mediators released in response to pain have been shown to affect the structure and function of the blood–brain barrier in vitro and in vivo. These alterations in blood–brain barrier permeability and cytoarchitecture have implications in terms of drug delivery to the central nervous system, since pain and inflammation have the capacity to alter drug uptake and efflux across the blood–brain barrier. An understanding of how blood–brain barrier and central nervous system drug delivery mechanisms are altered during pathological conditions involving pain and / or inflammation is important in designing effective therapeutic regimens to treat disease. 2003 Elsevier B.V. All rights reserved. Keywords: Inflammation; CNS response; HPA axis; Inflammatory mediator; Permeability; Transport
Contents 1. Introduction ............................................................................................................................................................................ 2. Function and structure of the blood–brain barrier in health ......................................................................................................... 3. Drug delivery across the blood–brain barrier in health ............................................................................................................... 3.1. Diffusion ......................................................................................................................................................................... 3.2. Carrier-mediated transport ................................................................................................................................................ 3.3. Endocytosis ..................................................................................................................................................................... 3.4. Drug efflux ...................................................................................................................................................................... 4. Pain mechanisms..................................................................................................................................................................... 4.1. Immune and central nervous system responses ................................................................................................................... 4.1.1. Cytokines and chemokines...................................................................................................................................... 4.1.2. Cellular adhesion molecules.................................................................................................................................... 4.1.3. Matrix metalloproteinases ....................................................................................................................................... 4.1.4. Kinins ................................................................................................................................................................... 4.1.5. Prostaglandins........................................................................................................................................................ 4.1.6. Excitatory peptides and amino acids ........................................................................................................................ *Corresponding author. Tel.: 1 1-520-626-7643; fax: 1 1-520-626-4053. E-mail address: [email protected] (T.P. Davis). 0169-409X / 03 / $ – see front matter 2003 Elsevier B.V. All rights reserved. doi:10.1016 / S0169-409X(03)00100-5
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4.2. Activation of the hypothalamic–pituitary–adrenal axis ....................................................................................................... 5. Alterations of the blood–brain barrier by pain mediators ............................................................................................................ 5.1. Effects of proinflammatory mediators on the blood–brain barrier......................................................................................... 5.2. Effects of excitatory peptides and amino acids on the blood–brain barrier ............................................................................ 5.3. Effects of hypothalamic–pituitary–adrenal axis activation on the blood–brain barrier ........................................................... 6. Implications of pain responses in central nervous system drug delivery ....................................................................................... 6.1. Influence of increased blood–brain barrier paracellular permeability on drug delivery to the brain ......................................... 6.2. Influence of altered blood–brain barrier endocytosis on drug delivery to the brain ................................................................ 6.3. Potential influence of altered blood–brain barrier efflux on drug delivery to the brain ........................................................... 6.4. Potential influence of pain-induced glutamate release on the delivery of glutamate-conjugated drugs to the brain .................... 6.5. Potential influence of pain-induced bradykinin release on the action of a bradykinin analogue at the blood–brain barrier......... 7. Conclusions ............................................................................................................................................................................ References ..................................................................................................................................................................................
1. Introduction The blood–brain barrier (BBB) serves as a physical and metabolic barrier between the central nervous system (CNS) and the periphery. The BBB is a dynamic structure capable of rapid modulation to maintain homeostasis within the CNS. Decreased BBB function has been described in CNS conditions with pain and / or inflammatory components, including multiple sclerosis [1], Alzheimer’s disease [2], human immunodeficiency virus (HIV) dementia [3], and meningitis [4]. Recent evidence has indicated that peripheral inflammation also alters the structure and increases the permeability of the BBB [5,6]. A potential consequence of increased BBB permeability is altered delivery of therapeutic pharmaceuticals to the CNS. An understanding of how the BBB and its transport / delivery mechanisms are altered during pathological conditions involving pain and / or inflammation is important both in assessing disease etiology and in creating effective therapeutic regimens to treat disease.
2. Function and structure of the blood–brain barrier in health The BBB, located at the level of brain capillary endothelial cells [7], serves to maintain brain homeostasis by regulating the composition of brain extracellular fluid independent of fluctuations within the peripheral circulation. In this manner, the BBB maintains optimal conditions for neuronal function. The structure and function of the BBB have been reviewed [8,9]. Tight junctions (TJs) and the lack of
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fenestrations at the BBB allow maintenance of CNS homeostasis. TJs in the BBB are composed of transmembrane and cytoplasmic proteins linked to an actin cytoskeleton. TJs impart significant transendothelial electrical resistance (TEER, 1500–2000 V cm 2 ) to brain endothelial cells and severely restrict paracellular diffusion of solutes into the brain [10]. Three integral proteins make up TJs: claudin, occludin, and junction adhesion molecule (JAM). The primary seal of the TJ is formed when claudin dimers bind homotypically to claudins on adjacent endothelial cells [11]. Occludin is a regulatory protein present at TJs, and the presence of occludin is associated with increased TEER and decreased paracellular permeability [12]. JAMs, members of the immunoglobin superfamily, can function in association with platelet endothelial cellular adhesion molecule 1 to regulate leukocyte migration [13]. Cytoplasmic accessory proteins such as zonula occludens proteins (ZO-1, -2, and -3) also play a role in maintaining the function of the BBB. ZO proteins, which belong to the membrane-associated guanylate kinase-like protein family, serve as recognition proteins for TJ placement and as a support structure for signal transduction proteins [14]. Actin, the primary cytoskeletal protein, has known binding sites on all ZO proteins, as well as on claudin and occludin [15]. A dense band of actin and myosin filaments circumscribe endothelial cells, with actin filaments extending into TJs [16]. ZO-1 binds to actin filaments and the C terminus of occludin. Therefore, the structural and dynamic properties of perijunctional actin are coupled to the paracellular barrier. The structural organization of actin has been shown to influence TJ integrity. Actin-disrupting substances have been shown to alter TJ structure and
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function [17,18], while ATP depletion has been shown to alter TJ structure, decrease TEER, and result in increased association of ZO-1 and -2 with actin [19]. TJs are located at cholesterol-rich regions of the plasma membrane associated with caveolin 1 [20], a molecule which regulates several signal transduction pathways and downstream targets [21]. Several cytoplasmic signaling molecules, including protein kinase C (PKC) and Ca 21 , are located at TJ complexes and are involved in signaling cascades that control TJ assembly and disassembly [22]. PKC serves to regulate TJ formation and function [23]. ZO proteins are thought to serve as scaffolding for PKC signal transduction pathways; in turn, PKC has been shown to play a role in the migration of intracellular ZO-1 to the plasma membrane [24]. PKCj and PKCl and their specific binding protein have been shown to be located at TJs. These proteins have been implicated in the establishment of cell polarity, which is fundamental to BBB differentiation and function [25]. TJ activity is regulated by both intracellular and extracellular Ca 21 . Removal of extracellular Ca 21 has been associated with a decrease in TEER across the membrane and an increase in permeability [18] via heterotrimeric G protein and PKC signaling mechanisms. Homotypic interaction of E-cadherin, which is thought to be the initial event of junctional complex formation, also depends on extracellular Ca 21 [26]. Intracellular Ca 21 regulates cell–cell contact [27], TEER [27], migration of intracellular ZO-1 to the plasma membrane [28], and assembly of TJs [29].
3.1. Diffusion
3. Drug delivery across the blood–brain barrier in health
3.3. Endocytosis
The barrier properties of the BBB result in limited brain penetration of a number of substances. Selective transport mechanisms present at the BBB include diffusion, carrier-mediated transport, and receptor-mediated, adsorptive, and fluid-phase endocytosis [30,31]. BBB efflux transporters that actively transport compounds from the brain to the blood serve to maintain brain homeostasis but also limit the uptake of therapeutic compounds into the CNS [32] (Fig. 1).
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Diffusion across the BBB is typically transcellular since TJs restrict the paracellular diffusion of solutes [10]. Therefore, the lipophilicity and hydrogen bonding potential of a solute determine its ability to diffuse into the brain; in general, greater lipophilicity and lower hydrogen bonding potential of a compound are associated with greater transcellular diffusivity [33–36].
3.2. Carrier-mediated transport Carrier-mediated transport at the BBB involves a substrate–transporter interaction on the brain endothelial surface. Carrier-mediated transport is a saturable process and is typically classified according to the energy requirements for transport and / or cotransport of another substance (symport or antiport) [31]. Transport of essential compounds, including amino acids, monocarboxylic acids, sugars, and nucleosides, in and / or out of the brain has been shown to occur via specific carrier-mediated transporters. Transporters have been identified at the BBB for sugars such as glucose and mannose; neutral amino acids such as phenylalanine, leucine, and tyrosine; acidic amino acids such as glutamate and aspartate; basic amino acids such as arginine and lysine; b-amino acids such as b-alanine; monocarboxylic acids such as lactate, ketone bodies, and other short-chain fatty acids; amines such as mepyramine; the purine bases adenine and guanine; and peptides such as vasopressin [37,38].
The BBB has reduced endocytosis compared to other tissues [39]; nevertheless, vesicular transport (via receptor-mediated, adsorptive, or fluid-phase endocytosis) plays an important role in the delivery of several compounds to the brain. The iron-bound iron transport protein transferrin has been shown to be endocytosed into the cerebral microvasculature via a receptor-mediated mechanism [40,41]. Similarly, insulin and low-density lipoproteins (LDLs) have been shown to undergo receptor-mediated endocytosis at the BBB [42,43]. Adsorptive endocytosis
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Fig. 1. Transport mechanisms across the blood–brain barrier (BBB). (A) Transcellular diffusion; (B) paracellular diffusion; (C) carrier-mediated transport; (D) fluid-phase endocytosis; (E) adsorptive endocytosis; (F) receptor-mediated endocytosis; and (G) drug efflux.
has been identified as the mechanism of uptake of certain cationized proteins [44] and peptides [45] into the brain. Fluid-phase endocytosis has been demonstrated in vitro in both bovine [46] and human [47] BBB cell culture systems.
3.4. Drug efflux The impact of efflux transporters on drug design and delivery to the CNS has been reviewed [32].
Drugs [48,49], nutrients, metabolites, peptides, hormones, and neurotransmitters [50] can be actively transported from the brain to the blood to maintain brain homeostasis. Active transport out of the brain occurs via efflux transporters localized at the BBB, including P-glycoprotein (P-gp), members of the multidrug resistance-associated protein (MRP) family, monocarboxylic acid transporters, and organic ion transporters [32]. Efflux at the BBB has been shown to limit the penetration of therapeutic compounds such as anti-HIV drugs [51,52], analgesics [53],
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antibacterials [54,55], antiepileptics [56], and anticancer agents [57,58] into the CNS.
adrenal (HPA) axis. These pain mechanisms and their influences on drug delivery across the BBB will be discussed in the following sections (Fig. 2).
4. Pain mechanisms
4.1. Immune and central nervous system responses
Pain is a complex phenomenon involving responses from the immune system and the CNS, as well as activation of the hypothalamic–pituitary–
The immune response is characterized by the rapid production and release of inflammatory mediators such as cytokines, chemokines, cellular adhesion
Fig. 2. Physiological responses to pain and their potential influences on drug delivery at the BBB.
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molecules, matrix metalloproteinases (MMPs), kinins, and prostaglandins (PGs) at the site of disease or injury. Inflammation is typified by increased vascular permeability, localized edema formation, erythema, and increased leukocyte migration. The CNS utilizes neuronal pathways to signal the immune system. The neuronal response to noxious stimulation involves both excitatory and inhibitory neurotransmission within the sensory areas of the spinal cord, and the balance of these CNS responses determines the level of transmission of nociceptive signals to the brain [59]. Furthermore, proinflammatory mediators produced and released in the CNS following local injury or inflammation play a role in the central-mediated pain response.
4.1.1. Cytokines and chemokines Cytokines can either be released in the periphery or the CNS during disease or in response to trauma. Numerous cytokines are involved in the immune response, particularly the interleukins IL-1a and -1b, -2, -4, -6, -8, -10, and -13, tumor necrosis factor-a (TNF-a), and the type I interferons IFN-a and -b [60]. Both excitatory and inhibitory cytokines play a role in inflammation. TNF-a, IL-2, IL-6, IL-8, and IL-1b have been shown to be hyperalgesic [61–65]. Cytokines have also been shown to interact with kinins to potentiate their effects [66]. Changes in expression of endothelial surface molecules (adhesion molecules such as selectins and integrins) and adhesion of polymorphoneutrophils (PMNs), monocytes, and lymphocytes to cell walls have been shown to be induced by proinflammatory cytokines such as IL-1b. Inhibitory cytokines, including IL-4, IL-10, and IL-13, modulate the immune response by exerting anti-inflammatory actions [66] and inhibiting the synthesis of proinflammatory cytokines such as IL-1b and TNF-a [67]. Peripheral cytokines such as IL-1, IL-6, and TNFa have been proposed to activate central responses to peripheral insult. Active transport systems for IL-1 and TNF-a exist at the BBB [68,69]; however, little bioavailable IL-1 or TNF-a circulates from the site of injury or inflammation, except in severe trauma [70]. It has been proposed that IL-1 and TNF-a instead induce IL-6, a cytokine whose circulating levels increase by several orders of magnitude during the development of fever [71]. Peripheral cytokines
may also influence the CNS via neural pathways [72]. While constitutive expression of cytokines in the CNS is low, ‘‘activated’’ microglia, neurons, astroglia, perivascular cells and endothelial cells release cytokines such as IL-1b, IL-6, and TNF-a in response to CNS tissue damage or infection associated with pathological states [70]. Levels of cytokine expression depend on brain region, with the greatest levels in the hypothalamus and hippocampus and lower levels in the cortex and brain stem [73–76]. Chemotactic cytokines, or chemokines, play inflammatory, homeostatic, angiostatic, and / or angiogenic roles in disease [77]. Inflammatory chemokines interact with seven-transmembrane G protein-coupled receptors expressed on leukocytes in order to recruit these molecules to the site of inflammation [78,79]. Chemokines have also been shown to regulate cytokine production [80,81]. Chemokines are expressed in the CNS as well as the periphery. Chemokines such as monocyte chemotactic proteins (MCPs), macrophage inflammatory protein 1-a and -b, regulated on activation normal T-cell expressed and secreted, and interferon-inducible protein 10 are produced in astrocytes, microglia, and perivascular leukocytes during inflammatory diseases such as multiple sclerosis and following brain injury [82].
4.1.2. Cellular adhesion molecules Increased leukocyte migration is a hallmark of the immune response. Receptors on the surface of leukocytes are classified either as selectins or integrins. While selectins take part in initial interactions of leukocytes with cell surfaces, integrins participate in adhesion and transmigration processes [83,84]. Endothelial cell ‘‘activation’’ following an immune challenge results in upregulation of the expression of genes that encode for leukocyte adhesion receptors [85,86] such as intercellular adhesion molecule 1 (ICAM-1) and vascular cell adhesion molecule 1 (VCAM-1) [85–87]. Interactions between endothelial cell receptors and selectins and integrins result in leukocyte adhesion to and migration across endothelial cells of the BBB. Leukocyte trafficking involves rolling, tethering, firm adhesion, diapedesis, and chemotaxis of leukocytes [88]. Following ‘‘activation’’ of the endo-
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thelium by inflammatory mediators, leukocytes reversibly adhere to the endothelium. Under conditions of flow, this initial adhesion results in rolling of leukocytes. The interaction between selectins and cell membrane glycoproteins tether leukocytes to the endothelium. Integrin receptors on tethered leukocytes are then ‘‘activated’’ by inflammatory mediators such as endothelial membrane-expressed platelet-activating factor or chemokines. Firm adhesion of leukocytes to the endothelium becomes possible since ‘‘activated’’ integrin receptors possess greater affinity for the endothelium. Adherent migrating leukocytes move over the endothelium and diapedese between endothelial cells to enter extravascular tissue. During diapedesis, leukocytes have been shown to signal endothelial cells, disrupting intercellular junction integrity [89]. Leukocytes then transmigrate to the site of immune reaction. The b1 class of integrins, which are the primary integrins expressed on endothelial cells in the CNS [90], play a critical role in regulating BBB function. A number of other integrins are expressed in the CNS, including av integrins, which are expressed on neurons, glial cells, meningeal cells, and endothelial cells [91,92], and b2 integrins, which are expressed on microglia and infiltrating leukocytes [91,93]. Integrins appear to play a role during CNS inflammation, since their expression has been shown to be altered during inflammatory diseases such as multiple sclerosis [94]. Furthermore, TNF-a, IL1-b, and IFN-g, cytokines that are elevated in inflammatory CNS disease, have been shown to induce expression of the adhesion molecules ICAM-1 and VCAM-1 on brain endothelial cells and astrocytes [95].
4.1.3. Matrix metalloproteinases Vascular endopeptidases known as MMPs play a role in vascular remodeling following inflammation, injury, and / or oxidative stress. MMP activity in the vasculature is rigorously controlled by tissue inhibitors of metalloproteinases (TIMPs). Stresses upregulate MMP expression and activity, disrupting the balance of MMPs and TIMPs. This imbalance then leads to extracellular matrix reorganization and degradation [96]. MMP release from inflammatory cells occurs following stress. MMPs are normally present in the brain in latent forms. ‘‘Activated’’ MMPs, which are
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secreted by microglia, astrocytes, and endothelial cells in the CNS in response to trauma or disease, contribute to tissue damage [97] and opening of the BBB [98,99]. MMP-2 (gelatinase A) and MMP-9 (gelatinase B) have been shown to degrade the major components of the basal lamina of cerebral blood vessels [100]. Furthermore, TNF-a, a cytokine which induces BBB opening, has been linked to MMP-9 (gelatinase B) expression [97]. In addition, cytokines secreted from ‘‘activated’’ macrophages upregulate MMP gene expression in the vasculature [101,102].
4.1.4. Kinins Kinins act on seven-transmembrane G proteincoupled B 1 or B 2 receptors to activate and sensitize nociceptors [103–105]. Bradykinin (BK) is well characterized [106–109] and has been shown to interact with B 2 receptors. The action of BK involves activation of phospholipase C followed by stimulation of PKC and an increase in Na 1 conductance. The result of these modulations is depolarization of sensory afferent neurons and hyperalgesia [110,111]. Kinins not only activate and sensitize nociceptors, but also exert proinflammatory effects, resulting in vasodilation, edema, and the release of other inflammatory molecules [66]. Mechanisms for the synthesis of kinins are present in the CNS [112]. Furthermore, kinins and their receptors have been detected in the brain in vivo and in vitro [113–115]. B 2 receptors have been identified on CNS microglia, the primary immune effector cell population in the CNS, as well as on endothelial cells [116,117]. The mechanism of BK in the cerebral vasculature is thought to be similar to its action in the periphery. BK stimulates neural and neuroglial cells, resulting in production and release of PG precursors, cytokines, free radicals, and nitric oxide. These actions of BK result in damage to neural cells and disturbance of BBB function [112]. Furthermore, activation of CNS astrocytes by kinins has been linked to glutamate release and increases in neuronal Ca 21 [118]. 4.1.5. Prostaglandins PGs play a critical role in the modulation of immune function [119,120]. Inflammatory insult leads to the release of arachidonic acid (AA) from membrane phospholipids via phospholipase A 2 ac-
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tion. The cyclooxygenase enzymes COX-1 and COX-2 convert AA to prostaglandin H 2 , which is then converted into different PGs, including PGI 2 , PGF 2a , PGD 2 and PGE 2 . Inflammation involves primarily PGE 2 and PGI 2 [121]. PGE 2 is one of the best-characterized PGs; it is secreted by fibroblasts, macrophages, and malignant cells following an immune challenge, resulting in vasodilation and subsequent erythema and edema formation [122]. Furthermore, PGE 2 controls the production of cytokines by ‘‘activated’’ macrophages [123,124] and induces the synthesis of MMPs [122], leading to reorganization and degradation of the extracellular matrix. Stimulation of CNS cells by inflammatory cytokines such as IL-1b and TNF-a results in production and release of PGE 2 by almost all CNS cell types, including brain endothelial cells [125–130]. The COX-2 enzyme, which plays a role in PG synthesis, has been shown to be upregulated in the excitatory neurons of the cerebral cortex and hippocampus following insult related to overstimulation of Nmethyl-D-aspartate (NMDA) receptors [131–133]. Furthermore, TNF-a has been shown to induce COX-2 expression in brain microvessel endothelial cells [128]. PGE 2 has been shown to induce the IL-6-type cytokine oncostatin-M in microglia [134], resulting in astrocytic production of IL-6 [135] and upregulation of ICAM-1, IL-6, and the chemokine MCP1 in human cerebral endothelial cells [136].
4.1.6. Excitatory peptides and amino acids Excitatory peptides in the CNS also play a role in nociception. The peptides present in the greatest abundance within the dorsal horn are substance P (SP) and calcitonin gene-regulated peptide (CGRP). SP, a member of the tachykinin family, acts on neurokinin NK 1 receptors causing long-lasting depolarization via inactivation of K 1 and / or activation of Na 1 or Ca 21 currents [137]. Synaptic depolarization and the increase in Ca 21 in turn induce the protooncogene c-fos, resulting in production of c-fos protein, a neural marker of pain [138]. Furthermore, SP stimulates the release of the proinflammatory mediator histamine from mast cells [139], increasing microvascular permeability at the BBB. CGRP enhances the action of SP by altering its breakdown by competing for the same degradatory enzyme [140]. The majority of excitatory neurotransmission with-
in the CNS is associated with activation of a-amino3-hydroxy-5-methyl-isoxazole-4-propionic acid and NMDA receptors on spinal neurons by glutamate (Glu) [141–144], an excitatory amino acid present in large sensory fibers and nociceptive neurons [59]. While Glu receptors have been shown to be present on astrocytes [145], conflicting evidence exists as to whether these receptors are expressed on cerebral endothelial cells [146–149]. NMDA receptor activation results in production of nitric oxide (NO) and adenosine. NO can diffuse to afferent terminals to activate guanylate cyclase, resulting in stimulation of cGMP and a further release of Glu [59].
4.2. Activation of the hypothalamic–pituitary– adrenal axis The CNS regulates the immune system primarily via activation of the HPA axis. Stress responses due to physical, emotional, and environmental stimuli result in activation of the HPA axis and initiation of a ‘‘stress cascade’’ [150]. Cytokines have been shown to activate the HPA axis at the level of the CNS. The effects of cytokine administration on plasma levels of adrenocorticotropin (ACTH), corticosterone, and other mediators of the HPA axis have been reviewed [151]. Upon activation of the HPA axis, corticotropin-releasing hormone (CRH) is released from the hypothalamus, and circulating CRH and vasopressin stimulate the expression and release of ACTH from the anterior pituitary. ACTH circulates to the adrenal glands, where it induces the production and release of glucocorticoids, stress hormones that are responsible for downregulation of the immune response [150]. Glucocorticoids modulate the expression of cytokines and adhesion molecules and regulate immune cell trafficking, expression, and differentiation, as well as expression of chemoattractants, chemotaxis, and production of inflammatory mediators. Furthermore, glucocorticoids negatively feed back to inhibit the release of CRH [152,153].
5. Alterations of the blood–brain barrier by pain mediators Pain mediators involved in CNS disease and injury have been shown to alter the structure and function
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of the BBB. Additionally, peripheral inflammatory pain has been shown to alter the cytoarchitecture and permeability of the BBB [5,6]. Perturbations of tight and adherens junctions have been shown to play a role in the pathogenesis of many diseases [9]. Inflammatory permeability is thought to occur following a loss of interendothelial junction integrity during which cell–cell borders actively contract and passively recoil, resulting in larger endothelial clefts [154–157]. A potential consequence of increased BBB permeability is altered transport of therapeutic compounds to the CNS.
5.1. Effects of proinflammatory mediators on the blood–brain barrier Cytokines appear to play a key role in BBB disruption in models of CNS inflammation and injury. Exposure of cultured rat cerebral endothelial cells to TNF-a, IL-1b, and IL-6 has been shown to result in decreased TEER; this decrease has been shown to be countered by administration of indomethacin, a COX inhibitor [158]. Furthermore, TNF-a has been shown to induce COX-2 expression and prostaglandin release in brain microvessel endothelial cells [128]. Therefore, it has been proposed that cyclooxygenase activation within endothelial cells plays a role in BBB disruption. Furthermore, endothelial permeability has been shown to be increased in vitro by IL-1a via a decrease in plasma membrane-associated tyrosine phosphatase activity [159]. Such a decrease has been associated with decreased tyrosine phosphorylation of tight junction proteins, disintegration of adherens junctions, and decreased TEER [160–162]. Intrastriatal injection of IL-1b in rats has been associated with a neutrophildependent increase in BBB permeability [163,164]. The mechanism of this permeability increase has been attributed to loss of the tight junction proteins occludin and ZO-1 and redistribution of the adherens junction protein vinculin [163]. TNF-a, on the other hand, has been shown to downregulate the tight junction protein occludin in astrocytes (which do not form a permeability barrier) but not cerebral endothelial cells [165]. In addition, TNF-a has been shown to alter receptor-mediated endocytosis of LDLs and the iron-binding protein transferrin (TF) at the BBB [166]. Chemokines, which are produced and released
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following inflammatory insult, recruit leukocytes to the site of inflammation. Adhesion of leukocytes to the endothelium and recruitment of these cells into the CNS, in turn, have been shown to modulate BBB permeability in a number of CNS disorders. ICAM-1 on endothelial cells and its integrin receptor on circulating leukocytes are necessary for tethering of leukocytes to the BBB [95]. The loss of the tight junction proteins occludin and ZO-1 and redistribution of vinculin have been shown to be accompanied by increased expression of ICAM-1 by endothelial cells, adhesion of PMNs by an integrin-dependent interaction [167], and increased flux of PMNs across the BBB [163]. Furthermore, increased phosphotyrosine staining has been shown in areas with extensive PMN recruitment, indicating that migrating PMNs initiate a signaling cascade that results in TJ protein phosphorylation, modulation of BBB permeability, and reorganization of adherens junctions [167]. The presence of perivascular macrophages has been shown to facilitate infiltration of more monocytes via alterations of TJ proteins and thereby enhance disease progression in a model of HIV-1associated dementia [168]. ‘‘Activated’’ MMPs produced by microglia, astrocytes, and endothelial cells in the CNS contribute to tissue damage [97] and opening of the BBB [98,99]. MMP-associated changes in microvascular permeability have generally been attributed to the effects of these enzymes on the extracellular matrix [169]. However, occludin has recently been shown to be a non-matrix target of MMPs [170]. MMP-2 is expressed constitutively in endothelial cells and is known to be distributed near interendothelial junctions, spatially close to occludin, making this TJ protein a potential target of MMP-2. Furthermore, inflammatory mediators have been shown to alter the distribution of MMP-2. It has been proposed that degradation of TJ proteins by MMPs could increase endothelial permeability for a prolonged period; only following synthesis of new proteins could TJ integrity be recovered. Since MMP-9 is expressed weakly by endothelial cells in the absence of cytokines, MMP-linked, protein synthesis-independent changes in endothelial permeability have been attributed to activation of the constitutive MMP-2 [171]. BK-mediated increases in BBB permeability have been shown to be blocked by a combination of indomethacin (a COX inhibitor) and nor-
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dihydroguaiaretic acid (a 5-lipoxygenase inhibitor), and by superoxide dismutase and catalase (free radical scavengers). Therefore, it has been proposed that BK increases BBB permeability via a B 2 receptor-mediated mechanism involving activation of phospholipase A 2 , release of arachadonic acid, and production of free radicals [172]. Furthermore, the BK analogue RMP-7 has been shown to open the BBB to lanthanum in vivo by altering the integrity of endothelial tight junctions [173]. IFN-g treatment has been shown to produce upregulation of B 1 receptors on human brain endothelial cells; application of a B 1 agonist was shown to stimulate NO production, increase BBB permeability, and inhibit IL-8 release in vitro [174].
5.2. Effects of excitatory peptides and amino acids on the blood–brain barrier It has been proposed that SP possesses an immunomodulatory action at the BBB during inflammation and autoimmune disease. SP secretion has been observed in rat brain endothelial cells following stimulation by the proinflammatory cytokines IL-1b and TNF-a. Further, a portion of this SP has been found to bind to brain endothelial cells [175]. SP has been shown to stimulate translocation of PKC in bovine cerebral microvessels, indicating that this peptide may play a role in the regulation of BBB protein phosphorylation [176]. Additionally, receptors for CGRP, a peptide which has been shown to enhance the actions of SP by slowing its degradation [140], have been identified in human brain astrocytes and cerebromicrovascular endothelial cells [177], suggesting a possible role of this peptide in regulation of the BBB. Brain Glu concentrations in the intracellular space are higher than those in the extracellular space under normal conditions [178–180]. However, brain injury and disease have been shown to increase levels of extracellular Glu [178–183]. Glu has been shown to induce the synthesis of inflammatory mediators such as brain platelet-activating factor and NO in vivo [180,184]. Further, it has been proposed that disruption of the BBB may result from indirect actions of Glu, including induction of apoptosis in perivascular glia [183] or stimulation of NO production [180,184]. NO has been implicated in increased BBB permeability following application of Glu to cerebral
endothelial cells in vitro [180]. Additionally, leukocyte recruitment has been observed parallel to BBB breakdown following intracerebrally injected NMDA in adult and juvenile rats [185]. ‘‘Activated’’ PMNs have been shown to release Glu and upregulate expression of Glu receptors, resulting in decreased BBB function [148].
5.3. Effects of hypothalamic–pituitary–adrenal axis activation on the blood–brain barrier Emotional stress has been shown to precipitate or worsen several neuroinflammatory disorders [186] including relapsing-remitting multiple sclerosis [187–189]. Stress responses activate the HPA axis through release of CRH from the hypothalamus, resulting in production of glucocorticoids to downregulate the immune response [150]. It has been hypothesized that CRH released in acute stress either affects the BBB directly or via mast cell activation. Mast cells are found throughout the periphery and CNS and play a critical role in the development of allergic reactions [190]. Mast cells are thought to modulate BBB permeability since many mast cell mediators, including TNF-a and histamine, are vasoactive [191]. In fact, recent studies have shown that CRH has proinflammatory effects which are mediated via mast cell activation [192,193]. Furthermore, acute, non-traumatic stress has been shown to increase BBB permeability and activate mast cells [194], supporting the hypothesis that mast cell activation in response to stress influences BBB permeability.
6. Implications of pain responses in central nervous system drug delivery Painful and / or inflammatory conditions can be treated with a number of different classes of drugs, including anti-HIV drugs, antibiotics, opioid analgesics, antineoplastics, and antiepileptics. Pain and inflammatory mediators and their analogues have been shown to alter the function of the BBB. One consequence of BBB disruption has been shown to be increased drug delivery to the brain. This altered delivery may be detrimental in the case of drugs with narrow therapeutic ranges. On the other hand, in-
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creased delivery to the brain may be beneficial for targeting disorders within the CNS.
6.1. Influence of increased blood–brain barrier paracellular permeability on drug delivery to the brain The TJs of the BBB prevent passage of small, hydrophilic molecules from the blood to the brain. During pain or inflammation, however, TJ structure has been shown to be modified, resulting in increased BBB permeability. Increased delivery of drugs, a potential consequence of this increased permeability, may be beneficial or detrimental. Few studies have been performed concerning the relationship among pain mediators, BBB paracellular permeability, and drug delivery. Several key studies involve transport of the platinum chemotherapeutic agent cisplatin (CIS) across the BBB. Lipopolysaccharide (LPS) has been shown to decrease TEER in bovine cerebral endothelial cells, indicating an ‘‘opening’’ of intercellular tight junctions [195]. Under normal conditions, CIS does not readily cross the BBB due to its hydrophilicity [196]. However, LPS administration and subsequent production of inflammatory mediators have been shown to enhance platinum content in the cerebral cortex [197]. The disabling neurotoxicity that has been observed following CIS readministration [198] has therefore been attributed to increased transport of the drug across a compromised BBB [197], likely via paracellular diffusion. TNF-a, which has also been shown to decrease TEER in vitro [158], has been shown to increase CIS transport across bovine brain microvessel endothelial cells [199], providing further evidence that BBB disruption by inflammatory mediators plays a role in CIS delivery to the brain. In this study, it was proposed that combined administration of TNF-a and CIS could be clinically useful in patients with CNS tumors.
6.2. Influence of altered blood–brain barrier endocytosis on drug delivery to the brain The BBB restricts the entry of most proteins and large-molecular weight molecules into the brain. However, receptors on the surface of brain capillary endothelial cells play an important role in selective transport of substances such as TF (an iron-binding
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protein), insulin, and LDLs across the BBB via receptor-mediated endocytosis [40–43]. The TF receptor and its substrate have in fact been exploited for delivery of therapeutic agents to the CNS. Biotinylated basic fibroblast growth factor and brainderived neurotrophic factor, potent neuroprotective agents, have been delivered across the BBB via incorporation into a peptide drug delivery vector containing murine OX26, a monoclonal antibody against the rat TF receptor which undergoes receptor-mediated transport [200–202]. This delivery vector has also been utilized for delivery of antiAlzheimer’s and anti-HIV antisense molecules across the BBB [203]. TF itself has been utilized to carry therapeutic agents across the BBB; conjugation of nerve growth factor to TF via avidin / biotin technology has been shown to be as effective in transporting biotinylated therapeutics as OX26 [204]. Alterations in receptor-mediated endocytosis during neuropathological conditions could potentially influence the delivery of compounds such as insulin, therapeutic drug delivery vectors, or transferrinconjugated drugs across the BBB. It has been shown that the process of receptor-mediated endocytosis is altered during neuropathological conditions. Neurodegenerative diseases such as Parkinson’s disease and Alzheimer’s disease have been associated with increased levels of iron and oxidative stress in the brain [205–207]. It has been proposed that one of the causes of neuronal death in such diseases involves disruption in iron transport protein expression [208,209]. Inflammatory mediators have also been shown to influence receptor-mediated endocytosis in vitro. TNF-a has been shown to alter receptor-mediated endocytosis and transendothelial transport of LDLs and TF. These modifications, significant since both iron and lipids are essential for normal growth and function of brain cells, were proposed to be due to a change in intracellular traffic kinetics, since no increase in LDL or TF receptor expression was observed at the BBB [166].
6.3. Potential influence of altered blood–brain barrier efflux on drug delivery to the brain Membrane efflux pumps at the BBB, including P-gp, organic anion transporters, and MRP, limit penetration of drugs into the CNS by actively transporting them out of the brain. Drug efflux has
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been linked to multidrug resistance, which has been described as an acquired or intrinsic resistance to therapy, in a number of pathologies. Efflux transporter function at the BBB has been associated with minimal effectiveness of anti-HIV drugs on AIDS dementia, antibacterials on CNS infection, opioids on CNS-based pain, and chemotherapy on brain tumors [32]. BBB efflux of a number of drugs has been shown to be influenced by putative specific inhibitors of efflux transporters [210–213]. Increased multidrug resistance (MDR1) gene mRNA and P-gp protein expression have been observed in brain specimens taken from patients with medically intractable epilepsy [214]. Furthermore, increased efflux transporter expression has been observed in cultured rat brain endothelial cells subjected to the oxidative stress of ischemia / reperfusion [215]. The possibility of alterations in the expression and function of efflux transport proteins and the MDR1 gene at the BBB during pain or inflammation remains to be investigated. However, such alterations have been observed in other cell lines following stimulation with proinflammatory mediators [216–218].
6.4. Potential influence of pain-induced glutamate release on the delivery of glutamate-conjugated drugs to the brain Glutamate (Glu), a neurotransmitter present in large sensory fibers and nociceptive neurons [59], initiates excitatory neurotransmission in the CNS via activation of NMDA receptors [141–144]. ‘‘Activated’’ PMNs have been shown to release Glu and upregulate expression of Glu receptors, resulting in decreased BBB function [148]. Conjugation of the BBB-impermeable drug p-di(hydroxyethyl)-aminoD-phenylalanine (an analogue of the antitumor agent D-melphalan) to L-Glu has resulted in improved permeability of the drug in vitro and in vivo via the L-Glu transport system. 5,7-Dichlorokynurenic acid and its conjugates ( L-Glu, L-Asp, and L-Gln), on the other hand, have exhibited a low brain-to-plasma concentration ratio in vivo. Therefore, it has been suggested that facilitation of the delivery of nonpermeable conjugates across the BBB depends on their physicochemical and receptor-binding properties [219,220]. Alterations in delivery of L-Glu conjugates in a cancer model have not been investi-
gated and may be influenced by the release of endogenous Glu and / or alterations in L-Glu transporter expression or activity in response to cancerrelated pain. The presence of endogenous Glu may effectively reduce the dose of Glu-conjugated drug to reach the brain. Furthermore, possible pain-induced alterations in Glu transporter expression or activity could influence the dose of Glu-conjugated drug required to elicit a therapeutic effect.
6.5. Potential influence of pain-induced bradykinin release on the action of a bradykinin analogue at the blood–brain barrier An analogue of the inflammatory mediator BK has been designed to transiently increase the permeability of the BBB and the blood–brain tumor barrier (BBTB). Labradimil (LAB) (also known as Cereport or RMP-7) is a nine-amino-acid peptide which selectively binds to the bradykinin B 2 receptor. In vitro, LAB initiates BK-like second messenger cascades, including increases in intracellular Ca 21 and turnover of phosphatidylinositol. The mechanism of intravenous LAB has been shown to involve disengagement of the TJs of endothelial cells that make up the BBB [221]. Pharmacological opening of the BBB and BBTB via LAB administration has been shown to be clinically relevant in the treatment of gliomas using antineoplastic agents such as carboplatin [221– 224]. Alterations in delivery of LAB during cancer have not been investigated and may be influenced by the release of endogenous BK and / or alterations in B 2 receptor expression or activity due to cancerrelated pain. The presence of endogenous BK may effectively reduce the dose of LAB needed to transiently open BBB TJs; furthermore, possible pain-induced alterations in B 2 receptor expression or activity could influence the required dose of LAB.
7. Conclusions The BBB plays a critical role in maintaining cerebral homeostasis by separating the CNS from the periphery. In health, the BBB serves to control the passage of solutes into and out of the brain. During pathological insult, the BBB is capable of rapid
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modulation; in all but the most extreme cases, the BBB is able to ‘‘bend without breaking’’, or yield increased permeability while maintaining structural integrity. The structure and function of the BBB has been shown to be altered in a number of diseases with pain and / or inflammatory components. Evidence has shown that a number of mediators involved in the pain response, including cytokines, chemokines, cellular adhesion molecules, MMPs, kinins, PGs, excitatory molecules such as SP and Glu, and CRH, play roles in altering the cytoarchitecture and permeability of the BBB. Inflammatory mediators have also been shown to alter receptor-mediated endocytotic uptake at the BBB. Furthermore, the release of endogenous inflammatory mediators during pain could potentially influence the uptake of drugs meant to utilize specific transporters or activate receptors at the BBB. While little is known about the effects of pain mediators on efflux transporter expression and activity at the BBB, such alterations have been observed in epilepsy; efflux has been shown to be altered in other cell lines in response to proinflammatory mediators as well. Therefore, an understanding of alterations in drug efflux at the BBB during pain and / or inflammation may be of significant importance in predicting therapeutic outcomes. Increased drug delivery to the brain is a potential consequence of pain- and / or inflammation-induced BBB disruption. This altered delivery may be either detrimental (resulting in CNS toxicity) or beneficial (resulting in improved therapeutic outcome) based on the drug and its intended site of action. An understanding of BBB structural, functional, and transport alterations in pain and / or inflammation will result in new and more effective therapeutic approaches to treating disease.
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Pain and the blood–brain barrier: obstacles to drug delivery Anne M. Wolka, Jason D. Huber, Thomas P. Davis* Department of Pharmacology, University of Arizona College of Medicine, P.O. Box 245050, 1501 N. Campbell Avenue, Tucson, AZ 85724, USA Received 18 April 2003; accepted 8 May 2003
Abstract Delivery of drugs across the blood–brain barrier has been shown to be altered during pathological states involving pain. Pain is a complex phenomenon involving immune and centrally mediated responses, as well as activation of the hypothalamic–pituitary–adrenal axis. Mediators released in response to pain have been shown to affect the structure and function of the blood–brain barrier in vitro and in vivo. These alterations in blood–brain barrier permeability and cytoarchitecture have implications in terms of drug delivery to the central nervous system, since pain and inflammation have the capacity to alter drug uptake and efflux across the blood–brain barrier. An understanding of how blood–brain barrier and central nervous system drug delivery mechanisms are altered during pathological conditions involving pain and / or inflammation is important in designing effective therapeutic regimens to treat disease. 2003 Elsevier B.V. All rights reserved. Keywords: Inflammation; CNS response; HPA axis; Inflammatory mediator; Permeability; Transport
Contents 1. Introduction ............................................................................................................................................................................ 2. Function and structure of the blood–brain barrier in health ......................................................................................................... 3. Drug delivery across the blood–brain barrier in health ............................................................................................................... 3.1. Diffusion ......................................................................................................................................................................... 3.2. Carrier-mediated transport ................................................................................................................................................ 3.3. Endocytosis ..................................................................................................................................................................... 3.4. Drug efflux ...................................................................................................................................................................... 4. Pain mechanisms..................................................................................................................................................................... 4.1. Immune and central nervous system responses ................................................................................................................... 4.1.1. Cytokines and chemokines...................................................................................................................................... 4.1.2. Cellular adhesion molecules.................................................................................................................................... 4.1.3. Matrix metalloproteinases ....................................................................................................................................... 4.1.4. Kinins ................................................................................................................................................................... 4.1.5. Prostaglandins........................................................................................................................................................ 4.1.6. Excitatory peptides and amino acids ........................................................................................................................ *Corresponding author. Tel.: 1 1-520-626-7643; fax: 1 1-520-626-4053. E-mail address: [email protected] (T.P. Davis). 0169-409X / 03 / $ – see front matter 2003 Elsevier B.V. All rights reserved. doi:10.1016 / S0169-409X(03)00100-5
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4.2. Activation of the hypothalamic–pituitary–adrenal axis ....................................................................................................... 5. Alterations of the blood–brain barrier by pain mediators ............................................................................................................ 5.1. Effects of proinflammatory mediators on the blood–brain barrier......................................................................................... 5.2. Effects of excitatory peptides and amino acids on the blood–brain barrier ............................................................................ 5.3. Effects of hypothalamic–pituitary–adrenal axis activation on the blood–brain barrier ........................................................... 6. Implications of pain responses in central nervous system drug delivery ....................................................................................... 6.1. Influence of increased blood–brain barrier paracellular permeability on drug delivery to the brain ......................................... 6.2. Influence of altered blood–brain barrier endocytosis on drug delivery to the brain ................................................................ 6.3. Potential influence of altered blood–brain barrier efflux on drug delivery to the brain ........................................................... 6.4. Potential influence of pain-induced glutamate release on the delivery of glutamate-conjugated drugs to the brain .................... 6.5. Potential influence of pain-induced bradykinin release on the action of a bradykinin analogue at the blood–brain barrier......... 7. Conclusions ............................................................................................................................................................................ References ..................................................................................................................................................................................
1. Introduction The blood–brain barrier (BBB) serves as a physical and metabolic barrier between the central nervous system (CNS) and the periphery. The BBB is a dynamic structure capable of rapid modulation to maintain homeostasis within the CNS. Decreased BBB function has been described in CNS conditions with pain and / or inflammatory components, including multiple sclerosis [1], Alzheimer’s disease [2], human immunodeficiency virus (HIV) dementia [3], and meningitis [4]. Recent evidence has indicated that peripheral inflammation also alters the structure and increases the permeability of the BBB [5,6]. A potential consequence of increased BBB permeability is altered delivery of therapeutic pharmaceuticals to the CNS. An understanding of how the BBB and its transport / delivery mechanisms are altered during pathological conditions involving pain and / or inflammation is important both in assessing disease etiology and in creating effective therapeutic regimens to treat disease.
2. Function and structure of the blood–brain barrier in health The BBB, located at the level of brain capillary endothelial cells [7], serves to maintain brain homeostasis by regulating the composition of brain extracellular fluid independent of fluctuations within the peripheral circulation. In this manner, the BBB maintains optimal conditions for neuronal function. The structure and function of the BBB have been reviewed [8,9]. Tight junctions (TJs) and the lack of
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fenestrations at the BBB allow maintenance of CNS homeostasis. TJs in the BBB are composed of transmembrane and cytoplasmic proteins linked to an actin cytoskeleton. TJs impart significant transendothelial electrical resistance (TEER, 1500–2000 V cm 2 ) to brain endothelial cells and severely restrict paracellular diffusion of solutes into the brain [10]. Three integral proteins make up TJs: claudin, occludin, and junction adhesion molecule (JAM). The primary seal of the TJ is formed when claudin dimers bind homotypically to claudins on adjacent endothelial cells [11]. Occludin is a regulatory protein present at TJs, and the presence of occludin is associated with increased TEER and decreased paracellular permeability [12]. JAMs, members of the immunoglobin superfamily, can function in association with platelet endothelial cellular adhesion molecule 1 to regulate leukocyte migration [13]. Cytoplasmic accessory proteins such as zonula occludens proteins (ZO-1, -2, and -3) also play a role in maintaining the function of the BBB. ZO proteins, which belong to the membrane-associated guanylate kinase-like protein family, serve as recognition proteins for TJ placement and as a support structure for signal transduction proteins [14]. Actin, the primary cytoskeletal protein, has known binding sites on all ZO proteins, as well as on claudin and occludin [15]. A dense band of actin and myosin filaments circumscribe endothelial cells, with actin filaments extending into TJs [16]. ZO-1 binds to actin filaments and the C terminus of occludin. Therefore, the structural and dynamic properties of perijunctional actin are coupled to the paracellular barrier. The structural organization of actin has been shown to influence TJ integrity. Actin-disrupting substances have been shown to alter TJ structure and
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function [17,18], while ATP depletion has been shown to alter TJ structure, decrease TEER, and result in increased association of ZO-1 and -2 with actin [19]. TJs are located at cholesterol-rich regions of the plasma membrane associated with caveolin 1 [20], a molecule which regulates several signal transduction pathways and downstream targets [21]. Several cytoplasmic signaling molecules, including protein kinase C (PKC) and Ca 21 , are located at TJ complexes and are involved in signaling cascades that control TJ assembly and disassembly [22]. PKC serves to regulate TJ formation and function [23]. ZO proteins are thought to serve as scaffolding for PKC signal transduction pathways; in turn, PKC has been shown to play a role in the migration of intracellular ZO-1 to the plasma membrane [24]. PKCj and PKCl and their specific binding protein have been shown to be located at TJs. These proteins have been implicated in the establishment of cell polarity, which is fundamental to BBB differentiation and function [25]. TJ activity is regulated by both intracellular and extracellular Ca 21 . Removal of extracellular Ca 21 has been associated with a decrease in TEER across the membrane and an increase in permeability [18] via heterotrimeric G protein and PKC signaling mechanisms. Homotypic interaction of E-cadherin, which is thought to be the initial event of junctional complex formation, also depends on extracellular Ca 21 [26]. Intracellular Ca 21 regulates cell–cell contact [27], TEER [27], migration of intracellular ZO-1 to the plasma membrane [28], and assembly of TJs [29].
3.1. Diffusion
3. Drug delivery across the blood–brain barrier in health
3.3. Endocytosis
The barrier properties of the BBB result in limited brain penetration of a number of substances. Selective transport mechanisms present at the BBB include diffusion, carrier-mediated transport, and receptor-mediated, adsorptive, and fluid-phase endocytosis [30,31]. BBB efflux transporters that actively transport compounds from the brain to the blood serve to maintain brain homeostasis but also limit the uptake of therapeutic compounds into the CNS [32] (Fig. 1).
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Diffusion across the BBB is typically transcellular since TJs restrict the paracellular diffusion of solutes [10]. Therefore, the lipophilicity and hydrogen bonding potential of a solute determine its ability to diffuse into the brain; in general, greater lipophilicity and lower hydrogen bonding potential of a compound are associated with greater transcellular diffusivity [33–36].
3.2. Carrier-mediated transport Carrier-mediated transport at the BBB involves a substrate–transporter interaction on the brain endothelial surface. Carrier-mediated transport is a saturable process and is typically classified according to the energy requirements for transport and / or cotransport of another substance (symport or antiport) [31]. Transport of essential compounds, including amino acids, monocarboxylic acids, sugars, and nucleosides, in and / or out of the brain has been shown to occur via specific carrier-mediated transporters. Transporters have been identified at the BBB for sugars such as glucose and mannose; neutral amino acids such as phenylalanine, leucine, and tyrosine; acidic amino acids such as glutamate and aspartate; basic amino acids such as arginine and lysine; b-amino acids such as b-alanine; monocarboxylic acids such as lactate, ketone bodies, and other short-chain fatty acids; amines such as mepyramine; the purine bases adenine and guanine; and peptides such as vasopressin [37,38].
The BBB has reduced endocytosis compared to other tissues [39]; nevertheless, vesicular transport (via receptor-mediated, adsorptive, or fluid-phase endocytosis) plays an important role in the delivery of several compounds to the brain. The iron-bound iron transport protein transferrin has been shown to be endocytosed into the cerebral microvasculature via a receptor-mediated mechanism [40,41]. Similarly, insulin and low-density lipoproteins (LDLs) have been shown to undergo receptor-mediated endocytosis at the BBB [42,43]. Adsorptive endocytosis
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Fig. 1. Transport mechanisms across the blood–brain barrier (BBB). (A) Transcellular diffusion; (B) paracellular diffusion; (C) carrier-mediated transport; (D) fluid-phase endocytosis; (E) adsorptive endocytosis; (F) receptor-mediated endocytosis; and (G) drug efflux.
has been identified as the mechanism of uptake of certain cationized proteins [44] and peptides [45] into the brain. Fluid-phase endocytosis has been demonstrated in vitro in both bovine [46] and human [47] BBB cell culture systems.
3.4. Drug efflux The impact of efflux transporters on drug design and delivery to the CNS has been reviewed [32].
Drugs [48,49], nutrients, metabolites, peptides, hormones, and neurotransmitters [50] can be actively transported from the brain to the blood to maintain brain homeostasis. Active transport out of the brain occurs via efflux transporters localized at the BBB, including P-glycoprotein (P-gp), members of the multidrug resistance-associated protein (MRP) family, monocarboxylic acid transporters, and organic ion transporters [32]. Efflux at the BBB has been shown to limit the penetration of therapeutic compounds such as anti-HIV drugs [51,52], analgesics [53],
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antibacterials [54,55], antiepileptics [56], and anticancer agents [57,58] into the CNS.
adrenal (HPA) axis. These pain mechanisms and their influences on drug delivery across the BBB will be discussed in the following sections (Fig. 2).
4. Pain mechanisms
4.1. Immune and central nervous system responses
Pain is a complex phenomenon involving responses from the immune system and the CNS, as well as activation of the hypothalamic–pituitary–
The immune response is characterized by the rapid production and release of inflammatory mediators such as cytokines, chemokines, cellular adhesion
Fig. 2. Physiological responses to pain and their potential influences on drug delivery at the BBB.
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molecules, matrix metalloproteinases (MMPs), kinins, and prostaglandins (PGs) at the site of disease or injury. Inflammation is typified by increased vascular permeability, localized edema formation, erythema, and increased leukocyte migration. The CNS utilizes neuronal pathways to signal the immune system. The neuronal response to noxious stimulation involves both excitatory and inhibitory neurotransmission within the sensory areas of the spinal cord, and the balance of these CNS responses determines the level of transmission of nociceptive signals to the brain [59]. Furthermore, proinflammatory mediators produced and released in the CNS following local injury or inflammation play a role in the central-mediated pain response.
4.1.1. Cytokines and chemokines Cytokines can either be released in the periphery or the CNS during disease or in response to trauma. Numerous cytokines are involved in the immune response, particularly the interleukins IL-1a and -1b, -2, -4, -6, -8, -10, and -13, tumor necrosis factor-a (TNF-a), and the type I interferons IFN-a and -b [60]. Both excitatory and inhibitory cytokines play a role in inflammation. TNF-a, IL-2, IL-6, IL-8, and IL-1b have been shown to be hyperalgesic [61–65]. Cytokines have also been shown to interact with kinins to potentiate their effects [66]. Changes in expression of endothelial surface molecules (adhesion molecules such as selectins and integrins) and adhesion of polymorphoneutrophils (PMNs), monocytes, and lymphocytes to cell walls have been shown to be induced by proinflammatory cytokines such as IL-1b. Inhibitory cytokines, including IL-4, IL-10, and IL-13, modulate the immune response by exerting anti-inflammatory actions [66] and inhibiting the synthesis of proinflammatory cytokines such as IL-1b and TNF-a [67]. Peripheral cytokines such as IL-1, IL-6, and TNFa have been proposed to activate central responses to peripheral insult. Active transport systems for IL-1 and TNF-a exist at the BBB [68,69]; however, little bioavailable IL-1 or TNF-a circulates from the site of injury or inflammation, except in severe trauma [70]. It has been proposed that IL-1 and TNF-a instead induce IL-6, a cytokine whose circulating levels increase by several orders of magnitude during the development of fever [71]. Peripheral cytokines
may also influence the CNS via neural pathways [72]. While constitutive expression of cytokines in the CNS is low, ‘‘activated’’ microglia, neurons, astroglia, perivascular cells and endothelial cells release cytokines such as IL-1b, IL-6, and TNF-a in response to CNS tissue damage or infection associated with pathological states [70]. Levels of cytokine expression depend on brain region, with the greatest levels in the hypothalamus and hippocampus and lower levels in the cortex and brain stem [73–76]. Chemotactic cytokines, or chemokines, play inflammatory, homeostatic, angiostatic, and / or angiogenic roles in disease [77]. Inflammatory chemokines interact with seven-transmembrane G protein-coupled receptors expressed on leukocytes in order to recruit these molecules to the site of inflammation [78,79]. Chemokines have also been shown to regulate cytokine production [80,81]. Chemokines are expressed in the CNS as well as the periphery. Chemokines such as monocyte chemotactic proteins (MCPs), macrophage inflammatory protein 1-a and -b, regulated on activation normal T-cell expressed and secreted, and interferon-inducible protein 10 are produced in astrocytes, microglia, and perivascular leukocytes during inflammatory diseases such as multiple sclerosis and following brain injury [82].
4.1.2. Cellular adhesion molecules Increased leukocyte migration is a hallmark of the immune response. Receptors on the surface of leukocytes are classified either as selectins or integrins. While selectins take part in initial interactions of leukocytes with cell surfaces, integrins participate in adhesion and transmigration processes [83,84]. Endothelial cell ‘‘activation’’ following an immune challenge results in upregulation of the expression of genes that encode for leukocyte adhesion receptors [85,86] such as intercellular adhesion molecule 1 (ICAM-1) and vascular cell adhesion molecule 1 (VCAM-1) [85–87]. Interactions between endothelial cell receptors and selectins and integrins result in leukocyte adhesion to and migration across endothelial cells of the BBB. Leukocyte trafficking involves rolling, tethering, firm adhesion, diapedesis, and chemotaxis of leukocytes [88]. Following ‘‘activation’’ of the endo-
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thelium by inflammatory mediators, leukocytes reversibly adhere to the endothelium. Under conditions of flow, this initial adhesion results in rolling of leukocytes. The interaction between selectins and cell membrane glycoproteins tether leukocytes to the endothelium. Integrin receptors on tethered leukocytes are then ‘‘activated’’ by inflammatory mediators such as endothelial membrane-expressed platelet-activating factor or chemokines. Firm adhesion of leukocytes to the endothelium becomes possible since ‘‘activated’’ integrin receptors possess greater affinity for the endothelium. Adherent migrating leukocytes move over the endothelium and diapedese between endothelial cells to enter extravascular tissue. During diapedesis, leukocytes have been shown to signal endothelial cells, disrupting intercellular junction integrity [89]. Leukocytes then transmigrate to the site of immune reaction. The b1 class of integrins, which are the primary integrins expressed on endothelial cells in the CNS [90], play a critical role in regulating BBB function. A number of other integrins are expressed in the CNS, including av integrins, which are expressed on neurons, glial cells, meningeal cells, and endothelial cells [91,92], and b2 integrins, which are expressed on microglia and infiltrating leukocytes [91,93]. Integrins appear to play a role during CNS inflammation, since their expression has been shown to be altered during inflammatory diseases such as multiple sclerosis [94]. Furthermore, TNF-a, IL1-b, and IFN-g, cytokines that are elevated in inflammatory CNS disease, have been shown to induce expression of the adhesion molecules ICAM-1 and VCAM-1 on brain endothelial cells and astrocytes [95].
4.1.3. Matrix metalloproteinases Vascular endopeptidases known as MMPs play a role in vascular remodeling following inflammation, injury, and / or oxidative stress. MMP activity in the vasculature is rigorously controlled by tissue inhibitors of metalloproteinases (TIMPs). Stresses upregulate MMP expression and activity, disrupting the balance of MMPs and TIMPs. This imbalance then leads to extracellular matrix reorganization and degradation [96]. MMP release from inflammatory cells occurs following stress. MMPs are normally present in the brain in latent forms. ‘‘Activated’’ MMPs, which are
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secreted by microglia, astrocytes, and endothelial cells in the CNS in response to trauma or disease, contribute to tissue damage [97] and opening of the BBB [98,99]. MMP-2 (gelatinase A) and MMP-9 (gelatinase B) have been shown to degrade the major components of the basal lamina of cerebral blood vessels [100]. Furthermore, TNF-a, a cytokine which induces BBB opening, has been linked to MMP-9 (gelatinase B) expression [97]. In addition, cytokines secreted from ‘‘activated’’ macrophages upregulate MMP gene expression in the vasculature [101,102].
4.1.4. Kinins Kinins act on seven-transmembrane G proteincoupled B 1 or B 2 receptors to activate and sensitize nociceptors [103–105]. Bradykinin (BK) is well characterized [106–109] and has been shown to interact with B 2 receptors. The action of BK involves activation of phospholipase C followed by stimulation of PKC and an increase in Na 1 conductance. The result of these modulations is depolarization of sensory afferent neurons and hyperalgesia [110,111]. Kinins not only activate and sensitize nociceptors, but also exert proinflammatory effects, resulting in vasodilation, edema, and the release of other inflammatory molecules [66]. Mechanisms for the synthesis of kinins are present in the CNS [112]. Furthermore, kinins and their receptors have been detected in the brain in vivo and in vitro [113–115]. B 2 receptors have been identified on CNS microglia, the primary immune effector cell population in the CNS, as well as on endothelial cells [116,117]. The mechanism of BK in the cerebral vasculature is thought to be similar to its action in the periphery. BK stimulates neural and neuroglial cells, resulting in production and release of PG precursors, cytokines, free radicals, and nitric oxide. These actions of BK result in damage to neural cells and disturbance of BBB function [112]. Furthermore, activation of CNS astrocytes by kinins has been linked to glutamate release and increases in neuronal Ca 21 [118]. 4.1.5. Prostaglandins PGs play a critical role in the modulation of immune function [119,120]. Inflammatory insult leads to the release of arachidonic acid (AA) from membrane phospholipids via phospholipase A 2 ac-
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tion. The cyclooxygenase enzymes COX-1 and COX-2 convert AA to prostaglandin H 2 , which is then converted into different PGs, including PGI 2 , PGF 2a , PGD 2 and PGE 2 . Inflammation involves primarily PGE 2 and PGI 2 [121]. PGE 2 is one of the best-characterized PGs; it is secreted by fibroblasts, macrophages, and malignant cells following an immune challenge, resulting in vasodilation and subsequent erythema and edema formation [122]. Furthermore, PGE 2 controls the production of cytokines by ‘‘activated’’ macrophages [123,124] and induces the synthesis of MMPs [122], leading to reorganization and degradation of the extracellular matrix. Stimulation of CNS cells by inflammatory cytokines such as IL-1b and TNF-a results in production and release of PGE 2 by almost all CNS cell types, including brain endothelial cells [125–130]. The COX-2 enzyme, which plays a role in PG synthesis, has been shown to be upregulated in the excitatory neurons of the cerebral cortex and hippocampus following insult related to overstimulation of Nmethyl-D-aspartate (NMDA) receptors [131–133]. Furthermore, TNF-a has been shown to induce COX-2 expression in brain microvessel endothelial cells [128]. PGE 2 has been shown to induce the IL-6-type cytokine oncostatin-M in microglia [134], resulting in astrocytic production of IL-6 [135] and upregulation of ICAM-1, IL-6, and the chemokine MCP1 in human cerebral endothelial cells [136].
4.1.6. Excitatory peptides and amino acids Excitatory peptides in the CNS also play a role in nociception. The peptides present in the greatest abundance within the dorsal horn are substance P (SP) and calcitonin gene-regulated peptide (CGRP). SP, a member of the tachykinin family, acts on neurokinin NK 1 receptors causing long-lasting depolarization via inactivation of K 1 and / or activation of Na 1 or Ca 21 currents [137]. Synaptic depolarization and the increase in Ca 21 in turn induce the protooncogene c-fos, resulting in production of c-fos protein, a neural marker of pain [138]. Furthermore, SP stimulates the release of the proinflammatory mediator histamine from mast cells [139], increasing microvascular permeability at the BBB. CGRP enhances the action of SP by altering its breakdown by competing for the same degradatory enzyme [140]. The majority of excitatory neurotransmission with-
in the CNS is associated with activation of a-amino3-hydroxy-5-methyl-isoxazole-4-propionic acid and NMDA receptors on spinal neurons by glutamate (Glu) [141–144], an excitatory amino acid present in large sensory fibers and nociceptive neurons [59]. While Glu receptors have been shown to be present on astrocytes [145], conflicting evidence exists as to whether these receptors are expressed on cerebral endothelial cells [146–149]. NMDA receptor activation results in production of nitric oxide (NO) and adenosine. NO can diffuse to afferent terminals to activate guanylate cyclase, resulting in stimulation of cGMP and a further release of Glu [59].
4.2. Activation of the hypothalamic–pituitary– adrenal axis The CNS regulates the immune system primarily via activation of the HPA axis. Stress responses due to physical, emotional, and environmental stimuli result in activation of the HPA axis and initiation of a ‘‘stress cascade’’ [150]. Cytokines have been shown to activate the HPA axis at the level of the CNS. The effects of cytokine administration on plasma levels of adrenocorticotropin (ACTH), corticosterone, and other mediators of the HPA axis have been reviewed [151]. Upon activation of the HPA axis, corticotropin-releasing hormone (CRH) is released from the hypothalamus, and circulating CRH and vasopressin stimulate the expression and release of ACTH from the anterior pituitary. ACTH circulates to the adrenal glands, where it induces the production and release of glucocorticoids, stress hormones that are responsible for downregulation of the immune response [150]. Glucocorticoids modulate the expression of cytokines and adhesion molecules and regulate immune cell trafficking, expression, and differentiation, as well as expression of chemoattractants, chemotaxis, and production of inflammatory mediators. Furthermore, glucocorticoids negatively feed back to inhibit the release of CRH [152,153].
5. Alterations of the blood–brain barrier by pain mediators Pain mediators involved in CNS disease and injury have been shown to alter the structure and function
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of the BBB. Additionally, peripheral inflammatory pain has been shown to alter the cytoarchitecture and permeability of the BBB [5,6]. Perturbations of tight and adherens junctions have been shown to play a role in the pathogenesis of many diseases [9]. Inflammatory permeability is thought to occur following a loss of interendothelial junction integrity during which cell–cell borders actively contract and passively recoil, resulting in larger endothelial clefts [154–157]. A potential consequence of increased BBB permeability is altered transport of therapeutic compounds to the CNS.
5.1. Effects of proinflammatory mediators on the blood–brain barrier Cytokines appear to play a key role in BBB disruption in models of CNS inflammation and injury. Exposure of cultured rat cerebral endothelial cells to TNF-a, IL-1b, and IL-6 has been shown to result in decreased TEER; this decrease has been shown to be countered by administration of indomethacin, a COX inhibitor [158]. Furthermore, TNF-a has been shown to induce COX-2 expression and prostaglandin release in brain microvessel endothelial cells [128]. Therefore, it has been proposed that cyclooxygenase activation within endothelial cells plays a role in BBB disruption. Furthermore, endothelial permeability has been shown to be increased in vitro by IL-1a via a decrease in plasma membrane-associated tyrosine phosphatase activity [159]. Such a decrease has been associated with decreased tyrosine phosphorylation of tight junction proteins, disintegration of adherens junctions, and decreased TEER [160–162]. Intrastriatal injection of IL-1b in rats has been associated with a neutrophildependent increase in BBB permeability [163,164]. The mechanism of this permeability increase has been attributed to loss of the tight junction proteins occludin and ZO-1 and redistribution of the adherens junction protein vinculin [163]. TNF-a, on the other hand, has been shown to downregulate the tight junction protein occludin in astrocytes (which do not form a permeability barrier) but not cerebral endothelial cells [165]. In addition, TNF-a has been shown to alter receptor-mediated endocytosis of LDLs and the iron-binding protein transferrin (TF) at the BBB [166]. Chemokines, which are produced and released
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following inflammatory insult, recruit leukocytes to the site of inflammation. Adhesion of leukocytes to the endothelium and recruitment of these cells into the CNS, in turn, have been shown to modulate BBB permeability in a number of CNS disorders. ICAM-1 on endothelial cells and its integrin receptor on circulating leukocytes are necessary for tethering of leukocytes to the BBB [95]. The loss of the tight junction proteins occludin and ZO-1 and redistribution of vinculin have been shown to be accompanied by increased expression of ICAM-1 by endothelial cells, adhesion of PMNs by an integrin-dependent interaction [167], and increased flux of PMNs across the BBB [163]. Furthermore, increased phosphotyrosine staining has been shown in areas with extensive PMN recruitment, indicating that migrating PMNs initiate a signaling cascade that results in TJ protein phosphorylation, modulation of BBB permeability, and reorganization of adherens junctions [167]. The presence of perivascular macrophages has been shown to facilitate infiltration of more monocytes via alterations of TJ proteins and thereby enhance disease progression in a model of HIV-1associated dementia [168]. ‘‘Activated’’ MMPs produced by microglia, astrocytes, and endothelial cells in the CNS contribute to tissue damage [97] and opening of the BBB [98,99]. MMP-associated changes in microvascular permeability have generally been attributed to the effects of these enzymes on the extracellular matrix [169]. However, occludin has recently been shown to be a non-matrix target of MMPs [170]. MMP-2 is expressed constitutively in endothelial cells and is known to be distributed near interendothelial junctions, spatially close to occludin, making this TJ protein a potential target of MMP-2. Furthermore, inflammatory mediators have been shown to alter the distribution of MMP-2. It has been proposed that degradation of TJ proteins by MMPs could increase endothelial permeability for a prolonged period; only following synthesis of new proteins could TJ integrity be recovered. Since MMP-9 is expressed weakly by endothelial cells in the absence of cytokines, MMP-linked, protein synthesis-independent changes in endothelial permeability have been attributed to activation of the constitutive MMP-2 [171]. BK-mediated increases in BBB permeability have been shown to be blocked by a combination of indomethacin (a COX inhibitor) and nor-
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dihydroguaiaretic acid (a 5-lipoxygenase inhibitor), and by superoxide dismutase and catalase (free radical scavengers). Therefore, it has been proposed that BK increases BBB permeability via a B 2 receptor-mediated mechanism involving activation of phospholipase A 2 , release of arachadonic acid, and production of free radicals [172]. Furthermore, the BK analogue RMP-7 has been shown to open the BBB to lanthanum in vivo by altering the integrity of endothelial tight junctions [173]. IFN-g treatment has been shown to produce upregulation of B 1 receptors on human brain endothelial cells; application of a B 1 agonist was shown to stimulate NO production, increase BBB permeability, and inhibit IL-8 release in vitro [174].
5.2. Effects of excitatory peptides and amino acids on the blood–brain barrier It has been proposed that SP possesses an immunomodulatory action at the BBB during inflammation and autoimmune disease. SP secretion has been observed in rat brain endothelial cells following stimulation by the proinflammatory cytokines IL-1b and TNF-a. Further, a portion of this SP has been found to bind to brain endothelial cells [175]. SP has been shown to stimulate translocation of PKC in bovine cerebral microvessels, indicating that this peptide may play a role in the regulation of BBB protein phosphorylation [176]. Additionally, receptors for CGRP, a peptide which has been shown to enhance the actions of SP by slowing its degradation [140], have been identified in human brain astrocytes and cerebromicrovascular endothelial cells [177], suggesting a possible role of this peptide in regulation of the BBB. Brain Glu concentrations in the intracellular space are higher than those in the extracellular space under normal conditions [178–180]. However, brain injury and disease have been shown to increase levels of extracellular Glu [178–183]. Glu has been shown to induce the synthesis of inflammatory mediators such as brain platelet-activating factor and NO in vivo [180,184]. Further, it has been proposed that disruption of the BBB may result from indirect actions of Glu, including induction of apoptosis in perivascular glia [183] or stimulation of NO production [180,184]. NO has been implicated in increased BBB permeability following application of Glu to cerebral
endothelial cells in vitro [180]. Additionally, leukocyte recruitment has been observed parallel to BBB breakdown following intracerebrally injected NMDA in adult and juvenile rats [185]. ‘‘Activated’’ PMNs have been shown to release Glu and upregulate expression of Glu receptors, resulting in decreased BBB function [148].
5.3. Effects of hypothalamic–pituitary–adrenal axis activation on the blood–brain barrier Emotional stress has been shown to precipitate or worsen several neuroinflammatory disorders [186] including relapsing-remitting multiple sclerosis [187–189]. Stress responses activate the HPA axis through release of CRH from the hypothalamus, resulting in production of glucocorticoids to downregulate the immune response [150]. It has been hypothesized that CRH released in acute stress either affects the BBB directly or via mast cell activation. Mast cells are found throughout the periphery and CNS and play a critical role in the development of allergic reactions [190]. Mast cells are thought to modulate BBB permeability since many mast cell mediators, including TNF-a and histamine, are vasoactive [191]. In fact, recent studies have shown that CRH has proinflammatory effects which are mediated via mast cell activation [192,193]. Furthermore, acute, non-traumatic stress has been shown to increase BBB permeability and activate mast cells [194], supporting the hypothesis that mast cell activation in response to stress influences BBB permeability.
6. Implications of pain responses in central nervous system drug delivery Painful and / or inflammatory conditions can be treated with a number of different classes of drugs, including anti-HIV drugs, antibiotics, opioid analgesics, antineoplastics, and antiepileptics. Pain and inflammatory mediators and their analogues have been shown to alter the function of the BBB. One consequence of BBB disruption has been shown to be increased drug delivery to the brain. This altered delivery may be detrimental in the case of drugs with narrow therapeutic ranges. On the other hand, in-
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creased delivery to the brain may be beneficial for targeting disorders within the CNS.
6.1. Influence of increased blood–brain barrier paracellular permeability on drug delivery to the brain The TJs of the BBB prevent passage of small, hydrophilic molecules from the blood to the brain. During pain or inflammation, however, TJ structure has been shown to be modified, resulting in increased BBB permeability. Increased delivery of drugs, a potential consequence of this increased permeability, may be beneficial or detrimental. Few studies have been performed concerning the relationship among pain mediators, BBB paracellular permeability, and drug delivery. Several key studies involve transport of the platinum chemotherapeutic agent cisplatin (CIS) across the BBB. Lipopolysaccharide (LPS) has been shown to decrease TEER in bovine cerebral endothelial cells, indicating an ‘‘opening’’ of intercellular tight junctions [195]. Under normal conditions, CIS does not readily cross the BBB due to its hydrophilicity [196]. However, LPS administration and subsequent production of inflammatory mediators have been shown to enhance platinum content in the cerebral cortex [197]. The disabling neurotoxicity that has been observed following CIS readministration [198] has therefore been attributed to increased transport of the drug across a compromised BBB [197], likely via paracellular diffusion. TNF-a, which has also been shown to decrease TEER in vitro [158], has been shown to increase CIS transport across bovine brain microvessel endothelial cells [199], providing further evidence that BBB disruption by inflammatory mediators plays a role in CIS delivery to the brain. In this study, it was proposed that combined administration of TNF-a and CIS could be clinically useful in patients with CNS tumors.
6.2. Influence of altered blood–brain barrier endocytosis on drug delivery to the brain The BBB restricts the entry of most proteins and large-molecular weight molecules into the brain. However, receptors on the surface of brain capillary endothelial cells play an important role in selective transport of substances such as TF (an iron-binding
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protein), insulin, and LDLs across the BBB via receptor-mediated endocytosis [40–43]. The TF receptor and its substrate have in fact been exploited for delivery of therapeutic agents to the CNS. Biotinylated basic fibroblast growth factor and brainderived neurotrophic factor, potent neuroprotective agents, have been delivered across the BBB via incorporation into a peptide drug delivery vector containing murine OX26, a monoclonal antibody against the rat TF receptor which undergoes receptor-mediated transport [200–202]. This delivery vector has also been utilized for delivery of antiAlzheimer’s and anti-HIV antisense molecules across the BBB [203]. TF itself has been utilized to carry therapeutic agents across the BBB; conjugation of nerve growth factor to TF via avidin / biotin technology has been shown to be as effective in transporting biotinylated therapeutics as OX26 [204]. Alterations in receptor-mediated endocytosis during neuropathological conditions could potentially influence the delivery of compounds such as insulin, therapeutic drug delivery vectors, or transferrinconjugated drugs across the BBB. It has been shown that the process of receptor-mediated endocytosis is altered during neuropathological conditions. Neurodegenerative diseases such as Parkinson’s disease and Alzheimer’s disease have been associated with increased levels of iron and oxidative stress in the brain [205–207]. It has been proposed that one of the causes of neuronal death in such diseases involves disruption in iron transport protein expression [208,209]. Inflammatory mediators have also been shown to influence receptor-mediated endocytosis in vitro. TNF-a has been shown to alter receptor-mediated endocytosis and transendothelial transport of LDLs and TF. These modifications, significant since both iron and lipids are essential for normal growth and function of brain cells, were proposed to be due to a change in intracellular traffic kinetics, since no increase in LDL or TF receptor expression was observed at the BBB [166].
6.3. Potential influence of altered blood–brain barrier efflux on drug delivery to the brain Membrane efflux pumps at the BBB, including P-gp, organic anion transporters, and MRP, limit penetration of drugs into the CNS by actively transporting them out of the brain. Drug efflux has
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been linked to multidrug resistance, which has been described as an acquired or intrinsic resistance to therapy, in a number of pathologies. Efflux transporter function at the BBB has been associated with minimal effectiveness of anti-HIV drugs on AIDS dementia, antibacterials on CNS infection, opioids on CNS-based pain, and chemotherapy on brain tumors [32]. BBB efflux of a number of drugs has been shown to be influenced by putative specific inhibitors of efflux transporters [210–213]. Increased multidrug resistance (MDR1) gene mRNA and P-gp protein expression have been observed in brain specimens taken from patients with medically intractable epilepsy [214]. Furthermore, increased efflux transporter expression has been observed in cultured rat brain endothelial cells subjected to the oxidative stress of ischemia / reperfusion [215]. The possibility of alterations in the expression and function of efflux transport proteins and the MDR1 gene at the BBB during pain or inflammation remains to be investigated. However, such alterations have been observed in other cell lines following stimulation with proinflammatory mediators [216–218].
6.4. Potential influence of pain-induced glutamate release on the delivery of glutamate-conjugated drugs to the brain Glutamate (Glu), a neurotransmitter present in large sensory fibers and nociceptive neurons [59], initiates excitatory neurotransmission in the CNS via activation of NMDA receptors [141–144]. ‘‘Activated’’ PMNs have been shown to release Glu and upregulate expression of Glu receptors, resulting in decreased BBB function [148]. Conjugation of the BBB-impermeable drug p-di(hydroxyethyl)-aminoD-phenylalanine (an analogue of the antitumor agent D-melphalan) to L-Glu has resulted in improved permeability of the drug in vitro and in vivo via the L-Glu transport system. 5,7-Dichlorokynurenic acid and its conjugates ( L-Glu, L-Asp, and L-Gln), on the other hand, have exhibited a low brain-to-plasma concentration ratio in vivo. Therefore, it has been suggested that facilitation of the delivery of nonpermeable conjugates across the BBB depends on their physicochemical and receptor-binding properties [219,220]. Alterations in delivery of L-Glu conjugates in a cancer model have not been investi-
gated and may be influenced by the release of endogenous Glu and / or alterations in L-Glu transporter expression or activity in response to cancerrelated pain. The presence of endogenous Glu may effectively reduce the dose of Glu-conjugated drug to reach the brain. Furthermore, possible pain-induced alterations in Glu transporter expression or activity could influence the dose of Glu-conjugated drug required to elicit a therapeutic effect.
6.5. Potential influence of pain-induced bradykinin release on the action of a bradykinin analogue at the blood–brain barrier An analogue of the inflammatory mediator BK has been designed to transiently increase the permeability of the BBB and the blood–brain tumor barrier (BBTB). Labradimil (LAB) (also known as Cereport or RMP-7) is a nine-amino-acid peptide which selectively binds to the bradykinin B 2 receptor. In vitro, LAB initiates BK-like second messenger cascades, including increases in intracellular Ca 21 and turnover of phosphatidylinositol. The mechanism of intravenous LAB has been shown to involve disengagement of the TJs of endothelial cells that make up the BBB [221]. Pharmacological opening of the BBB and BBTB via LAB administration has been shown to be clinically relevant in the treatment of gliomas using antineoplastic agents such as carboplatin [221– 224]. Alterations in delivery of LAB during cancer have not been investigated and may be influenced by the release of endogenous BK and / or alterations in B 2 receptor expression or activity due to cancerrelated pain. The presence of endogenous BK may effectively reduce the dose of LAB needed to transiently open BBB TJs; furthermore, possible pain-induced alterations in B 2 receptor expression or activity could influence the required dose of LAB.
7. Conclusions The BBB plays a critical role in maintaining cerebral homeostasis by separating the CNS from the periphery. In health, the BBB serves to control the passage of solutes into and out of the brain. During pathological insult, the BBB is capable of rapid
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modulation; in all but the most extreme cases, the BBB is able to ‘‘bend without breaking’’, or yield increased permeability while maintaining structural integrity. The structure and function of the BBB has been shown to be altered in a number of diseases with pain and / or inflammatory components. Evidence has shown that a number of mediators involved in the pain response, including cytokines, chemokines, cellular adhesion molecules, MMPs, kinins, PGs, excitatory molecules such as SP and Glu, and CRH, play roles in altering the cytoarchitecture and permeability of the BBB. Inflammatory mediators have also been shown to alter receptor-mediated endocytotic uptake at the BBB. Furthermore, the release of endogenous inflammatory mediators during pain could potentially influence the uptake of drugs meant to utilize specific transporters or activate receptors at the BBB. While little is known about the effects of pain mediators on efflux transporter expression and activity at the BBB, such alterations have been observed in epilepsy; efflux has been shown to be altered in other cell lines in response to proinflammatory mediators as well. Therefore, an understanding of alterations in drug efflux at the BBB during pain and / or inflammation may be of significant importance in predicting therapeutic outcomes. Increased drug delivery to the brain is a potential consequence of pain- and / or inflammation-induced BBB disruption. This altered delivery may be either detrimental (resulting in CNS toxicity) or beneficial (resulting in improved therapeutic outcome) based on the drug and its intended site of action. An understanding of BBB structural, functional, and transport alterations in pain and / or inflammation will result in new and more effective therapeutic approaches to treating disease.
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