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Acta Neuropathologica
Published in: Acta Neuropathologica 3/2011

Open Access 01-03-2011 | Review

Homeostatic regulation of the endoneurial microenvironment during development, aging and in response to trauma, disease and toxic insult

Authors: Andrew P. Mizisin, Ananda Weerasuriya

Published in: Acta Neuropathologica | Issue 3/2011

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Abstract

The endoneurial microenvironment, delimited by the endothelium of endoneurial vessels and a multi-layered ensheathing perineurium, is a specialized milieu intérieur within which axons, associated Schwann cells and other resident cells of peripheral nerves function. The endothelium and perineurium restricts as well as regulates exchange of material between the endoneurial microenvironment and the surrounding extracellular space and thus is more appropriately described as a blood–nerve interface (BNI) rather than a blood–nerve barrier (BNB). Input to and output from the endoneurial microenvironment occurs via blood–nerve exchange and convective endoneurial fluid flow driven by a proximo-distal hydrostatic pressure gradient. The independent regulation of the endothelial and perineurial components of the BNI during development, aging and in response to trauma is consistent with homeostatic regulation of the endoneurial microenvironment. Pathophysiological alterations of the endoneurium in experimental allergic neuritis (EAN), and diabetic and lead neuropathy are considered to be perturbations of endoneurial homeostasis. The interactions of Schwann cells, axons, macrophages, and mast cells via cell–cell and cell–matrix signaling regulate the permeability of this interface. A greater knowledge of the dynamic nature of tight junctions and the factors that induce and/or modulate these key elements of the BNI will increase our understanding of peripheral nerve disorders as well as stimulate the development of therapeutic strategies to treat these disorders.
Literature
1.
Abbott NJ (2000) Inflammatory mediators and modulation of blood–brain barrier permeability. Cell Mol Neurobiol 20:131–147PubMed
2.
Abbott NJ (2002) Astrocyte-endothelial interactions and blood–brain barrier permeability. J Anat 200:629–638PubMed
3.
Aguayo AJ, Charron L, Bray GM (1976) Potential of Schwann cells from unmyelinated nerves to produce myelin: a quantitative ultrastructural and autoradiographic study. J Neurocytol 5:565–573PubMed
4.
Aijaz S, Balda MS, Matter K (2006) Tight junctions: molecular architecture and function. Int Rev Cytol 248:261–298PubMed
5.
Allt G, Lawrenson JG (2000) The blood–nerve barrier: enzymes, transporters and receptors—a comparison with the blood–brain barrier. Brain Res Bull 52:1–12PubMed
6.
Arvidson B (1979) A study of the perineurial diffusion barrier of a peripheral ganglion. Acta Neuropathol 46:139–144PubMed
7.
Asbury AK, Arnason BGW, Adams RD (1969) The inflammatory lesion in idiopathic polyneuritis: its role in pathogenesis. Medicine 48:173–215PubMed
8.
Ask P, Levitan H, Robinson PJ, Rapoport SI (1983) Peripheral nerve as an osmometer: role of the perineurium in frog sciatic nerve. Am J Physiol 244:C75–C81PubMed
9.
Balda MS, Matter K (2008) Tight junctions at a glance. J Cell Sci 121:3677–3682PubMed
10.
Ballin RHM, Thomas PK (1968) Electron microscopic observations on demyelination and remyelination in allergic neuritis. I. Demyelination. J Neurol Sci 8:1–8
11.
Bell MA, Wedell AGM (1984) A morphometric study of intrafascicular vessels in mammalian sciatic nerve. Muscle Nerve 7:524–534PubMed
12.
Betz AL, Firth JA, Goldstein GW (1980) Polarity of the blood–brain barrier: distribution of enzymes between the luminal and antiluminal membranes of brain capillary endothelial cells. Brain Res 193:17–28
13.
Boddingius J (1984) Ultrastructural and histophysiological studies on the blood–nerve barrier and perineurial barrier in leprosy neuropathy. Acta Neuropathol 64:282–296PubMed
14.
Bradley WG, Asbury AK (1970) Duration of synthesis phase in neurilemmal cells in mouse sciatic nerve during degeneration. Exp Neurol 26:275–282PubMed
15.
Brown WF, Feasby TE (1984) Conduction block and denervation in Guillain–Barre polyneuropathy. Brain 107:219–239PubMed
16.
Brownlee M, Vlassara H, Cerami A (1986) Trapped immunoglobulins on peripheral nerve myelin from patients with diabetes mellitus. Diabetes 35:999–1003PubMed
17.
Bundgaard M, Frokjaer-Jensen J (1982) Functional aspects of the ultrastructure of terminal blood vessels: a quantitative study on consecutive segments of the frog mesenteric microvasculature. Microvasc Res 23:1–30PubMed
18.
Bunge MB, Wood PM, Tynan LB, Bates ML, Sanes JR (1989) Perineurium originates from fibroblasts: demonstration in vitro with a retroviral marker. Science 243:229–231PubMed
19.
Burkel WE (1967) The histological fine structure of perineurium. Anat Rec 158:177–190PubMed
20.
Calcutt NA, Allendorfer KL, Mizisin AP et al (2003) Therapeutic efficacy of sonic hedgehog protein in experimental diabetic neuropathy. J Clin Invest 111:507–514PubMed
21.
Choi YK, Kim K-W (2008) Blood-neural barrier: its diversity ad coordinated cell-to-cell communication. BMB Rep 41:345–352PubMed
22.
Crone C, Levitt DG (1984) Capillary permeability to small solutes. In: Renkin EM, Michel CC (eds). Handbook of physiology. The cardiovascular system, vol 4. Microcirculation. American Physiological Society, Bethesda, pp 411–466
23.
Crowley NR, Nelson SL, Weerasuriya A, Black AC (1996) Endoneurial hydrostatic pressure in rat sciatic nerve during development. Soc Neurosci Abstr 22:772
24.
Dyck PJ, Karnes J, Lais A, Lofgren EP, Stevens JC (1984) Pathologic alterations of the peripheral nervous system of humans. In: Dyck PJ, Thomas PK, Lambert EH, Bunge R (eds) Peripheral neuropathy. WB Saunders, Philadelphia, pp 760–870
25.
Dyck PJ, Windebank AJ, Low PA, Baumann WJ (1980) Blood–nerve barrier in rat and cellular mechanisms of lead-induced segmental demyelination. J Neuropathol Exp Neurol 139:700–709
26.
Eaton RP, Qualls C, Bicknell J, Sibbitt WL Jr, King MM, Griffey RH (1996) Structure-function relationships within peripheral nerves in diabetic neuropathy: the hydration hypothesis. Diabetologia 39:439–446PubMed
27.
Enerback L, Olsson Y, Sourander P (1965) Mast cells in normal and sectioned peripheral nerve. Z Zellforsch 66:596–608
28.
Farquhar MG, Palade GE (1963) Junctional complexes in various epithelia. J Cell Biol 17:375–412PubMed
29.
Feasby TE, Gilbert JJ, Brown WF et al (1986) An acute axonal form of Guillain–Barre polyneuropathy. Brain 109:1115–1126PubMed
30.
Forcier NJ, Mizisin AP, Rimmer MA, Powell HC (1991) Cellular pathology of the nerve microenvironment in galactose intoxication. J Neuropathol Exp Neurol 50:235–255PubMed
31.
Fraher JP (1999) The transitional zone and CNS regeneration. J Anat 194:161–182PubMed
32.
Froehner SC, Davies A, Baldwin SA, Lienhard GE (1988) The blood–nerve barrier is rich in glucose transporter. J Neurocytol 17:173–178PubMed
33.
Gerhart DZ, Drewes LR (1990) Glucose transporters at the blood–nerve barrier are associated with perineurial cells and endoneurial microvessels. Brain Res 508:46–50PubMed
34.
Goyer RA (1971) Lead toxicity: a problem of environmental pathology. Am J Pathol 64:167–182PubMed
35.
Graham AR, Johnson PC (1985) Direct immunofluorescence findings in peripheral nerve from patients with diabetic neuropathy. Ann Neurol 17:450–454PubMed
36.
Griffey RH, Eaton RP, Gasparovic C, Sibbitt W (1987) Galactose neuropathy. Structural changes evaluated by nuclear magnetic resonance spectroscopy. Diabetes 36:776–778PubMed
37.
Griffey RH, Eaton RP, Sibbitt WL Jr, Bicknell JM (1988) Diabetic neuropathy. Structural analysis of nerve hydration by magnetic resonance spectroscopy. JAMA 18:2872–2878
38.
Griffin JW (2001) Vasculitic neuropathies. Rheum Dis Clin North Am 27:751–760PubMed
39.
Grotte G (1956) Passage of dextran molecules across the blood–lymph barrier. Acta Chir Scand Suppl 211:1–84PubMed
40.
Hahn AF, Feasby TE, Steele A, Lovgren DS, Berry J (1988) Demyelination and axonal regeneration in Lewis rat experimental allergic neuritis depend on myelin dosage. Lab Invest 59:115–125PubMed
41.
Haller FR, Low FN (1971) The fine structure of the peripheral nerve root sheath in the subarachnoid space in the rat and other laboratory animals. Am J Anat 131:1–19PubMed
42.
Haller FR, Haller C, Low FN (1972) The fine structure of cellular layers and connective tissue space at spinal nerve root attachment in the rat. Am J Anat 133:109–123PubMed
43.
Hartung HP, Toyka KV (1990) T cell and macrophage activation in experimental autoimmune neuritis and Guillain–Barre syndrome. Ann Neurol 27:S57–S63PubMed
44.
Hirakawa H, Okajima S, Nagaoka T, Takamatsu T, Oyamada M (2003) Loss and recovery of the blood–nerve barrier in the rat sciatic nerve after crush injury are associated with expression of intercellular junctional proteins. Exp Cell Res 284:196–210PubMed
45.
Jacobs JM, Macfarlane RM, Cavanagh JB (1976) Vascular leakage in the dorsal root ganglia of the rat studied with horseradish peroxidase. J Neurol Sci 29:95–107PubMed
46.
Jakobsen J (1978) Peripheral nerve in early experimental diabetes: expansion of the endoneurial space as a cause of increased water content. Diabetologia 14:113–119PubMed
47.
Jakobsen J, Malmgren L, Olsson Y (1978) Permeability of the blood–brain barrier in the streptozotocin-diabetic rat. Exp Neurol 60:277–285PubMed
48.
Jessen KR, Mirsky R (1999) Schwann cells and their precursors emerge as major regulators of nerve development. TINS 22:402–410PubMed
49.
Jessen KR, Mirsky R, Morgan L (1987) Axonal signals regulate the differentiation of non-myelin-forming Schwann cells: an immunohistochemical study of galactocerebroside in transected and degenerating nerves. J Neurosci 7:3362–3369PubMed
50.
Jiang Y, Calcutt NA, Ramos KM, Mizisin AP (2006) Novel sites of aldose reductase immunolocalization in normal and streptozotocin-diabetic rats. J Peripher Nerv Syst 11:274–285PubMed
51.
Johnson PC (1983) Thickening of the human dorsal root ganglion perineurial cell basement membrane in diabetes mellitus. Muscle Nerve 6:561–565PubMed
52.
Kalichman MW, Myers RR (1991) Transperineurial vessel constriction in an edematous neuropathy. J Neuropathol Exp Neurol 50:408–418PubMed
53.
Kalichman MW, Powell HC, Calcutt NA, Mizisin AP (1995) Mast cell degranulation and blood–nerve barrier permeability in rat sciatic nerve after 7 days of hyperglycemia. Am J Physiol 268:H740–H748PubMed
54.
Kanda T, Numata Y, Mizusawa H (2004) Chronic inflammatory demyelinating polyneuropathy: decreased claudin-5 and relocated ZO-1. J Neurol Neurosurg Psychiatry 75:765–769PubMed
55.
Kandel ER, Schwartz JH, Jessell TM (2000) Principles of neural science, 4th edn. McGraw-Hill, New York
56.
Karnovsky MJ (1970) Morphology of capillaries with special reference to muscle capillaries. In: Crone C, Lassen NA (eds) Capillary permeability. Munksgaard, Copenhagen, pp 341–350
57.
Kido Y, Yamai I, Okamoto M, Susuki F, Tsuji A (2000) Functional clarification of MCT1-mediated transport of monocarboxylic acids at the blood–brain barrier using in vitro cultured cells and in vivo BUI studies. Pharm Res 17:55–62PubMed
58.
Kihara M, Schmelzer JD, Poduslo JF, Curran GL, Nickander KK, Low PA (1991) Aminoguanidine effects on nerve blood flow, vascular permeability, electrophysiology, and oxygen free radicals. Proc Natl Acad Sci USA 88:6107–6111PubMed
59.
King RHM, Llewelyn JG, Thomas PK, Gilbey SG, Watkins PJ (1989) Diabetic neuropathy: abnormalities of Schwann cell and perineurial basal laminae. Implications for diabetic vasculopathy. Neuropathol Appl Neurobiol 15:339–355PubMed
60.
Krinke G, Schaumberg HH, Spencer PS, Suter J, Thomann P, Hess R (1981) Pyridoxine megavitimanosis produces degeneration of peripheral sensory neurons (sensory neuronopathy) in the dog. Neurotoxicology 2:13–24PubMed
61.
Kristensson K, Olsson Y (1971) The perineurium as a diffusion barrier to protein tracers: differences between mature and immature animals. Acta Neuropathol 17:127–138PubMed
62.
Krnjevic K (1954) Some observations on perfused frog sciatic nerves. J Physiol 123:338–356PubMed
63.
Krnjevic K (1955) The distribution of Na and K in cat nerves. J Physiol 128:473–488PubMed
64.
Lampert PW (1969) Mechanisms of demyelination in experimental allergic neuritis: electron microscopic studies. Lab Invest 20:127–138PubMed
65.
Landis EM, Pappenheimer JR (1963) Exchange of substances through the capillary wall. In: Hamilton WF, Dow P (eds) Handbook of physiology, Circulation, section 2, vol II. American Physiological Society, Washington DC, pp 961–1034
66.
Latker CH, Wadhwani KC, Balbo A, Rapoport SI (1991) Blood–nerve barrier in the frog during Wallerian degeneration: are axons necessary for maintenance of barrier function? J Comp Neurol 309:650–664
67.
Lo EH, Broderick JP, Moskowitz MA (2004) tPA and proteolysis in the neurovascular unit. Stroke 35:354–356PubMed
68.
Lok J, Gupta P, Guo S et al (2007) Cell-cell signaling in the neurovascular unit. Neurochem Res 32:2032–2045PubMed
69.
Low FN (1976) The perineurium and connective tissue of peripheral nerve. In: Landon DN (ed) The peripheral nerve. Chapman and Hall, London, pp 159–187
70.
Low PA (1981) In vitro study of acute elevations of endoneurial pressure in mammalian peripheral nerve sheath. Exp Neurol 74:160–169PubMed
71.
Low PA (1985) Endoneurial potassium is increased and enhances spontaneous activity in regenerating mammalian nerve fibers. Implications for neuropathic positive symptoms. Muscle Nerve 8:27–33PubMed
72.
Low PA, Dyck PJ (1977) Increased endoneurial fluid pressure in experimental lead neuropathy. Nature 269:427–428PubMed
73.
Low PA, Dyck PJ, Schmelzer JD (1982) Chronic elevation of endoneurial fluid pressure is associated with low-grade fiber pathology. Muscle Nerve 5:162–165PubMed
74.
Low PA, Marchand G, Knox F, Dyck PJ (1977) Measurement of endoneurial fluid pressure with polyethylene matrix capsule. Brain Res 122:373–377PubMed
75.
Low PA, Tuck RR (1984) Effects of changes in blood pressure, respiratory acidosis and hypoxia on blood flow in the sciatic nerve of the rat. J Physiol 347:513–524PubMed
76.
Lundborg G (1988) Nerve injury and repair. Churchill Livingstone, Edinburgh
77.
Mackenzie ML, Ghabriel MN, Allt G (1987) The blood–nerve barrier: an in vivo lanthanum tracer study. J Anat 154:27–37PubMed
78.
Madrid RE, Wisniewski HM (1977) Axonal degeneration in demyelinating disorders. J Neurocytol 6:103–117PubMed
79.
Magnani P, Cherian PV, Gould GW, Greene DA, Sima AA, Brosius FF III (1996) Glucose transporters in rat peripheral nerve: paranodal expression of GLUT1 and GLUT3. Metabolism 45:1466–1473PubMed
80.
Malinovsky L (1996) Sensory nerve formations in the skin and their classification. Microsc Res Tech 34:283–301PubMed
81.
McCabe JS, Low FN (1969) The subarachnoid angle: an area of transition in peripheral nerve. Anat Rec 164:15–33PubMed
82.
Mellick RS, Cavanagh JB (1967) Longitudinal movement of radio-iodinated albumin within extravascular spaces of peripheral nerves following three systems of trauma. J Neurol Neurosurg Psychiatry 30:458–463PubMed
83.
Meyer J, Mischeck U, Veyhl M, Henzel K, Galla H-J (1990) Blood–brain barrier characteristic enzymatic properties in cultured brain capillary endothelial cells. Brain Res 514:305–309PubMed
84.
Mizisin AP, Kalichman MW (1993) Permeability and surface area of the blood–nerve barrier in galactose intoxication. Brain Res 618:109–114PubMed
85.
Mizisin AP, Kalichman MW, Calcutt NA, Myers RR, Powell HC (1993) Decreased endoneurial fluid electrolytes in normal rat sciatic nerve after aldose reductase inhibition. J Neurol Sci 116:67–72PubMed
86.
Mizisin AP, Kalichman MW, Myers RR, Powell HC (1990) Role of the blood–nerve barrier in experimental nerve edema. Toxicol Pathol 18:170–185PubMed
87.
Mizisin AP, Myers RR, Heckman HM, Powell HC (1988) Dose-dependence of endoneurial fluid sodium and chloride accumulation in galactose intoxication. J Neurol Sci 86:113–124PubMed
88.
Mizisin AP, Powell HC (1993) Schwann cell injury is attenuated by aldose reductase inhibition in galactose intoxication. J Neuropathol Exp Neurol 52:78–86PubMed
89.
Mizisin AP, Powell HC (2003) Diabetic peripheral neuropathy. In: Gries FA, Cameron NE, Low PA, Ziegler D (eds) Textbook of diabetic neuropathy. Thieme, Stuttgart, pp 83–87
90.
Mizisin AP, Powell HC, Myers RR (1986) Edema and increased endoneurial sodium in galactose neuropathy. Reversal with an aldose reductase inhibitor. J Neurol Sci 74:35–43PubMed
91.
Mizisin AP, Powell HC, Myers RR (1986) Endoneurial sodium accumulation in galactosemic rat nerves. Muscle Nerve 9:440–444PubMed
92.
Myers RR, Heckman HM, Powell HC (1983) Endoneurial fluid in hypertonic. J Neuropathol Exp Neurol 42:217–224PubMed
93.
Myers RR, James HC, Powell HC (1985) Laser injury of peripheral nerve: a model for focal endoneurial damage. J Neurol Neurosurg Psychiatry 48:1265–1268PubMed
94.
Myers RR, Mizisin AP, Powell HC, Lampert PW (1982) Reduced nerve blood flow in hexachlorophene neuropathy. Relationship to elevated endoneurial fluid pressure. J Neuropathol Exp Neurol 41:391–399PubMed
95.
Myers RR, Murakami H, Powell HC (1986) Reduced nerve blood flow in edematous neuropathies—a biochemical mechanism. Microvasc Res 32:145–151PubMed
96.
Myers RR, Powell HC (1984) Galactose neuropathy: impact of chronic endoneurial edema on nerve blood flow. Ann Neurol 16:587–594PubMed
97.
Myers RR, Powell HC, Costello ML, Lampert PW, Zweifach BW (1978) Endoneurial fluid pressure: direct measurement with micropipettes. Brain Res 148:510–515PubMed
98.
Myers RR, Powell HC, Heckman HM, Costello ML, Katz J (1981) Biophysical and pathological effects of cryogenic nerve lesion. Ann Neurol 10:478–485PubMed
99.
Myers RR, Powell HC, Shapiro HM, Costello ML, Lampert PW (1980) Changes in endoneurial fluid pressure, permeability and peripheral nerve ultrastructure in experimental lead neuropathy. Ann Neurol 8:392–401PubMed
100.
Myers RR, Rydevik BL, Heckman HM, Powell HC (1988) Proximo-distal gradient in endoneurial fluid pressure. Exp Neurol 102:368–370PubMed
101.
Ohi T, Poduslo JF, Curran GL, Dyck PJ (1985) Quantitative methods for detection of blood–nerve barrier alterations in experimental animal models of neuropathy. Exp Neurol 90:365–372PubMed
102.
Ohara S, Ikuta F (1985) On the occurrence of the fenestrated vessels in Wallerian degeneration of the peripheral nerve. Acta Neuropathol 68:259–262PubMed
103.
Ohi T, Poduslo JF, Dyck PJ (1985) Increased endoneurial albumin in diabetic polyneuropathy. Neurology 35:1790–1791PubMed
104.
Ohtsuki S, Tachikawa M, Takanaga H et al (2002) The blood–brain carrier creatine transporter is a major pathway for supplying creatine to the brain. J Cereb Blood Flow Metab 22:1327–1335PubMed
105.
Olsson Y (1966) Studies on vascular permeability in peripheral nerve. I. Distribution of circulating fluorescent serum albumin in normal, crushed and sectioned rat sciatic nerve. Acta Neuropathol 7:1–15PubMed
106.
Olsson Y (1968) Topographical differences in the vascular permeability of the peripheral nervous system. Acta Neuropathol 10:26–33PubMed
107.
Olsson Y (1984) Vascular permeability in the peripheral nervous system. In: Dyck PJ, Thomas PK, Lambert EH, Bunge R (eds) Peripheral neuropathy, 2nd edn. Saunders, Philadelphia, pp 579–597
108.
Olsson Y (1990) Microenvironment of the peripheral nervous system under normal and pathological conditions. Critical Rev Neurobiol 5:265–311
109.
Olsson Y, Kristensson K (1971) Permeability of blood vessels and connective tissue sheaths in the peripheral nervous system to exogenous proteins. Acta Neuropathol 5(Suppl 5):61–69PubMed
110.
Olsson Y, Reese TS (1971) Permeability of vasa nervorum and perineurium in mouse sciatic nerve studied by fluorescence and electron microscopy. J Neuropathol Exp Neurol 30:105–119PubMed
111.
Orte C, Lawrenson JG, Finn TM, Reid AR, Allt G (1999) A comparison of blood–brain barrier and blood–nerve barrier endothelial cell markers. Anat Embryol 199:509–517PubMed
112.
Pappenheimer JR (1953) Passage of molecules through capillary walls. Physiol Rev 33:387–423PubMed
113.
Parmantier E, Lynn B, Lawson D et al (1999) Schwann cell-derived desert hedgehog controls the development of peripheral nerve sheaths. Neuron 23:713–724PubMed
114.
Pellegrino RG, Politis MJ, Ritchie JM, Spencer PS (1986) Events in degenerating cat peripheral nerve: induction of Schwann cell S phase and its relation to nerve fiber degeneration. J Neurocytol 15:17–28PubMed
115.
Peters A, Palay SL, DeF Webster H (1991) The fine structure of the nervous system. Oxford University Press, New York, pp 384–394
116.
Peters T (1975) Serum albumin. In: Putnam FW (ed) The plasma proteins. Academic Press, New York, pp 131–181
117.
Poduslo JF, Curran GL (1992) Increased permeability across the blood–nerve barrier of albumin glycated in vitro and in vivo from patients with diabetic polyneuropathy. Proc Natl Acad Sci USA 89:2218–2222PubMed
118.
Poduslo JF, Curran GL, Dyck PJ (1988) Increase in albumin, IgG and IgM blood–nerve barrier indices in human diabetic neuropathy. Proc Natl Acad Sci USA 88:4879–4883
119.
Poduslo JF, Dyck PJ, Berg CT (1985) Regulation of myelination: Schwann cell transition from a myelin-maintaining state to a quiescent state after permanent nerve transection. J Neurochem 44:388–400PubMed
120.
Poduslo JF, Low PA, Nickander KK, Dyck PJ (1985) Mammalian endoneurial fluid: collection and protein analysis from normal and crushed nerves. Brain Res 332:91–102PubMed
121.
Polydefkis M, Griffin JW, McArthur J (2003) New insights into diabetic polyneuropathy. JAMA 290:1371–1376PubMed
122.
Powell DW (1981) Barrier function of epithelia. Am J Physiol 241:G275–G288PubMed
123.
Powell HC, Braheny SL, Myers RR, Rodriguez M, Lampert PW (1983) Early changes in experimental allergic neuritis. Lab Invest 48:332–338PubMed
124.
Powell HC, Costello ML, Myers RR (1981) Galactose neuropathy. Permeability studies, mechanism of edema, and mast cell abnormalities. Acta Neuropathol 55:89–95PubMed
125.
Powell HC, Garrett RS, Kador PF, Mizisin AP (1991) Fine-structural localization of aldose reductase and oubain-sensitive, K+-dependent p-nitro-phenylphosphatase in rat peripheral nerve. Acta Neuropathol 81:529–539PubMed
126.
Powell HC, Myers RR (1989) The blood–nerve barrier and the pathological significance of nerve edema. In: Neuwelt EA (ed) Implications of the blood–brain barrier and its manipulation, vol 1. Plenum Press, New York, pp 199–212
127.
Powell HC, Myers RR (2004) Impact of inflammatory disease on the nerve microenvironment. J Neurol Sci 220:131–132PubMed
128.
Powell HC, Myers RR, Costello ML (1980) Increased endoneurial fluid pressure following injection of histamine and compound 48/80 into rat peripheral nerves. Lab Invest 43:564–572PubMed
129.
Powell HC, Myers RR, Costello ML, Lampert PW (1979) Endoneurial fluid pressure in Wallerian degeneration. Ann Neurol 5:550–557PubMed
130.
Powell HC, Myers RR, Lampert PW (1982) Changes in Schwann cells and vessels in lead neuropathy. Am J Pathol 109:193–205PubMed
131.
Powell HC, Myers RR, Mizisin AP, Olle T, Brostoff SW (1991) Response of the axon and barrier endothelium to experimental allergic neuritis induced by autoreactive T cell lines. Acta Neuropathol 82:364–377PubMed
132.
Powell HC, Olee T, Brostoff SW, Mizisin AP (1991) Comparative histology of experimental allergic neuritis induced with minimum length neuritogenic peptides by adoptive transfer with sensitized cells or direct sensitization. J Neuropathol Exp Neurol 50:658–674PubMed
133.
Prineas JW, Spencer PS (1975) Pathology of the nerve cell body in disorders of the peripheral nervous system. In: Dyck PJ, Thomas PK, Lambert EH (eds) Peripheral neuropathy. Saunders, Philadelphia, pp 253–295
134.
Pummi KP, Heape AM, Grenman RA, Peltonen JTK, Peltonen SA (2004) Tight junction proteins ZO-1, occluding, and claudins in developing and adult human perineurium. J Histochem Cytochem 52:1037–1046PubMed
135.
Rapoport SI (1976) Blood–brain barrier in physiology and medicine. Raven Press, New York
136.
Rechthand E, Smith QR, Latker CH, Rapoport SI (1987) Altered blood–nerve barrier permeability to small molecules in experimental diabetes mellitus. J Neuropathol Exp Neurol 46:302–314PubMed
137.
Rechthand E, Smith QR, Rapoport SI (1985) Facilitated transport of glucose from blood into peripheral nerve. J Neurochem 45:957–964PubMed
138.
Rechthand E, Smith QR, Rapoport SI (1987) Transfer of nonelectrolytes from blood into peripheral nerve endoneurium. Am J Physiol 252:H1175–H1182PubMed
139.
Renkin EM (1977) Multiple pathways of capillary permeability. Circ Res 41:735–743PubMed
140.
Rippe B, Haraldsson B (1987) How are macromolecules transported across the capillary wall? News Physiol Sci 2:135–138
141.
Ross MH, Reith EJ (1969) Perineurium: evidence for contractile elements. Science 165:604–605PubMed
142.
Rossiter RJ (1961) The chemistry of Wallerian degeneration. In: Folch-Pi J (ed) Chemical pathology of the nervous system. Pergamon Press, New York, pp 207–227
143.
Rubenstein A, Arbit E (1990) Spinal cord blood flow in the rat under normal physiological conditions. Neurosurgery 27:882–886
144.
Rundquist I, Smith QR, Michael ME, Ask P, Oberg PA, Rapoport SI (1985) Sciatic nerve blood flow measured by laser Doppler flowmetry and [14C] iodoantipyrine. Am J Physiol 248:H311–H317PubMed
145.
Said G, Slama G, Selva J (1983) Progressive centripetal degeneration of axons in small fiber type diabetic polyneuropathy. A clinical and pathological study. Brain 106:791–807PubMed
146.
Saida K, Kawakami H, Ohta M, Iwamura K (1997) Coagulation and vascular abnormalities in Crow-Fukase syndrome. Muscle Nerve 20:486–492PubMed
147.
Saito T, Zhang Z, Ohtsubo T et al (2001) Homozygous disruption of the mdr1a p-glycoprotein gene affects blood–nerve barrier function in mice administered with neurotoxic drugs. Acta Otolaryngol 121:735–742PubMed
148.
Sano Y, Shimuzu F, Nakayama H et al (2007) Endothelial cells constituting blood–nerve barrier have highly specialized characteristics as barrier-forming cells. Cell Struct Funct 32:139–147PubMed
149.
Sasaki H, Schmelzer JD, Zollman PJ, Low PA (1997) Neuropathology and blood flow of nerve, spinal roots and dorsal root ganglia in longstanding diabetic rats. Acta Neuropathol 93:118–128PubMed
150.
Schmelzer JD, Low PA (1988) The effects of hyperbaric oxygenation and hypoxia on the blood–nerve barrier. Brain Res 473:321–326PubMed
151.
Seneviratne KN (1972) Permeability of blood–nerve barriers in the diabetic rat. J Neurol Neurosurg Psychiatry 35:156–162PubMed
152.
Shanthaveerappa TS, Bourne GH (1962) The ‘perineurial epithelium’, a metabolically active, continuous, protoplasmic cell barrier surrounding peripheral nerve fasciculi. J Anat 96:527–537PubMed
153.
Shanthaveerappa TS, Bourne GH (1966) Perineurial epithelium: a new concept of its role in the integrity of the peripheral nervous system. Science 154:1464–1467PubMed
154.
Sharghi-Namini S, Turmaine M, Meier C et al (2006) The structural and functional integrity of peripheral nerves depends on the glial-derived signal desert hedgehog. J Neurosci 26:6364–6376PubMed
155.
Shelton KR, Egle PM (1982) The proteins of lead-induced intranuclear inclusion bodies. J Biol Chem 257:11802–11807PubMed
156.
Shimizu F, Yasuteru S, Masa-aki A et al (2010) Peripheral nerve pericytes modify the blood–nerve barrier function and tight junctional molecules through the secretion of various soluble factors. J Cell Physiol. doi:10.​1002/​jcp.​22337
157.
Shinowara NL, Michel ME, Rapoport SI (1982) Morphological correlates of permeability in the frog perineurium: vesicles and transcellular channels. Cell Tissue Res 227:11–22PubMed
158.
Sima AAF, Hay K (1981) Functional aspects and pathogenetic considerations of the neuropathy in the spontaneously diabetic BB-Wistar rat. Neuropathol Appl Neurobiol 7:341–350PubMed
159.
Sima AAF, Robertson DM (1978) The perineurial and blood–nerve barriers in experimental diabetes. Acta Neuropathol 44:189–195PubMed
160.
Smith CE, Atchabahian A, Mackinnon SE, Hunter DA (2001) Development of the blood–nerve barrier in neonatal rats. Microsurgery 21:290–297PubMed
161.
Smith ME, Jones TA, Hilton D (1998) Vascular endothelial cadherin is expressed by perineurial cells of peripheral nerve. Histopathology 32:411–413PubMed
162.
Soderfeldt B (1974) The perineurium as a diffusion barrier to protein tracers. Influence of histamine, serotonine and bradykinine. Acta Neuropathol 27:55–60PubMed
163.
Spencer PS, Weinberg HJ, Raines CS (1975) The perineurial window—a new model of focal demyelination and remyelination. Brain Res 96:323–329PubMed
164.
165.
Stoll G, Griffin JW, Li CY, Trapp BD (1989) Wallerian degeneration in the peripheral nervous system: participation of both Schwann cells and macrophages in myelin degradation. J Neurocytol 18:671–683PubMed
166.
Stoll G, Jander S, Myers RR (2002) Degeneration and regeneration in the peripheral nervous system: from August Waller’s observation on neuroinflammation. J Peripher Nerv Syst 7:13–27PubMed
167.
Stoll G, Trapp BD, Griffin JW (1989) Macrophage function during Wallerian degeneration of rat optic nerve: clearance of degenerating myelin and Ia expression. J Neurosci 9:2327–2335PubMed
168.
Sunderland S (1946) The effect of rupture of the perineurium on the contained nerve fibres. Brain 69:149–152PubMed
169.
Sunderland S (1978) Nerves and nerve injury. Churchill Livingstone, Edinburgh
170.
Tamara A, Asano T, Sano K (1978) Measurement of spinal cord blood flow in rabbits: central gray matter flow and CO2 reactivity. No To Shinkei 30:383–386
171.
Taylor AE, Granger DN (1984) Exchange of macromolecules across the microcirculation. In: Renkin EM, Michel CC (eds). Handbook of physiology, section 2, The cardiovascular system, vol 4, Microcirculation. American Physiological Society, Bethesda, pp 467–520
172.
Terry S, Nie M, Matter K, Balda MS (2010) Rho signaling and tight junction functions. Physiology 25:16–26PubMed
173.
Thomas PK, Bhagat S (1978) The effect of extraction of the intrafascicular contents of peripheral nerve trunks on perineurial structure. Acta Neuropathol 43:135–141PubMed
174.
Tsao JW, George EB, Griffin JW (1999) Temperature modulation reveals three distinct stages of Wallerian degeneration. J Neurosci 19:4718–4726PubMed
175.
Tserentsoodol N, Shin BC, Koyama H, Suzuki T, Takata K (1999) Immunolocalization of tight junction proteins, occludin and ZO-1, and GLUT1 in the cells of the blood–nerve barrier. Arch Histol Cytol 62:459–469PubMed
176.
Vorbrodt AW, Dobrogowska DH, Lossinsky AS (1994) Ultracytochemical studies of the effects of aluminum on the blood–brain barrier of mice. J Histochem Cytochem 42:203–212PubMed
177.
Wadhwani KC, Casper-Velu LE, Murphy VA, Smith QR, Kador PF, Rapoport SI (1989) Prevention of nerve edema and increased blood–nerve barrier permeability-surface area product in galactosemic rats by aldose reductase or thromboxane synthesis inhibitors. Diabetes 38:1469–1477PubMed
178.
Wadhwani KC, Koistinaho J, Balbo A, Rapoport SI (1991) Blood–nerve and blood–brain barrier permeabilities and nerve vascular space in Fischer-344 rats of different ages. Mech Ageing Dev 58:177–190PubMed
179.
Wadhwani KC, Latker CH, Balbo A, Rapoport SI (1989) Perineurial permeability and endoneurial edema during Wallerian degeneration of the frog peripheral nerve. Brain Res 493:231–239PubMed
180.
Waxman BH, Adams RD (1955) Allergic neuritis: experimental disease of rabbits induced by the injection of peripheral nervous tissue and adjuvants. J Exp Med 102:213–236
181.
Weber C, Fraemohs L, Dejana E (2007) The role of junctional adhesion molecules in vascular inflammation. Nat Rev Immunol 7:467–477PubMed
182.
Weerasuriya A (1987) Permeability of endoneurial capillaries to K, Na, and Cl and its relation to peripheral nerve excitability. Brain Res 419:188–196PubMed
183.
Weerasuriya A (1988) Patterns of change in endoneurial capillary permeability and vascular space during Wallerian degeneration. Brain Res 445:181–187PubMed
184.
Weerasuriya A (1990) Permeabilities of endoneurial capillaries and perineurium of rat sciatic nerve to 22Na during development. Physiologist 33:A-100
185.
Weerasuriya A (1993) Changes in the permeability coefficient - surface area product (PS) of the blood–nerve interface (BNI) to sodium in degenerating and regenerating rat sciatic nerve. 11th Biennial Meeting of the Peripheral Nerve Study Group, Aachen, Germany
186.
Weerasuriya A (2005) Blood–nerve interface and endoneurial homeostasis. In: Dyck PJ, Thomas PK (eds) Peripheral neuropathy, 4th edn. Elsevier, New York, pp 651–665
187.
Weerasuriya A, Coath G, Crowley N (1996) Endoneurial Na concentration and hydrostatic pressure in galactose neuropathy. FASEB J 10:A764
188.
Weerasuriya A, Curran GL, Poduslo JF (1989) Blood–nerve transfer of albumin and its implications for the endoneurial microenvironment. Brain Res 494:114–121PubMed
189.
Weerasuriya A, Curran GL, Poduslo JF (1990) Developmental changes in blood–nerve transfer of albumin and endoneurial albumin content in rat sciatic nerve. Brain Res 521:40–46PubMed
190.
Weerasuriya A, Curran GL, Poduslo JF (1990) Physiological changes in the sciatic nerve endoneurium of lead intoxicated rats: a model of endoneurial homeostasis. Brain Res 517:1–6PubMed
191.
Weerasuriya A, Hockman CH (1992) Perineurial permeability to sodium during Wallerian degeneration in rat sciatic nerve. Brain Res 581:327–333PubMed
192.
Weerasuriya A, Nelson SL, Crowley NR (1998) Evidence for endoneurial fluid flow from endoneurial hydrostatic pressure measurements in transected and crushed rat sciatic nerves. Soc Neurosci Abstr 24:267
193.
Weerasuriya A, Rapoport SI (1986) Endoneurial capillary permeability to [14C] sucrose in frog sciatic nerve. Brain Res 375:150–156PubMed
194.
Weerasuriya A, Rapoport SI, Taylor RE (1979) Modification of permeability of frog perineurium to [14C] sucrose by stretch and hypertonicity. Brain Res 173:503–512PubMed
195.
Weerasuriya A, Rapoport SI, Taylor RE (1980) Ionic permeabilities of the frog perineurium. Brain Res 191:405–415PubMed
196.
Weerasuriya A, Rapoport SI, Taylor RE (1980) Perineurial permeability increases during Wallerian degeneration. Brain Res 192:581–585PubMed
197.
Weiss P, Wang H, Taylor AC, Edds MV (1945) Proximo-distal fluid convection in the endoneurial spaces of peripheral nerves, demonstrated by colored and radioactive (isotope) tracers. Am J Physiol 143:521–540
198.
Williams PL, Hall SM (1971) Chronic Wallerian degeneration—an in vivo and ultrastructural study. J Anat 109:487–503PubMed
199.
Willison HJ (2005) The immunobiology of Guillain–Barre syndromes. J Peripher Nerv Syst 10:94–112PubMed
200.
Windebank AJ, Dyck PJ (1984) Lead intoxication as a model of primary segmental demyelination. In: Dyck PJ, Thomas PK, Lambert EH, Bunge R (eds) Peripheral neuropathy, 2nd edn. Saunders, Philadelphia, pp 650–665
201.
Windebank AJ, McCall JT, Hunder HG, Dyck PJ (1980) The endoneurial content of lead related to the onset and severity of segmental demyelination. J Neuropathol Exp Neurol 39:692–699PubMed
202.
Wisniewski H, Terry RD, Whitaker JN, Cook SD, Dowling PC (1969) Landry-Guillain–Barre syndrome. A primary demyelinating disease. Arch Neurol 21:269–276PubMed
203.
Zhou L, Griffin JW (2003) Demyelinating polyneuropathies. Curr Opin Neurol 16:307–313PubMed
204.
Yousef N, Xia RH, Ubogu EE (2010) Development and characterization of a novel human in vitro blood–nerve barrier model using primary endoneurial endothelial cells. J Neuropathol Exp Neurol 69:82–97
205.
Zochodne DW (2002) Nerve and ganglion blood flow: an appraisal. Int Rev Neurobiol 50:161–202PubMed
Metadata
Title
Homeostatic regulation of the endoneurial microenvironment during development, aging and in response to trauma, disease and toxic insult
Authors
Andrew P. Mizisin
Ananda Weerasuriya
Publication date
01-03-2011
Publisher
Springer-Verlag
Published in
Acta Neuropathologica / Issue 3/2011
Print ISSN: 0001-6322
Electronic ISSN: 1432-0533
DOI
https://doi.org/10.1007/s00401-010-0783-x

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