 |
|||||
|
|||||
|
|||||
|
|||||
|
|||||
The Journal of Neuroscience, May 1, 1999, 19(9):3649-3655
Upregulation of Tumor Necrosis Factor
Transport across the Blood-Brain Barrier after Acute Compressive Spinal Cord Injury
Weihong Pan1, Abba J. Kastin2, 3, Richard L. Bell3, and Richard D. Olson3 Departments of 1 Neurology and 2 Medicine and Veterans Affairs Medical Center, Tulane University School of Medicine, New Orleans, Louisiana 70112, and 3 Department of Psychology, University of New Orleans, New Orleans, Louisiana 70148
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Tumor necrosis factor
(TNF) is a cytokine that is involved in the inflammatory process after CNS injury and is implicated in neuroregeneration. A saturable transport system for TNF located at the blood-brain barrier (BBB) is responsible for the limited entry of TNF from blood to the CNS in normal mice.
After partial disruption of the BBB by compression of the lumbar spinal cord, permeability to TNF was increased not only in the lumbar spinal cord but also in brain and distal spinal cord segments, where the BBB remained intact. The increase in the entry of TNF to the CNS followed a biphasic temporal pattern, with a first peak immediately after injury and a second peak starting on day 3; these changes lasted longer than the mere disruption of the BBB. The increased entry of TNF was abolished by addition of excess unlabeled TNF, showing that the transport system for TNF remained saturable after spinal cord injury (SCI) and providing evidence that the enhanced entry of TNF could not be explained by diffusion or leakage.
This study adds strong support for our concept that the saturable transport system for TNF across the BBB can be upregulated in the diseased state, and it suggests that the BBB is actively involved in the modulation of the processes of degeneration and regeneration after SCI.
Key words: TNF
INTRODUCTION
Spinal cord injury (SCI) in mammals is associated with disruption of the blood-brain barrier (BBB), increased cytokine production, and degeneration of CNS tissue with poor functional recovery (McKenzie et al., 1995
; Popovich et al., 1996
TNF also can exert different effects on the BBB, including changes in permeability (Camussi et al., 1991
The interaction between TNF and the BBB in normal animals involves a saturable transport system at the BBB, which regulates the entry of TNF in peripheral blood to the brain and spinal cord unidirectionally (Gutierrez et al., 1993
Having found that the TNF transport system across the BBB is increased in two different pathological states (SCI by complete transection and EAE), we investigated the possibility that this upregulation is a more generalized phenomenon. In the study reported here, we applied a compression model of SCI to further study the alterations of the saturable transport system for TNF. The time course and spatial pattern of TNF entry at various times after SCI were measured and compared with entry of radiolabeled albumin, which was indicative of disruption of the BBB. The results were designed to answer the following questions. (1) How does the disruption of the BBB differ in the compressive model of SCI? (2) Does TNF enter the injured CNS by leakage only? (3) If not, where is the transport system for TNF preserved and how does it function? In general, knowledge about the regulation of the availability of TNF to the injured CNS should provide a novel approach, with possible therapeutic implications to understanding how inflammatory processes limit degeneration in the CNS.
MATERIALS AND METHODS
Spinal cord compression. Adult male ICR mice received deep anesthesia by intramuscular ketamine and xylazine (Sigma, St. Louis, MO). The skin was incised longitudinally on the lower back, the supraspinal muscles were separated, and laminectomy was performed on L1 and L2 vertebral bones with a pair of iridectomy scissors (Fine Science Tools, Foster City, CA). The spinal cord at this level was compressed by initially flanking the spinal cord with a pair of modified cover glass forceps at a length of 6 mm (Fine Science Tools). SCI involved steady compression of the 3 mm spinal cord to a width of 1 mm for 5 sec. After the injury, the subcutaneous tissue and skin were sutured in layers. The mice were placed on a heating pad until recovery from anesthesia within 1 hr and then were returned to their cages containing soft bedding and easy access to food and water. Manual compression of the bladder was performed for those with bladder distension. The extent of injury was quantified daily with the locomotor rating scale shown in Table 1 (n = 14-18 for daily scoring).
View this table: [in this window]
[in a new window]
Table 1. Scoring scales for mice after mild to moderate compressive spinal cord injury Measurement of BBB permeability. Twelve groups of mice were studied (n = 8-12 per group). Experimental groups were tested immediately after SCI (5 min) at 0.5, 1, 2, 4, and 12 hr and then 1, 2, 3, 4, and 5 d after SCI. A nonsurgical control group was included in each experiment. The mice were anesthetized by intraperitoneal injection of 40% urethane (Sigma). The neck of the mouse was exposed, and the jugular veins and the right carotid artery were separated. Approximately 0.9 µCi/mouse 125I-TNF (R & D Systems, Minneapolis, MN), together with 1.8 µCi/mouse 99mTc-albumin (Amersham Health Care, San Antonio, TX), was injected in a total volume of 200 µl into the left jugular vein. The radioactive solution was mixed in lactated Ringer's solution containing 1% bovine serum albumin. At 10 min after intravenous injection, blood was collected from a cut in the carotid artery, and the mouse was decapitated immediately. Samples of brain and spinal cord (cervical, thoracic, and lumbar regions) were collected and weighed. The tissue sample and 50 µl of serum were counted in a dual channel
-counter (Wallac, Gaithersburg, MD). The tissue/serum ratio was calculated and expressed as microliters per grams. The entry of 99mTc-albumin was used as a measurement of BBB permeability in general, whereas the entry of 125I-TNF may be a combination of leakage and transport across the BBB.
Inhibition study to test saturability. Four groups of mice were studied (n = 8-9 per group): (1) control (non-SCI) injected with 125I-TNF and 99mTc-albumin only; (2) control with addition of 1 µg/mouse (~40 µg/kg body weight) unlabeled TNF in the injection solution of 125I-TNF and 99mTc-albumin; (3) mice at 3 d after SCI injected with 125I-TNF and 99mTc-albumin only; and (4) mice at 3 d after SCI with addition of 1 µg/mouse unlabeled TNF in the injection solution with the radiolabeled compounds. BBB permeability was studied as mentioned above.
Statistical analysis. Statistical Program for the Social Sciences software was used. Means were expressed with their SEs, ANOVA was performed for all groups, and, subsequently, Tukey's range test was performed if ANOVA showed statistical significance (p < 0.05). Sigma Plot was used to generate the figures.
RESULTS
Functional deficit after SCI
Figure 1 shows that SCI produced a deficit of locomotor activity in the mice that began immediately after their awakening from anesthesia (n = 14-18). Eighteen mice underwent SCI on the same day and were evaluated subsequently for 23 d; four of them died of complications during the first week. The reduction in the combined scores was statistically significant during the first 8 d after injury (p < 0.01 for days 3, 4, 5, and 6; p < 0.05 for the rest of the 8 d).
View larger version (12K):[in this window]
[in a new window]
Figure 1. Functional deficit after acute compression of the lumbar spinal cord on day 1. Time 0, Control without SCI with a full score of 17. The decrease in scores was statistically significant from day 1 to day 8. *p < 0.05; **p < 0.01 versus control (n = 14-18 per group).
Time course of BBB disruption after SCI as measured by 99mTc-albumin
The extent of BBB disruption at different time intervals after SCI was reflected in the tissue/serum ratios of 99mTc-albumin injected intravenously 10 min before each determination. In the baseline (time 0) control group (no SCI), the cervical area had the greatest permeability among the four regions. After SCI, statistically significant changes occurred in the thoracic and especially the lumbar spinal cord but not in the brain or the cervical spinal cord. The significant change in the thoracic spinal cord consisted of decreased permeability at day 5 after injury (p < 0.05).
In the lumbar spinal cord, where most of the disruption was evident, a brief increase in entry occurred immediately (5 min after injury) (p < 0.01) after SCI and remained elevated 0.5 hr later (p < 0.01). Permeability to 99mTc-albumin in the lumbar area returned to basal levels 1 hr after SCI and remained there, except for a smaller second increase (p < 0.05) on day 3 (Fig. 2).
View larger version (15K):[in this window]
[in a new window]
Figure 2. BBB permeation of 99mTc-albumin and 125I-TNF in the lumbar spinal cord after acute lumbar SCI. Postinjury intervals signify the different time points after injury when the entry of the two compounds was studied. The intervals are as follows: (1) control without injury; (2) immediately (5 min) after injury; (3) 0.5 hr; (4) 1 hr; (5) 2 hr; (6) 4 hr; (7) 12 hr; (8) 24 hr; (9) 48 hr; (10) 72 hr; (11) 96 hr; and (12) 120 hr after injury. *p < 0.05; **p < 0.01; ***p < 0.001 versus control group. SC, Spinal cord.
Increased permeability to 125I-TNF in comparison with BBB disruption
The BBB permeability to 125I-TNF, also measured 10 min after intravenous injection, was higher than that to 99mTc-albumin in each CNS region in both control and SCI mice. In comparison with the control group, entry of 125I-TNF was significantly increased in the brain on days 3 (p < 0.01), 4 (p < 0.001), and 5 (p < 0.001). The spinal cord had a greater increase in the entry of 125I-TNF than the brain. The cervical spinal cord showed increases at 12 hr (p < 0.05) and day 5 (p < 0.001), whereas the thoracic spinal cord showed an increase on day 2 (p < 0.001). In the lumbar spinal cord, there was a transient peak immediately (5 min) after SCI (p < 0.001), which paralleled the increase of 99mTc-albumin temporally as shown in Figure 2; permeability returned to almost normal between 0.5 and 24 hr after injury. A second, more prolonged, peak of increased permeability to 125I-TNF in the lumbar spinal cord occurred at 48 hr (day 2, p < 0.001), earlier than the second increase in 99mTc-albumin, and remained elevated (p < 0.001) up to the end of the study at 120 hr (day 5 after injury).
When the ratio of the entry of 125I-TNF to that of the entry of 99mTc-albumin was plotted against time to clearly illustrate differential permeability (Fig. 3), it was seen that the immediate increase was significant (p < 0.05) in the cervical and thoracic areas, as well as the lumbar spinal cord. Furthermore, the prolonged second increase was significant in the thoracic (p < 0.001) and lumbar spinal cord (p < 0.005) from day 2 after injury, remaining elevated (p < 0.001) for the 5 d of the study. Increases also were present in brain (day 3-5, p < 0.001) and cervical spinal cord (day 4-5, p < 0.001).
View larger version (17K):[in this window]
[in a new window]
Figure 3. Differential permeability of the BBB after acute compression of the lumbar spinal cord. The ratio of the entry of 125I-TNF to 99mTc-albumin is plotted against time after SCI performed at time 0. *p < 0.05; **p < 0.01; ***p < 0.001 versus control. The inset shows the earlier times (in hours). SC, Spinal cord.
When the entry of 99mTc-albumin was subtracted from the entry of 125I-TNF as a correction for vascular volume and leakage secondary to BBB disruption, the pattern was somewhat different from that of the differential permeability. The initial increase was transient and appeared only in the lumbar spinal cord (p < 0.005). For brain and lumbar spinal cord, the second peak started on day 2 after injury (p < 0.001) and lasted until day 5. For the thoracic spinal cord, the elevation was significant on day 2-4 (p < 0.05). The cervical spinal cord showed a significant increase at day 5 (p < 0.005).
Inhibition of increased permeability to 125I-TNF
Figure 4 shows the effects of unlabeled TNF on the differential permeability of TNF/albumin 3 d after SCI. After SCI, the increase in the differential permeability was statistically significant (p < 0.01) in the brain, thoracic, and lumbar spinal cord but not in the cervical region. Just as saturability in the control groups was demonstrated by the self-inhibition seen after addition of unlabeled TNF (p < 0.001), a similar pattern of inhibition of 125I-TNF entry also was found in the SCI groups. Not only was inhibition of entry of 125I-TNF found with unlabeled TNF in the SCI groups in which entry was already increased by the injury, but saturability occurred in all four of the CNS regions (p < 0.001).
View larger version (33K):[in this window]
[in a new window]
Figure 4. Inhibition of the differential permeability of the BBB after acute compression of the lumbar spinal cord. Groups are as follows: (1) control with 125I-TNF and 99mTc-albumin; (2) control with 125I-TNF and 99mTc-albumin and 1 µg/mouse unlabeled TNF; (3) 72 hr after injury with 125I-TNF and 99mTc-albumin; and (4) 72 hr after injury with 125I-TNF and 99mTc-albumin and 1 µg/mouse unlabeled TNF. SCI significantly (**p < 0.01) increased the TNF/albumin ratio in brain and in thoracic and lumbar spinal cord (group 3 vs group 1). Unlabeled TNF significantly (***p < 0.001) decreased the TNF/albumin ratio compared with both control group 1 and SCI group 3. SC, Spinal cord.
DISCUSSION
In the acute stage after lumbar SCI, disruption of the BBB (indicated by dynamic changes in the entry of albumin) was biphasic and restricted to the lumbar spinal cord. In contrast, the entry of TNF was more pronounced in several ways: its magnitude was greater; it occurred earlier; it lasted for a longer time; it involved distal regions, as well as the lumbar spinal cord; and it retained the self-inhibition characteristic of a saturable transport system, which would not be seen with diffusion or leakage.
SCI by compression to a set thickness provides a reproducible model of functional deficit with correlated histological findings that have been well characterized in guinea pigs (Blight, 1991
The entry of TNF into the CNS, in comparison with albumin, initially followed a similar pattern in that there was an early peak of BBB opening in the lumbar spinal cord. However, the second increase in the entry of TNF preceded that of albumin, was much greater, and lasted a longer time. In addition, in regions that are distal to the site of injury and that did not show the disruption of the BBB characterized by albumin, the entry of TNF also was increased. Because TNF circulates in the blood as a trimer (Smith and Baglioni, 1987
Thus, the more widespread and persistent increase in the entry of TNF from the periphery is not related to disruption of the BBB but rather to alternative mechanisms of BBB transport. To illustrate this point further, we performed two conversions. The first showed the differential permeability of TNF and albumin by expression of the results as the ratio of 125I-TNF to 99mTc-albumin. The differential permeability best reflects dynamic changes during partial disruption of the BBB in which molecules with different sizes cross at different rates (Ziylan et al., 1983
99mTc-albumin). Both results clearly demonstrate that the entry of TNF differs from that caused by disruption of the BBB.
In normal mice, TNF has a unidirectional transport across the BBB from blood to the CNS, with an influx rate of 0.622 ± 0.092 µl · g
1 · min
There are pathophysiological considerations for the upregulation of TNF transport system at the BBB. On the one hand, adequate TNF in the damaged CNS is related to increased neurite outgrowth by recruitment and activation of macrophages, counteracting myelin-associated inhibitory molecules so as to provide a permissive substrate for axonal regrowth (Lotan and Schwartz, 1994
Production of TNF within the CNS is induced after injury (Fan et al., 1994
In summary, although lumbar spinal cord compressive injury caused a restricted biphasic opening of the BBB, it caused a much greater increase in the permeation of TNF from blood to all CNS regions. The prolonged increased entry of TNF during the second phase was related to the upregulation of a saturable transport system rather than to disruption of the BBB. This upregulation showed active involvement of the BBB during SCI in controlling the availability of the blood-borne cytokine. The increased, but still limited, entry of TNF from blood to the CNS may be beneficial in restricting secondary tissue damage and in aiding regeneration of the CNS.
FOOTNOTES Received Dec. 18, 1998; revised Feb. 5, 1999; accepted Feb. 16, 1999.
This work was supported by Veterans Affairs, Office of Naval Research, and National Institutes of Health.
Correspondence should be addressed to Dr. Weihong Pan, Veterans Affairs Research 8F 159, 1601 Perdido Street, New Orleans, LA 70112-1262.
REFERENCES
- Banks WA, Kastin AJ, Arimura A (1998) Effect of spinal cord injury on the permeability of the blood-brain and blood-spinal cord barriers to the neurotrophin PACAP. Exp Neurol 151:116-123[Web of Science][Medline].
- Baskaya MK, Rao AM, Dogan A, Donaldson D, Dempsey RJ (1997) The biphasic opening of the blood-brain barrier in the cortex and hippocampus after traumatic brain injury in rats. Neurosci Lett 226:33-36[Web of Science][Medline].
- Blight AR (1991) Morphometric analysis of a model of spinal cord injury in guinea pigs, with behavioral evidence of delayed secondary pathology. J Neurol Sci 103:156-171[Web of Science][Medline].
- Boddeke HWGM, Appel K, Sauter A, Gebicke-Haerter PJ, Buttini M (1995) In: Expression of TNF
- Camussi G, Turello E, Bussolino F, Baglioni C (1991) Tumor necrosis factor alters cytoskeletal organization and barrier function of endothelial cells. Int Arch Allergy Appl Immunol 96:84-91[Web of Science][Medline].
- Chao CC, Hu S (1994) Tumor necrosis factor-
- Descamps L, Cecchelli R, Torpier G (1997) Effects of tumor necrosis factor on receptor-mediated endocytosis and barrier functions of bovine brain capillary endothelial cell monolayers. J Neuroimmunol 74:173-184[Web of Science][Medline].
- Duchini A, Govindarajan S, Santucci M, Zampi G, Hofman FM (1996) Effects of tumor necrosis factor-
- Fan L, Perlman KP, Young PR, Barone FC, Feuerstein GZ, Gennarelli TA, Smith DH, McIntosh TK (1994) Experimental brain injury induces expression of tumor necrosis factor-
- Fan L, Young PR, Barone FC, Feuerstein GZ, Smith DH, McIntosh TK (1996) Experimental brain injury induces differential expression of tumor necrosis factor-
- Fitch MT, Silver J (1997) Activated macrophages and the blood-brain barrier: inflammation after CNS injury leads to increases in putative inhibitory molecules. Exp Neurol 148:587-603[Web of Science][Medline].
- Franzen R, Schoenen J, Leprince P, Joosten E, Moonen G, Martin D (1998) Effects of macrophage transplantation in the injured adult rat spinal cord: a combined immunocytochemical and biochemical study. J Neurosci Res 51:316-327[Web of Science][Medline].
- Fujiki M, Zhang Z, Guth L, Steward O (1996) Genetic influences on cellular reactions to spinal cord injury: activation of macrophages/microglia and astrocytes is delayed in mice carrying a mutation (Wlds) that causes delayed wallerian degeneration. J Comp Neurol 371:469-484[Web of Science][Medline].
- Gelbard HA, Dzenko KA, DiLoreto D, del Cerro C, del Cerro M, Epstein LG (1993) Neurotoxic effects of tumor necrosis factor
- Genestier L, Bonnefoy-Berard N, Rouault JP, Flacher M, Revillard JP (1995) Tumor necrosis factor-
[Abstract/Free Full Text] .- Gutierrez EG, Banks WA, Kastin AJ (1993) Murine tumor necrosis factor
- Jaeger CB, Blight AR (1997) Spinal cord compression injury in guinea pigs: structural changes of endothelium and its perivascular cell associations after blood-brain barrier breakdown and repair. Exp Neurol 144:381-399[Web of Science][Medline].
- Kim KS, Wass CA, Cross AS, Opal SM (1992) Modulation of blood-brain barrier permeability by tumor necrosis factor and antibody to tumor necrosis factor in the rat. Lymphokine Cytokine Res 11:293-298[Web of Science][Medline].
- Klusman I, Schwab ME (1997) Effects of pro-inflammatory cytokines in experimental spinal cord injury. Brain Res 762:173-184[Web of Science][Medline].
- Kuroiwa T, Ting P, Martinez H, Klatzo I (1985) The biphasic opening of the blood-brain barrier to proteins following temporary middle cerebral artery occlusion. Acta Neuropathol 68:122-129[Medline].
- Li GL, Brodin G, Farooque M, Funa K, Holtz A, Wang WL, Olsson Y (1996) Apoptosis and expression of Bcl-2 after compression trauma to rat spinal cord. J Neuropathol Exp Neurol 55:280-289[Web of Science][Medline].
- Liu T, Clark RK, McDonnell PC, Young PR, White RF, Barone FC, Feuerstein GZ (1994) Tumor necrosis factor-
- Lotan M, Schwartz M (1994) Cross talk between the immune system and the nervous system in response to injury: implications for regeneration. FASEB J 8:1026-1033[Abstract].
- Mattson MP (1997) Neuroprotective signal transduction: relevance to stroke. Neurosci Biobehav Rev 21:193-206[Web of Science][Medline].
- McKenzie AL, Hall JJ, Aihara N, Fukuda K, Noble LJ (1995) Immunolocalization of endothelin in the traumatized spinal cord: relationship to blood-spinal cord barrier breakdown. J Neurotrauma 12:257-268[Web of Science][Medline].
- Miura M, Friedlander RM, Yuan J (1995) Tumor necrosis factor-induced apoptosis is mediated by a CrmA-sensitive cell death pathway. Proc Natl Acad Sci USA 92:8318-8322
[Abstract/Free Full Text] .- Pan W, Banks WA, Kennedy MK, Gutierrez EG, Kastin AJ (1996) Differential permeability of the BBB in acute EAE: enhanced transport of TNF-
[Abstract/Free Full Text] .- Pan W, Banks WA, Kastin AJ (1997a) Permeability of the blood-brain and blood-spinal cord barriers to interferons. J Neuroimmunol 76:105-111[Web of Science][Medline].
- Pan W, Banks WA, Kastin AJ (1997b) BBB permeability to ebiratide and TNF in acute spinal cord injury. Exp Neurol 146:367-373[Web of Science][Medline].
- Pan W, Zadina JE, Harlan RE, Weber JT, Banks WA, Kastin AJ (1997c) Tumor necrosis factor
- Popovich PG, Horner PJ, Mullin BB, Stokes BT (1996) A quantitative spatial analysis of the blood-spinal cord barrier. I. Permeability changes after experimental spinal cord contusion injury. Exp Neurol 142:258-275[Web of Science][Medline].
- Probert L, Selmaj K (1997) TNF and related molecules: trends in neuroscience and clinical applications. J Neuroimmunol 72:113-117[Web of Science][Medline].
- Probert L, Akassoglou K, Kassiotis G, Pasparakis M, Alexopoulou L, Kollias G (1997) TNF-
- Schwartz M, Solomon A, Lavie V, Ben-Bassat S, Belkin M, Cohen A (1991) Tumor necrosis factor facilitates regeneration of injured central nervous system axons. Brain Res 545:334-338[Web of Science][Medline].
- Schwartz M, Sivron T, Eitan S, Hirschberg DL, Lotan M, Elman-Faber A (1994) Cytokines and cytokine-related substances regulating glial cell response to injury of the central nervous system. Prog Brain Res 103:331-341[Web of Science][Medline].
- Shohami E, Gallily R, Mechoulam R, Bass R, Ben-Hur T (1997) Cytokine production in the brain following closed head injury: dexanabinol (HU-211) is a novel TNF-
- Smith RA, Baglioni C (1987) The active form of tumor necrosis factor is a trimer. J Biol Chem 262:6951-6954
[Abstract/Free Full Text] .- Soares HD, Hicks RR, Smith D, McIntosh TK (1995) Inflammatory leukocytic recruitment and diffuse neuronal degeneration are separate pathological processes resulting from traumatic brain injury. J Neurosci 15:8223-8233[Abstract].
- Vandenabeele P, Declercq W, Vanhaesebroeck B, Grooten J, Fiers W (1995) Both TNF receptors are required for TNF-mediated induction of apoptosis in PC60 cells. J Immunol 154:2904-2913[Abstract].
- Wang CX, Nuttin B, Heremans H, Dom R, Gybels J (1996) Production of tumor necrosis factor in spinal cord following traumatic injury in rats. J Neuroimmunol 69:151-156[Web of Science][Medline].
- Ziylan YZ, Robinson PJ, Rapoport SI (1983) Differential blood-brain barrier permeabilities to [14C]sucrose and [3H]inulin after osmotic opening in the rat. Exp Neurol 79:845-857[Web of Science][Medline].
Copyright © 1999 Society for Neuroscience 0270-6474/99/1993649-07$05.00/0
This article has been cited by other articles:
W. Pan, C. Yu, H. Hsuchou, Y. Zhang, and A. J. Kastin
Neuroinflammation facilitates LIF entry into brain: role of TNF
Am J Physiol Cell Physiol, June 1, 2008; 294(6): C1436 - C1442.
[Abstract] [Full Text] [PDF]
B. Osburg, C. Peiser, D. Domling, L. Schomburg, Y. T. Ko, K. Voigt, and U. Bickel
Effect of endotoxin on expression of TNF receptors and transport of TNF-alpha at the blood-brain barrier of the rat
Am J Physiol Endocrinol Metab, November 1, 2002; 283(5): E899 - E908.
[Abstract] [Full Text] [PDF]
W. Pan, G. Cornelissen, F. Halberg, and A. J. Kastin
Functional Genomics of Sleep and Circadian Rhythm: Selected Contribution: Circadian rhythm of tumor necrosis factor-alpha uptake into mouse spinal cord
J Appl Physiol, March 1, 2002; 92(3): 1357 - 1362.
[Abstract] [Full Text] [PDF]
This Article Abstract 
Full Text (PDF) Submit an eLetter Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager 
Citing Articles Citing Articles via HighWire Citing Articles via Web of Science (58) Citing Articles via Google Scholar Google Scholar Articles by Pan, W. Articles by Olson, R. D. Search for Related Content PubMed PubMed Citation Articles by Pan, W. Articles by Olson, R. D.
|
|
|
|
 |
|