Engineering the tissue which encapsulates subcutaneous implants. I. Diffusion properties

This report uses normal rat subcutis as a reference point to provide a quantitative analysis of small analyte transport through the tissue which encapsulates implants. Polyvinyl alcohol (PVA) with 60‐ and 350‐μm mean pore size (PVA‐60, PVA‐350), nonporous PVA (PVA‐skin), and stainless‐steel cage (SS...

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Published in:Journal of biomedical materials research 1997-12, Vol.37 (3), p.401-412
Main Authors: Sharkawy, A. Adam, Klitzman, Bruce, Truskey, George A., Reichert, W. Monty
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
Biosensors
capsules
Diffusion
Diffusion in solids
Encapsulation
Epidermal Cells
Epidermis - growth & development
Fluorescein
Implants, Experimental
Medical sciences
Models, Biological
Physiological models
Polyvinyl Alcohol
Polyvinyl alcohols
Porous materials
Radiotherapy. Instrumental treatment. Physiotherapy. Reeducation. Rehabilitation, orthophony, crenotherapy. Diet therapy and various other treatments (general aspects)
Rats
Rats, Sprague-Dawley
sensors
Stainless steel
subcutaneous implants
Technology. Biomaterials. Equipments. Material. Instrumentation
Tissue
transport barrier
Volume fraction
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Klitzman, Bruce
Truskey, George A.
Reichert, W. Monty
description This report uses normal rat subcutis as a reference point to provide a quantitative analysis of small analyte transport through the tissue which encapsulates implants. Polyvinyl alcohol (PVA) with 60‐ and 350‐μm mean pore size (PVA‐60, PVA‐350), nonporous PVA (PVA‐skin), and stainless‐steel cage (SS) specimens were implanted in the subcutis of Sprague‐Dawley rats for 4 weeks to elicit a range of capsular wound‐healing tissues. Histologic examination showed that the capsular tissue which formed around PVA‐skin and SS specimens was densely fibrous and avascular. That forming around PVA‐60 and PVA‐350 was less densely fibrous and more vascular. The fibrous content of capsular tissue and subcutis was determined from eosin‐stained histologic sections. Dual‐chamber diffusion measurements of sodium fluorescein (Mw 376 g/mol) through capsular tissue and normal rat subcutis were used to quantitatively compare the effective diffusion coefficients of small analytes on the order of glucose. The two most fibrous capsular tissues exhibited diffusion coefficients that were statistically (p < 0.05) less than that determined for rat subcutis by 50 and 25% for PVA‐skin and SS, respectively. The diffusion coefficients of the less dense capsular tissue which formed around the porous implants were not statistically different from subcutis. The experimentally measured diffusion coefficients of the two most fibrous capsular tissues were closely predicted by a simple two‐component diffusion model consisting of an aqueous interstitium with an array of impenetrable bodies equal in volume fraction to the fibrous content of the tissue. This model overestimates the diffusion coefficients measured for the least fibrous tissues. Using the diffusion coefficient measured for the PVA‐skin capsular tissue, a finite difference model predicts that a 200‐μm‐thick capsular layer would increase from 5 to 20 min the time required for subcutaneously implanted sensor to detect 95% of the blood analyte concentration. This study suggests that the fibrous capsule forming around a subcutaneously implanted smooth‐surface sensor imposes a significant diffusion barrier to small analytes such as glucose, thus increasing the lag time of the sensor by as much as threefold. A corollary observation is that a sensor with a porous surface which allows tissue ingrowth may be more responsive to blood analyte fluctuations as a result of its a more vascular and less fibrous encapsulation tissue. © 1997 John Wiley &
doi_str_mv 10.1002/(SICI)1097-4636(19971205)37:3<401::AID-JBM11>3.0.CO;2-E
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I. Diffusion properties</title><source>Wiley</source><creator>Sharkawy, A. Adam ; Klitzman, Bruce ; Truskey, George A. ; Reichert, W. Monty</creator><creatorcontrib>Sharkawy, A. Adam ; Klitzman, Bruce ; Truskey, George A. ; Reichert, W. Monty</creatorcontrib><description>This report uses normal rat subcutis as a reference point to provide a quantitative analysis of small analyte transport through the tissue which encapsulates implants. Polyvinyl alcohol (PVA) with 60‐ and 350‐μm mean pore size (PVA‐60, PVA‐350), nonporous PVA (PVA‐skin), and stainless‐steel cage (SS) specimens were implanted in the subcutis of Sprague‐Dawley rats for 4 weeks to elicit a range of capsular wound‐healing tissues. Histologic examination showed that the capsular tissue which formed around PVA‐skin and SS specimens was densely fibrous and avascular. That forming around PVA‐60 and PVA‐350 was less densely fibrous and more vascular. The fibrous content of capsular tissue and subcutis was determined from eosin‐stained histologic sections. Dual‐chamber diffusion measurements of sodium fluorescein (Mw 376 g/mol) through capsular tissue and normal rat subcutis were used to quantitatively compare the effective diffusion coefficients of small analytes on the order of glucose. The two most fibrous capsular tissues exhibited diffusion coefficients that were statistically (p &lt; 0.05) less than that determined for rat subcutis by 50 and 25% for PVA‐skin and SS, respectively. The diffusion coefficients of the less dense capsular tissue which formed around the porous implants were not statistically different from subcutis. The experimentally measured diffusion coefficients of the two most fibrous capsular tissues were closely predicted by a simple two‐component diffusion model consisting of an aqueous interstitium with an array of impenetrable bodies equal in volume fraction to the fibrous content of the tissue. This model overestimates the diffusion coefficients measured for the least fibrous tissues. Using the diffusion coefficient measured for the PVA‐skin capsular tissue, a finite difference model predicts that a 200‐μm‐thick capsular layer would increase from 5 to 20 min the time required for subcutaneously implanted sensor to detect 95% of the blood analyte concentration. This study suggests that the fibrous capsule forming around a subcutaneously implanted smooth‐surface sensor imposes a significant diffusion barrier to small analytes such as glucose, thus increasing the lag time of the sensor by as much as threefold. A corollary observation is that a sensor with a porous surface which allows tissue ingrowth may be more responsive to blood analyte fluctuations as a result of its a more vascular and less fibrous encapsulation tissue. © 1997 John Wiley &amp; Sons, Inc. 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Adam</creatorcontrib><creatorcontrib>Klitzman, Bruce</creatorcontrib><creatorcontrib>Truskey, George A.</creatorcontrib><creatorcontrib>Reichert, W. Monty</creatorcontrib><title>Engineering the tissue which encapsulates subcutaneous implants. I. Diffusion properties</title><title>Journal of biomedical materials research</title><addtitle>J. Biomed. Mater. Res</addtitle><description>This report uses normal rat subcutis as a reference point to provide a quantitative analysis of small analyte transport through the tissue which encapsulates implants. Polyvinyl alcohol (PVA) with 60‐ and 350‐μm mean pore size (PVA‐60, PVA‐350), nonporous PVA (PVA‐skin), and stainless‐steel cage (SS) specimens were implanted in the subcutis of Sprague‐Dawley rats for 4 weeks to elicit a range of capsular wound‐healing tissues. Histologic examination showed that the capsular tissue which formed around PVA‐skin and SS specimens was densely fibrous and avascular. That forming around PVA‐60 and PVA‐350 was less densely fibrous and more vascular. The fibrous content of capsular tissue and subcutis was determined from eosin‐stained histologic sections. Dual‐chamber diffusion measurements of sodium fluorescein (Mw 376 g/mol) through capsular tissue and normal rat subcutis were used to quantitatively compare the effective diffusion coefficients of small analytes on the order of glucose. The two most fibrous capsular tissues exhibited diffusion coefficients that were statistically (p &lt; 0.05) less than that determined for rat subcutis by 50 and 25% for PVA‐skin and SS, respectively. The diffusion coefficients of the less dense capsular tissue which formed around the porous implants were not statistically different from subcutis. The experimentally measured diffusion coefficients of the two most fibrous capsular tissues were closely predicted by a simple two‐component diffusion model consisting of an aqueous interstitium with an array of impenetrable bodies equal in volume fraction to the fibrous content of the tissue. This model overestimates the diffusion coefficients measured for the least fibrous tissues. Using the diffusion coefficient measured for the PVA‐skin capsular tissue, a finite difference model predicts that a 200‐μm‐thick capsular layer would increase from 5 to 20 min the time required for subcutaneously implanted sensor to detect 95% of the blood analyte concentration. This study suggests that the fibrous capsule forming around a subcutaneously implanted smooth‐surface sensor imposes a significant diffusion barrier to small analytes such as glucose, thus increasing the lag time of the sensor by as much as threefold. A corollary observation is that a sensor with a porous surface which allows tissue ingrowth may be more responsive to blood analyte fluctuations as a result of its a more vascular and less fibrous encapsulation tissue. © 1997 John Wiley &amp; Sons, Inc. J Biomed Mater Res, 37, 401–412, 1997.</description><subject>Animals</subject><subject>Biological and medical sciences</subject><subject>Biosensors</subject><subject>capsules</subject><subject>Diffusion</subject><subject>Diffusion in solids</subject><subject>Encapsulation</subject><subject>Epidermal Cells</subject><subject>Epidermis - growth &amp; development</subject><subject>Fluorescein</subject><subject>Implants, Experimental</subject><subject>Medical sciences</subject><subject>Models, Biological</subject><subject>Physiological models</subject><subject>Polyvinyl Alcohol</subject><subject>Polyvinyl alcohols</subject><subject>Porous materials</subject><subject>Radiotherapy. Instrumental treatment. Physiotherapy. Reeducation. 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Histologic examination showed that the capsular tissue which formed around PVA‐skin and SS specimens was densely fibrous and avascular. That forming around PVA‐60 and PVA‐350 was less densely fibrous and more vascular. The fibrous content of capsular tissue and subcutis was determined from eosin‐stained histologic sections. Dual‐chamber diffusion measurements of sodium fluorescein (Mw 376 g/mol) through capsular tissue and normal rat subcutis were used to quantitatively compare the effective diffusion coefficients of small analytes on the order of glucose. The two most fibrous capsular tissues exhibited diffusion coefficients that were statistically (p &lt; 0.05) less than that determined for rat subcutis by 50 and 25% for PVA‐skin and SS, respectively. The diffusion coefficients of the less dense capsular tissue which formed around the porous implants were not statistically different from subcutis. The experimentally measured diffusion coefficients of the two most fibrous capsular tissues were closely predicted by a simple two‐component diffusion model consisting of an aqueous interstitium with an array of impenetrable bodies equal in volume fraction to the fibrous content of the tissue. This model overestimates the diffusion coefficients measured for the least fibrous tissues. Using the diffusion coefficient measured for the PVA‐skin capsular tissue, a finite difference model predicts that a 200‐μm‐thick capsular layer would increase from 5 to 20 min the time required for subcutaneously implanted sensor to detect 95% of the blood analyte concentration. This study suggests that the fibrous capsule forming around a subcutaneously implanted smooth‐surface sensor imposes a significant diffusion barrier to small analytes such as glucose, thus increasing the lag time of the sensor by as much as threefold. A corollary observation is that a sensor with a porous surface which allows tissue ingrowth may be more responsive to blood analyte fluctuations as a result of its a more vascular and less fibrous encapsulation tissue. © 1997 John Wiley &amp; Sons, Inc. J Biomed Mater Res, 37, 401–412, 1997.</abstract><cop>New York</cop><pub>John Wiley &amp; Sons, Inc</pub><pmid>9368145</pmid><doi>10.1002/(SICI)1097-4636(19971205)37:3&lt;401::AID-JBM11&gt;3.0.CO;2-E</doi><tpages>12</tpages></addata></record>
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ispartof Journal of biomedical materials research, 1997-12, Vol.37 (3), p.401-412
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1097-4636
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source Wiley
subjects Animals
Biological and medical sciences
Biosensors
capsules
Diffusion
Diffusion in solids
Encapsulation
Epidermal Cells
Epidermis - growth & development
Fluorescein
Implants, Experimental
Medical sciences
Models, Biological
Physiological models
Polyvinyl Alcohol
Polyvinyl alcohols
Porous materials
Radiotherapy. Instrumental treatment. Physiotherapy. Reeducation. Rehabilitation, orthophony, crenotherapy. Diet therapy and various other treatments (general aspects)
Rats
Rats, Sprague-Dawley
sensors
Stainless steel
subcutaneous implants
Technology. Biomaterials. Equipments. Material. Instrumentation
Tissue
transport barrier
Volume fraction
title Engineering the tissue which encapsulates subcutaneous implants. I. Diffusion properties
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