Radiofrequency Ablation: Modeling the Enhanced Temperature Response to Adjuvant NaCl Pretreatment

S. Melvyn Lobo, Karim S. Afzal, Muneeb Ahmed, Jonathan B. Kruskal, Robert E. Lenkinski, S. Nahum Goldberg

Research output: Contribution to journalArticle

65 Citations (Scopus)

Abstract

PURPOSE: To characterize the effects of volume and concentration of adjuvant NaCl pretreatment on radiofrequency (RF) ablation and to model these results to determine their applicability to in vivo systems. MATERIALS AND METHODS: Standardized I-L 5% agar phantoms were constructed with central wells of varying volume that were filled with a protein-based polymer gel of varying NaCl concentration (0%-35%). RF ablation to the maximum system current output (2,000 mA) was applied to internally cooled 2-cm electrodes placed in the center of the gel wells. Remote thermometry was performed 20 mm from the electrode. Temperatures generated within the phantom were then used to model the response surface by using regression analysis. The generated model was then applied to previously published in vivo data to determine its applicability to a porcine liver tissue model. Statistical analyses included one-way analysis of variance to compare the temperatures reached with different NaCl concentrations and volumes with those reached without NaCl. In addition, modeled functions were evaluated for goodness of fit and the statistical significance of their coefficients. RESULTS: NaCl volume and concentration had significant effects on RF-generated heating of the agar phantoms. The mean maximum temperature, 91.4°C ± 0.8 (SD), was reached with 3.5 mL of 10% NaCl gel. This was significantly higher than the mean temperature reached in phantoms containing 0% NaCl gel, 40.3°C ± 4.9 (P < .001). Heat increases to the maximum temperature correlated strongly with the deposited RF energy, with maximum temperatures limited by the current output of the RF generator. The response surface was defined by a generator energy-dependent region and a generator current-limited region, which were best modeled by a modified gamma-variate function and an exponential function, respectively (r2 = 0.92). This model correlated well with previously published in vivo data (r2 = 0.86). CONCLUSION: Modulation of electrical conductivity has different effects on RF ablation response that are dependent on generator capabilities and the volume and concentration of NaCl pretreatment.

Original languageEnglish (US)
Pages (from-to)175-182
Number of pages8
JournalRadiology
Volume230
Issue number1
DOIs
StatePublished - Jan 2004

Fingerprint

Temperature
Gels
Agar
Electrodes
Thermometry
Electric Conductivity
Heating
Analysis of Variance
Polymers
Swine
Hot Temperature
Regression Analysis
Liver
Proteins

Keywords

  • Computers, simulation
  • Experimental study
  • Neoplasms, therapy
  • Radiofrequency (RF) ablation

ASJC Scopus subject areas

  • Radiological and Ultrasound Technology

Cite this

Lobo, S. M., Afzal, K. S., Ahmed, M., Kruskal, J. B., Lenkinski, R. E., & Goldberg, S. N. (2004). Radiofrequency Ablation: Modeling the Enhanced Temperature Response to Adjuvant NaCl Pretreatment. Radiology, 230(1), 175-182. https://doi.org/10.1148/radiol.2301021512

Radiofrequency Ablation : Modeling the Enhanced Temperature Response to Adjuvant NaCl Pretreatment. / Lobo, S. Melvyn; Afzal, Karim S.; Ahmed, Muneeb; Kruskal, Jonathan B.; Lenkinski, Robert E.; Goldberg, S. Nahum.

In: Radiology, Vol. 230, No. 1, 01.2004, p. 175-182.

Research output: Contribution to journalArticle

Lobo, SM, Afzal, KS, Ahmed, M, Kruskal, JB, Lenkinski, RE & Goldberg, SN 2004, 'Radiofrequency Ablation: Modeling the Enhanced Temperature Response to Adjuvant NaCl Pretreatment', Radiology, vol. 230, no. 1, pp. 175-182. https://doi.org/10.1148/radiol.2301021512
Lobo, S. Melvyn ; Afzal, Karim S. ; Ahmed, Muneeb ; Kruskal, Jonathan B. ; Lenkinski, Robert E. ; Goldberg, S. Nahum. / Radiofrequency Ablation : Modeling the Enhanced Temperature Response to Adjuvant NaCl Pretreatment. In: Radiology. 2004 ; Vol. 230, No. 1. pp. 175-182.
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abstract = "PURPOSE: To characterize the effects of volume and concentration of adjuvant NaCl pretreatment on radiofrequency (RF) ablation and to model these results to determine their applicability to in vivo systems. MATERIALS AND METHODS: Standardized I-L 5{\%} agar phantoms were constructed with central wells of varying volume that were filled with a protein-based polymer gel of varying NaCl concentration (0{\%}-35{\%}). RF ablation to the maximum system current output (2,000 mA) was applied to internally cooled 2-cm electrodes placed in the center of the gel wells. Remote thermometry was performed 20 mm from the electrode. Temperatures generated within the phantom were then used to model the response surface by using regression analysis. The generated model was then applied to previously published in vivo data to determine its applicability to a porcine liver tissue model. Statistical analyses included one-way analysis of variance to compare the temperatures reached with different NaCl concentrations and volumes with those reached without NaCl. In addition, modeled functions were evaluated for goodness of fit and the statistical significance of their coefficients. RESULTS: NaCl volume and concentration had significant effects on RF-generated heating of the agar phantoms. The mean maximum temperature, 91.4°C ± 0.8 (SD), was reached with 3.5 mL of 10{\%} NaCl gel. This was significantly higher than the mean temperature reached in phantoms containing 0{\%} NaCl gel, 40.3°C ± 4.9 (P < .001). Heat increases to the maximum temperature correlated strongly with the deposited RF energy, with maximum temperatures limited by the current output of the RF generator. The response surface was defined by a generator energy-dependent region and a generator current-limited region, which were best modeled by a modified gamma-variate function and an exponential function, respectively (r2 = 0.92). This model correlated well with previously published in vivo data (r2 = 0.86). CONCLUSION: Modulation of electrical conductivity has different effects on RF ablation response that are dependent on generator capabilities and the volume and concentration of NaCl pretreatment.",
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AU - Lobo, S. Melvyn

AU - Afzal, Karim S.

AU - Ahmed, Muneeb

AU - Kruskal, Jonathan B.

AU - Lenkinski, Robert E.

AU - Goldberg, S. Nahum

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N2 - PURPOSE: To characterize the effects of volume and concentration of adjuvant NaCl pretreatment on radiofrequency (RF) ablation and to model these results to determine their applicability to in vivo systems. MATERIALS AND METHODS: Standardized I-L 5% agar phantoms were constructed with central wells of varying volume that were filled with a protein-based polymer gel of varying NaCl concentration (0%-35%). RF ablation to the maximum system current output (2,000 mA) was applied to internally cooled 2-cm electrodes placed in the center of the gel wells. Remote thermometry was performed 20 mm from the electrode. Temperatures generated within the phantom were then used to model the response surface by using regression analysis. The generated model was then applied to previously published in vivo data to determine its applicability to a porcine liver tissue model. Statistical analyses included one-way analysis of variance to compare the temperatures reached with different NaCl concentrations and volumes with those reached without NaCl. In addition, modeled functions were evaluated for goodness of fit and the statistical significance of their coefficients. RESULTS: NaCl volume and concentration had significant effects on RF-generated heating of the agar phantoms. The mean maximum temperature, 91.4°C ± 0.8 (SD), was reached with 3.5 mL of 10% NaCl gel. This was significantly higher than the mean temperature reached in phantoms containing 0% NaCl gel, 40.3°C ± 4.9 (P < .001). Heat increases to the maximum temperature correlated strongly with the deposited RF energy, with maximum temperatures limited by the current output of the RF generator. The response surface was defined by a generator energy-dependent region and a generator current-limited region, which were best modeled by a modified gamma-variate function and an exponential function, respectively (r2 = 0.92). This model correlated well with previously published in vivo data (r2 = 0.86). CONCLUSION: Modulation of electrical conductivity has different effects on RF ablation response that are dependent on generator capabilities and the volume and concentration of NaCl pretreatment.

AB - PURPOSE: To characterize the effects of volume and concentration of adjuvant NaCl pretreatment on radiofrequency (RF) ablation and to model these results to determine their applicability to in vivo systems. MATERIALS AND METHODS: Standardized I-L 5% agar phantoms were constructed with central wells of varying volume that were filled with a protein-based polymer gel of varying NaCl concentration (0%-35%). RF ablation to the maximum system current output (2,000 mA) was applied to internally cooled 2-cm electrodes placed in the center of the gel wells. Remote thermometry was performed 20 mm from the electrode. Temperatures generated within the phantom were then used to model the response surface by using regression analysis. The generated model was then applied to previously published in vivo data to determine its applicability to a porcine liver tissue model. Statistical analyses included one-way analysis of variance to compare the temperatures reached with different NaCl concentrations and volumes with those reached without NaCl. In addition, modeled functions were evaluated for goodness of fit and the statistical significance of their coefficients. RESULTS: NaCl volume and concentration had significant effects on RF-generated heating of the agar phantoms. The mean maximum temperature, 91.4°C ± 0.8 (SD), was reached with 3.5 mL of 10% NaCl gel. This was significantly higher than the mean temperature reached in phantoms containing 0% NaCl gel, 40.3°C ± 4.9 (P < .001). Heat increases to the maximum temperature correlated strongly with the deposited RF energy, with maximum temperatures limited by the current output of the RF generator. The response surface was defined by a generator energy-dependent region and a generator current-limited region, which were best modeled by a modified gamma-variate function and an exponential function, respectively (r2 = 0.92). This model correlated well with previously published in vivo data (r2 = 0.86). CONCLUSION: Modulation of electrical conductivity has different effects on RF ablation response that are dependent on generator capabilities and the volume and concentration of NaCl pretreatment.

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