Characterization of a novel phantom for three-dimensional in vitro cell experiments.

A novel intensity-modulated radiation therapy (IMRT) phantom for use in three-dimensional in vitro cell experiments, based on a commercially available system (CIRS Inc., Norfolk, VA), was designed and fabricated. The water-equivalent plastic phantom can, with a set of water-equivalent plastic inserts, enclose 1-3 multi-well tissue culture plates. Dosimetry within the phantom was assessed using thermoluminescence dosimeters (TLDs) and film. The phantom was loaded with three tissue culture plates, and an array of TLDs or a set of three films was placed underneath each plate within the phantom, and then irradiated using an IMRT plan created for it. Measured doses from each dosimeter were compared to those acquired from the treatment planning system. The percent differences between TLD measurements and the corresponding points in the treatment plan ranged from 1.3% to 2.9%, differences which did not show statistical significance. Average point-by-point percent dose differences for each film plane ranged from 1.6% to 3.1%. The percentage dose difference for which 95% of the points in the film matched those corresponding to the calculated dose plane to within 3.0% ranged from 2.8% to 4.2%. The good agreement between predicted and measured dose shows that the phantom is a useful and efficient tool for three-dimensional in vitro cell experiments.

Fluorodeoxyglucose positron emission tomography response and normal tissue regeneration after stereotactic body radiotherapy to liver metastases.

PURPOSE: To characterize changes in standardized uptake value (SUV) in positron emission tomography (PET) scans and determine the pace of normal tissue regeneration after stereotactic body radiation therapy (SBRT) for solid tumor liver metastases. METHODS AND MATERIALS: We reviewed records of patients with liver metastases treated with SBRT to ≥40 Gy in 3-5 fractions. Evaluable patients had pretreatment PET and ≥1 post-treatment PET. Each PET/CT scan was fused to the planning computed tomography (CT) scan. The maximum SUV (SUV(max)) for each lesion and the total liver volume were measured on each PET/CT scan. Maximum SUV levels before and after SBRT were recorded. RESULTS: Twenty-seven patients with 35 treated liver lesions were studied. The median follow-up was 15.7 months (range, 1.5-38.4 mo), with 5 PET scans per patient (range, 2-14). Exponential decay curve fitting (r=0.97) showed that SUV(max) declined to a plateau of 3.1 for controlled lesions at 5 months after SBRT. The estimated SUV(max) decay half-time was 2.0 months. The SUV(max) in controlled lesions fluctuated up to 4.2 during follow-up and later declined; this level is close to 2 standard deviations above the mean normal liver SUV(max) (4.01). A failure cutoff of SUV(max) ≥6 is twice the calculated plateau SUV(max) of controlled lesions. Parenchymal liver volume decreased by 20% at 3-6 months and regenerated to a new baseline level approximately 10% below the pretreatment level at 12 months. CONCLUSIONS: Maximum SUV decreases over the first months after SBRT to plateau at 3.1, similar to the median SUV(max) of normal livers. Transient moderate increases in SUV(max) may be observed after SBRT. We propose a cutoff SUV(max) ≥6, twice the baseline normal liver SUV(max), to score local failure by PET criteria. Post-SBRT values between 4 and 6 would be suspicious for local tumor persistence or recurrence. The volume of normal liver reached nadir 3-6 months after SBRT and regenerated within the next 6 months.

Normal liver tissue density dose response in patients treated with stereotactic body radiation therapy for liver metastases.

PURPOSE: To evaluate the temporal dose response of normal liver tissue for patients with liver metastases treated with stereotactic body radiation therapy (SBRT). METHODS AND MATERIALS: Ninety-nine noncontrast follow-up computed tomography (CT) scans of 34 patients who received SBRT between 2004 and 2011 were retrospectively analyzed at a median of 8 months post-SBRT (range, 0.7-36 months). SBRT-induced normal liver tissue density changes in follow-up CT scans were evaluated at 2, 6, 10, 15, and 27 months. The dose distributions from planning CTs were mapped to follow-up CTs to relate the mean Hounsfield unit change (ΔHU) to dose received over the range 0-55 Gy in 3-5 fractions. An absolute density change of 7 HU was considered a significant radiographic change in normal liver tissue. RESULTS: Increasing radiation dose was linearly correlated with lower post-SBRT liver tissue density (slope, -0.65 ΔHU/5 Gy). The threshold for significant change (-7 ΔHU) was observed in the range of 30-35 Gy. This effect did not vary significantly over the time intervals evaluated. CONCLUSIONS: SBRT induces a dose-dependent and relatively time-independent hypodense radiation reaction within normal liver tissue that is characterized by a decrease of >7 HU in liver density for doses >30-35 Gy.

Stereotactic body radiation therapy for melanoma and renal cell carcinoma: impact of single fraction equivalent dose on local control.

BACKGROUND: Melanoma and renal cell carcinoma (RCC) are traditionally considered less radioresponsive than other histologies. Whereas stereotactic body radiation therapy (SBRT) involves radiation dose intensification via escalation, we hypothesize SBRT might result in similar high local control rates as previously published on metastases of varying histologies. METHODS: The records of patients with metastatic melanoma (n = 17 patients, 28 lesions) or RCC (n = 13 patients, 25 lesions) treated with SBRT were reviewed. Local control (LC) was defined pathologically by negative biopsy or radiographically by lack of tumor enlargement on CT or stable/declining standardized uptake value (SUV) on PET scan. The SBRT dose regimen was converted to the single fraction equivalent dose (SFED) to characterize the dose-control relationship using a logistic tumor control probability (TCP) model. Additionally, the kinetics of decline in maximum SUV (SUVmax) were analyzed. RESULTS: The SBRT regimen was 40-50 Gy/5 fractions (n = 23) or 42-60 Gy/3 fractions (n = 30) delivered to lung (n = 39), liver (n = 11) and bone (n = 3) metastases. Median follow-up for patients alive at the time of analysis was 28.0 months (range, 4-68). The actuarial LC was 88% at 18 months. On univariate analysis, higher dose per fraction (p < 0.01) and higher SFED (p = 0.06) were correlated with better LC, as was the biologic effective dose (BED, p < 0.05). The actuarial rate of LC at 24 months was 100% for SFED ≥45 Gy v 54% for SFED <45 Gy. TCP modeling indicated that to achieve ≥90% 2 yr LC in a 3 fraction regimen, a prescription dose of at least 48 Gy is required. In 9 patients followed with PET scans, the mean pre-SBRT SUVmax was 7.9 and declined with an estimated half-life of 3.8 months to a post-treatment plateau of approximately 3. CONCLUSIONS: An aggressive SBRT regimen with SFED ≥ 45 Gy is effective for controlling metastatic melanoma and RCC. The SFED metric appeared to be as robust as the BED in characterizing dose-response, though additional studies are needed. The LC rates achieved are comparable to those obtained with SBRT for other histologies, suggesting a dominant mechanism of in vivo tumor ablation that overrides intrinsic differences in cellular radiosensitivity between histologic subtypes.

Validation of temporal optimization effects for a single fraction of radiation in vitro.

PURPOSE: To experimentally validate how temporal modification of the applied dose pattern within a single fraction of radiation therapy affects cell survival. METHOD AND MATERIALS: Using the linear-quadratic model, we have previously demonstrated that the greatest difference in cell survival results from comparing a temporal dose pattern delivering the highest doses during the middle of a fraction and the lowest at the beginning and end ("Triangle") to one with the lowest doses at the middle and the highest at the beginning and end ("V-shaped"). Also, these differences would be greatest in situations with low alpha/beta and large dose/fraction and fraction length. Two low (WiDr, PC-3) and one high (SQ-20B) alpha/beta cell lines were irradiated in six-well plates with 900 cGy over 20 min (900 cGy/20 min), one each with a Triangle and V-shaped dose pattern. WiDr cells were subjected to the same experiments with first 180 cGy/20 min, then 900 cGy/5 min. Cell survival was assessed using the clonogenic assay. RESULTS: At 900 cGy/20 min, irradiation with a V-shaped pattern resulted in an increased survival compared with use of a Triangle pattern of 21.2% for WiDr (p < 0.01), 18.6% for PC-3 (p < 0.025), and 4.7% for SQ-20B cells (p > 0.05). For WiDr cells at 180 cGy/20 min, this increase reduced to 2.7% (p > 0.05) and to -0.8% (p > 0.05) at 900 cGy/5 min. CONCLUSIONS: These results verify the assertions of the modeling study in vitro, and imply that the temporal pattern of applied dose should be considered in treatment planning and delivery.

Antisense to transforming growth factor-beta1 messenger RNA reduces vein graft intimal hyperplasia and monocyte chemotactic protein 1.

BACKGROUND: Autogenous vein grafts are commonly used for arterial reconstructive procedures. Their success is limited by the development of intimal hyperplasia (IH), a fibroproliferative disease that predisposes the grafts to occlusive stenosis. Mesenchymal cell proliferation and the deposition of an extracellular matrix characterize neointimal development. Increasing evidence suggests that, regardless of blood vessel type, IH results from complex interactions among vessel wall cells, infiltrating leukocytes, and cytokines. Transforming growth factor-beta1 (TGF-beta1) is a pleiotropic cytokine with powerful effects on inflammatory cell chemotaxis; smooth muscle cell, fibroblast, and endothelial cell proliferation; and extracellular matrix synthesis. METHODS: Epigastric vein to common femoral artery interposition grafts were placed in male Lewis rats and harvested at 1, 2, 4, and 12 weeks after surgery. We used replication-defective adenoviruses to deliver a control reporter gene for the enzyme beta-galactosidase (Ad-GAL), empty virus (Ad-CMVpLpA), or the sequence encoding the antisense strand of TGF-beta1 (Ad-AST). The vein graft was transduced passively in medium containing 10 7 plaque-forming units per milliliter of Ad-GAL, Ad-CMVpLpA, or Ad-AST for 20 minutes at room temperature. The adenovirus-treated grafts were compared with grafts treated with medium without virus (sham). RESULTS: The Ad-GAL control grafts showed beta-galactosidase activity from 3 days to 4 weeks. Twenty percent of cells were positive out to 2 weeks, at which time the number of cells positive for beta-galactosidase activity began to decline. Treatment with Ad-AST resulted in a significant reduction vs sham, Ad-CMVpLpA, and Ad-GAL in TGF-beta1 messenger RNA, total TGF-beta1 protein, and bioactive TGF-beta1 protein. Neointimal area was significantly reduced in the Ad-AST group vs Ad-GAL at 4 weeks, vs Ad-CMVpLpA at 4 and 12 weeks, and vs sham at 2 and 4 weeks. The medial/adventitial layer was significantly thicker in the Ad-AST group than the Ad-GAL group at 12 weeks. In addition, we studied the effect of Ad-AST on monocyte chemotactic protein 1 (MCP-1). Although the reduction in TGF-beta1 resulted in a reduction of MCP-1 messenger RNA in whole-graft homogenates and MCP-1 protein-positive staining in histologic sections from the perianastomotic region, no reduction in the number of ED1-positive cells (monocytes and macrophages) was observed. CONCLUSIONS: Perioperative antisense TGF-beta1 treatment of the vein to be used in arterial reconstructions resulted in a prolonged diminution of IH; this emphasizes the importance of TGF-beta1 in neointimal thickening and indicates that ex vivo gene therapy can reduce the vessel's predisposition to IH. CLINICAL RELEVANCE: The main cause of occlusion and graft failure after peripheral and cardiac arterial reconstruction is IH. The study of the mechanisms and mediators of IH, including TGF-beta1, should lead to future gene therapies to prevent or limit IH. The clinical effect of such treatments would be enormous, because they would increase graft longevity, thereby enhancing quality of life and enabling patients to live without the threat of limb loss or recurrent heart attack.