Jason T. Fitzgerald

Real-time assessment of in vivo renal ischemia using laser autofluorescence imaging

Potentially transplantable kidneys experience warm ischemia, and this injury is difficult to quantify. We investigate optical spectroscopic methods for evaluating, in real time, warm ischemic kidney injury and reperfusion. Vascular pedicles of rat kidneys are clamped unilaterally for 18 or 85 min, followed by 18 or 35 min of reperfusion, respectively. Contralateral, uninjured kidneys serve as controls. Autofluorescence and cross-polarized light scattering images are acquired every 15 s using 335-nm laser excitation (autofluorescence) and 650+/-20-nm linearly polarized illumination (light scattering). We analyze changes of injured-to-normal kidney autofluorescence intensity ratios during ischemia and reperfusion phases. The effect of excitation with 260 nm is also explored. Average injured-to-normal intensity ratios under 335-nm excitation decrease from 1.0 to 0.78 at 18 min of ischemia, with a return to baseline during 18 min of reperfusion. However, during 85 min of warm ischemia, average intensity ratios level off at 0.65 after 50 min, with no significant change during 35 min of reperfusion. 260-nm excitation results in no autofluorescence changes with ischemia. Cross-polarized light scattering images at 650 nm suggest that changes in hemoglobin absorption are not related to observed temporal behavior of the autofluorescence signal. Real-time detection of kidney tissue changes associated with warm ischemia and reperfusion using laser spectroscopy is feasible. Normalizing autofluorescence changes under 335 nm using the autofluorescence measured under 260-nm excitation may eliminate the need for a control kidney.

Pretransplant recipient cytomegalovirus seropositivity and hemodialysis are associated with decreased renal allograft and patient survival

Background. Pretransplant systemic inflammation has been associated with decreased renal allograft survival, and infectious agents such as cytomegalovi-rus (CMV) may play a role. We hypothesized that pretransplant CMV seropositivity is a risk factor for decreased patient and allograft survival after cadaveric renal transplantation and that other factors believed to modulate systemic inflammation, such as dialysis modality, might act synergistically with CMV to decrease patient and allograft survival. Methods. The United Network for Organ Sharing database was reviewed to identify all patients undergoing cadaveric renal transplantation in the United States from 1988 to 1997. Outcomes for CMV seropositive and seronegative recipients of organs from CMV seronegative donors were analyzed. Subgroup analysis was performed to identify any synergistic influence on outcome between CMV serostatus and known determinants of risk, including degree of human leukocyte antigen mismatch, pretransplant dialysis, and cold ischemia time. Results. Of 29,875 patients who underwent transplantation, 12,239 were CMV seronegative and 17,636 were CMV seropositive. Patient survival was decreased by pretransplant seropositivity (relative risk [RR] 1.11, P =0.001). In addition, this group demonstrated worse overall allograft survival (RR 1.05, P =0.029), although this adverse effect disappeared when patients who died with a functioning graft were censored. Decreased allograft survival was most pronounced in patients who were on hemodialysis before transplantation (RR 1.62, P =0.004). Conclusions. Pretransplant CMV seropositivity is associated with decreased patient survival. Pretransplant CMV seropositivity and hemodialysis have a synergistic adverse effect on graft survival, independent of patient mortality. Additional studies are required to define mechanisms by which pretransplant CMV infection and dialysis modality may contribute to decreased allograft survival.

Pre-transplant elevations of interleukin-12 and interleukin-10 are associated with acute rejection after renal transplantation.

Abstract:  Background:  Methods for predicting patients at higher risk for rejection before transplantation may help improve outcomes. We hypothesized that pre‐transplant elevations of serum interleukin‐12 (IL‐12), a pro‐inflammatory cytokine, would predict acute rejection, while pre‐transplant IL‐10, an immunoregulatory cytokine, would be down‐regulated in patients subsequently experiencing acute rejection.

Spectroscopic imaging for detection of ischemic injury in rat kidneys by use of changes in intrinsic optical properties

It is currently impossible to consistently predict kidney graft viability and function before and after transplantation. We explored optical spectroscopy to assess the degree of ischemic damage in kidney tissue. Tunable UV laser excitation was used to record autofluorescence images, at different spectral ranges, of injured and contralateral control rat kidneys to reveal the excitation conditions that offered optimal contrast. Autofluorescence and near-infrared cross-polarized light-scattering imaging were both used to monitor changes in intensity and spectral characteristics, as a function of exposure time to ischemic injury. These two modalities provided different temporal behaviors, arguably arising from two different mechanisms providing direct correlation of intrinsic optical signatures to ischemic injury time.

Occult pretransplantation systemic inflammation and posttransplantation vascular changes in a primate arterial allograft model

Background. Occult systemic inflammation, as manifested by increased levels of C-reactive protein (CRP), identify patients at increased risk for renal allograft rejection. The mechanisms linking occult systemic inflammation to these adverse outcomes remain unclear. The purpose of this study was to examine the anatomic and physiologic effects of occult pretransplantation systemic inflammation on posttransplantation allograft outcome in a nonhuman primate model. Methods. Seventy-one healthy male Rhesus macaques were stratified into quartiles based on serum CRP. Five high quartile and six low quartile animals underwent common iliac artery transplantation from male donors. Duplex ultrasound measured graft flow at 3 weeks postoperatively; luminal narrowing was assessed by graft/femoral peak systolic velocity ratio. At 6 weeks, the grafts were harvested and morphometry studies were performed. Vessel wall changes were assessed by measuring the intimal medial area. Results. The allografts placed in high CRP quartile animals had more luminal narrowing by 3 weeks than those placed in low quartile animals, as evidenced by a higher mean graft/femoral peak systolic velocity ratio (1.6 vs. 0.90, P=0.006). Morphometry studies after graft harvest showed increased vessel wall area in the high quartile group versus the low quartile group (1.39 mm2 vs. 1.03 mm2, P=0.018). Conclusions. Occult pretransplantation systemic inflammation is associated with increased intimal thickening and stenosis after arterial allograft transplantation in a primate model. Additional studies are needed to confirm these results and to further investigate potential mechanisms linking pretransplantation systemic inflammation to adverse outcomes after transplantation.

Real-time imaging of tissue microstructures using intrinsic optical signatures

We explore imaging of tissue microstructures using autofluorescence and light scattering methods implemented through a hyperspectral microscope design. This system utilizes long working distance objectives that enable off-axis illumination of tissue thereby allowing for excitation at any optical wavelength without requiring change of optical elements within the microscope. Spectral and polarization elements are easily and rapidly incorporated to take advantage of spectral variations of spectroscopic optical signatures for enhanced contrast. The collection efficiency has been maximized such that image acquisition may be acquired within very short exposure times, a key feature for transferring this technology to a clinical setting. Preliminary studies using human and animal tissues demonstrate the feasibility of this approach for real-time imaging of intact tissues as they would appear in the operating room.

Spectroscopic monitoring of kidney tissue ischemic injury

Noninvasive evaluation of tissue viability of donor kidneys used for transplantation is an issue that current technology is not able to address. In this work, we explore optical spectroscopy for its potential to assess the degree of ischemic damage in kidney tissue. We hypothesized that ischemic damage to kidney tissue will give rise to changes in its optical properties which in turn may be used to asses the degree of tissue injury. The experimental results demonstrate that the autofluorescence intensity of the injured kidney is decreasing as a function of time exposed to ischemic injury. Changes were also observed in the NIR light scattering intensities most probably arising from changes due to injury and death of the tissue.

Real time monitoring of renal ischemic injury via optical spectroscopy

We investigate optical spectroscopy methods to correlate with warm ischemia time in hypothermically preserved rat kidneys and in vivo. The objective is to find a practical method for analyzing organ warm ischemic damage before transplantation.