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March 12, 2002; 58 (5) Articles

Bilateral human fetal striatal transplantation in Huntington’s disease

R. A. Hauser, S. Furtado, C. R. Cimino, H. Delgado, S. Eichler, S. Schwartz, D. Scott, G. M. Nauert, E. Soety, V. Sossi, D. A. Holt, P. R. Sanberg, A. J. Stoessl, T. B. Freeman
First published March 12, 2002, DOI: https://doi.org/10.1212/WNL.58.5.687
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Abstract

Background: Transplanted striatal cells have been demonstrated to survive, grow, establish afferent and efferent connections, and improve behavioral signs in animal models of Huntington’s disease (HD).

Objective: To evaluate feasibility and safety and to provide preliminary information regarding the efficacy of bilateral human fetal striatal transplantation in HD.

Methods: Seven symptomatic patients with genetically confirmed HD underwent bilateral stereotactic transplantation of two to eight fetal striata per side in two staged procedures. Tissue was dissected from the lateral half of the lateral ventricular eminence of donors 8 to 9 weeks postconception. Subjects received cyclosporine for 6 months.

Results: Three subjects developed subdural hemorrhages (SDHs) and two required surgical drainage. One subject died 18 months after surgery from probable cardiac arrhythmia secondary to severe atherosclerotic cardiac disease. Autopsy demonstrated clearly demarcated grafts of typical developing striatal morphology, with host-derived dopaminergic fibers extending into the grafts and no evidence of immune rejection. Other adverse events were generally mild and transient. Mean Unified HD Rating Scale (UHDRS) motor scores were 32.9 ± 6.2 at baseline and 29.7 ± 7.5 12 months after surgery (p = 0.24). Post-hoc analysis, excluding one subject who experienced cognitive and motor deterioration after the development of symptomatic bilateral SDHs, found that UHDRS motor scores were 33.8 ± 6.2 at baseline and 27.5 ± 5.2 at 12 months (p = 0.03).

Conclusions: Transplantation of human fetal striatal cells is feasible and survival of transplanted cells was demonstrated. Patients with moderately advanced HD are at risk for SDH after transplantation surgery.

Huntington’s disease (HD) is a progressive and fatal neurodegenerative disorder caused by increased CAG repeats in the huntingtin gene.1 This mutation results in a polyglutamine expansion in the N-terminal region of huntingtin protein and leads to neuronal degeneration predominantly affecting medium spiny projection neurons in the putamen and caudate nucleus.2 The mechanism by which polyglutamine expansion causes neuronal death is not completely elucidated, but recent work suggests that abnormal interactions with proteins containing short polyglutamine stretches, such as CREB binding protein (CBP), interfere with gene transcription necessary for cell survival.3 Clinically, patients experience motor impairments including chorea and imbalance, cognitive decline, and psychiatric disturbances. No intervention is currently known to slow, stop, or reverse the progressive clinical deterioration or underlying neurodegeneration.

Transplanted fetal neurons lacking the HD mutation may be able to replace lost host neurons, reconstitute neuronal circuitry, and provide clinical benefit.4-6 In animal models, transplanted striatal cells have been demonstrated to survive, grow, establish afferent and efferent connections, and improve behavioral signs analogous to those of HD.7-11 Normal development of striatal grafts, connectivity with host brain, and behavioral improvement in a rodent model of HD have been described using human donor grafts from either the lateral ventricular eminence8,12-14 or the far lateral ventricular eminence.15,16 In primate models, striatal allografts and xenografts have been shown to survive and improve motor and cognitive function.17-19

Evidence suggests that human fetal striatal grafts may survive transplantation and induce clinical benefit in patients with HD.4,16 In patients with PD, human fetal nigral transplantation provides antiparkinsonian effects,20,21 and long-term graft survival22-24 without evidence of immune rejection25 has been demonstrated. HD is also an attractive target for transplantation in that the area of predominant degeneration (striatum) is relatively small and accessible. Further, it is anticipated that transplanted fetal allogenic striatal cells lacking the HD mutation would not be adversely affected by the host disease because the HD mutation appears to cause neuronal death through an intracellular process. In addition, the pathologic process is not normally expressed in fetal or early prenatal stages of development, even in cells with the HD mutation.

Based on these considerations and the lack of any treatment known to mitigate the progression of the underlying disease process, we initiated a clinical trial of fetal striatal tissue transplantation for the treatment of HD. This was an open-label pilot study aimed at evaluating the feasibility and safety of this procedure and providing preliminary information regarding the efficacy of this novel therapy.

Methods.

Subject selection, enrollment, and evaluation were performed according to a modified version of a standardized protocol (Core Assessment Program for Intracerebral Transplantation in Huntington’s Disease [CAPIT-HD]).26 Consecutive patients who met eligibility criteria and who were willing to provide informed consent were enrolled in the study. Subjects were required to meet inclusion and exclusion criteria at entry and before surgery. Functionally independent adults (aged >18 years) with neurologic signs consistent with HD and with genetic confirmation (trinucleotide repeat length >37)27 were eligible to participate. Exclusion criteria included dementia that would preclude providing informed consent and clinically remarkable medical or laboratory abnormalities (including serum creatinine concentration >1.8 mg/dL, or HIV-1, HIV-2, or HTLV-1 antibody positive). All subjects provided written informed consent before entering the study, before PET scanning, and before each surgery.

Subjects underwent clinical evaluations every 3 months for 1 year before surgery (−12,−9, −6,−3, and 0 months) and at 1, 3, 6, 9, and 12 months after surgery. Attempts were made to maintain medications unchanged throughout the study. Clinical evaluations included the Unified HD Rating Scale (UHDRS)28 and a battery of neuropsychological tests. Alternate forms of neuropsychological tests were used when available. All neuropsychological raw scores were converted to z scores for analysis to correct for age, sex, and education, where available.

Subjects underwent PET scanning to assess regional glucose metabolism and dopamine D1 and D2 receptor binding before and 6 to 18 months after surgery. All scans were performed on a Siemens/CTI 953B tomograph (Knoxville, TN) in three-dimensional mode, with an in-plane resolution of 5.6 mm and a slice thickness of 3.4 mm. Reconstruction with corrections for scatter and normalization was achieved as previously described.29

Dopamine D1 receptor binding was assessed following injection of 185 MBq of [11C]SCH 23390 (specific activity > 37 GBq/mmol) administered by IV bolus over 60 seconds. Dopamine D2 receptor binding was assessed following the injection of 185 MBq of [11C]raclopride (specific activity > 70 GBq/mmol) administered by IV bolus over 60 seconds. Sixteen PET scans were obtained over 60 minutes, starting at the midpoint of tracer injection. Regional glucose metabolism was determined using [18F]2-fluoro-2-deoxy-D-glucose (FDG). A total of 185 MBq of FDG was administered via an IV cannula over 60 seconds. Beginning 40 minutes after FDG administration, two PET scans were obtained, each of 10 minutes’ duration.

Fetal striatal tissue was transplanted stereotactically in two staged procedures. Subjects received cyclosporine 6 mg/kg/day beginning 7 days before the first operation and continuing through 14 days after the second (contralateral) operation. The cyclosporine dose was then reduced to 2 mg/kg/day for 6 months and then discontinued. Serum creatinine concentration was monitored monthly and cyclosporine dosages were reduced if creatinine concentration increased above normal.

Embryonic tissue was obtained in accordance with state, federal, and NIH guidelines and stored as previously described.30,31 The developing striatum was dissected from the lateral half of the lateral ventricular eminence of donors 8 to 9 weeks postconception.12,15,16 Each striatum was dissected into 0.5-1 mm3 pieces and deposited along a needle tract 9 to 15 mm in height. Deposits were separated by up to 5 mm in a three-dimensional array. Two to eight donor striata were implanted into each host striatum. The amount of tissue implanted depended on donor tissue availability. The primary goal was to transplant into the “motor” striatum (postcommissural putamen).30 Transplantation into striatal areas associated with cognitive function (caudate nucleus and precommissural putamen) was also performed if sufficient tissue was available.4,20,32

Beginning at the time of surgery, subjects received antibiotics to provide prophylaxis against routine vaginal flora.33 These included piperacillin 3 grams IV every 6 hours, vancomycin 1 gram IV every 12 hours, and fluconazole 100 milligrams by mouth every day, for 3 days. Donor tissue samples and all reagents were cultured to determine the need for additional antibiotic therapy.

Experimental surgery and hospitalization were provided without cost to the subjects. Costs to subjects were approximately $20,000 to cover nonfunded aspects of the study, including travel expenses for subjects and spouses, PET and MRI scans, cyclosporine, and home health administration of antibiotics.

Analyses.

Twelve-month neurologic and neuropsychological scores were compared to presurgery baseline (last evaluation before first surgery) using a Wilcoxon sign rank test. The annual rate of change was calculated for pre- and postsurgery scores using the least squares method and the postsurgery rates of change were compared to presurgery rates of change using a Wilcoxon sign rank test.

D1 and D2 PET scans were analyzed using a graphical analysis with a tissue (cerebellar) input function.34 FDG data were analyzed using a region of interest template and literature values for rate constants.35 Pre- and postsurgery PET values were compared using a Wilcoxon sign rank test. Correlations between changes in UHDRS motor scores and changes in pre- and postsurgery PET values were assessed using Spearman’s rank correlation.

Change in UHDRS motor scores was chosen a priori as the primary efficacy variable and α was set at 0.05. Because this was a pilot study, no adjustments were made for multiple comparisons and p values for additional evaluations were derived for descriptive purposes only.

Results.

Seven subjects (six women, one man) underwent transplantation and have been followed up for 12 months. An additional subject entered the clinical evaluation phase of the study but did not meet eligibility criteria for surgery because she became nonambulatory and developed dementia that precluded providing informed consent for surgery.

For the seven subjects undergoing transplantation, mean (±SD) expanded CAG repeat length was 44.4 ± 4.2 (range, 42 to 53; table 1). Age at time of transplantation was 50.1 ± 12.4 years (range, 28 to 64 years) and time from diagnosis to first surgery was 5.9 ± 3.5 years (range, 2 to 12 years). Subjects received 4.5 ± 1.2 (range, 2 to 6) striata implanted into each putamen and 1.1 ± 0.5 (range, 0 to 2) striata implanted into each caudate nucleus. All subjects had the second procedure within 4 weeks of the first procedure, except Subject 6, for whom 14 weeks elapsed between surgical procedures owing to lack of tissue availability.

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Table 1.

Demographics and patient information

None of the subjects received dopamine antagonists or depletors during the study. Three subjects (Subjects 2, 6, and 7) received selective serotonin reuptake inhibitors (SSRIs) at stable doses (fluoxetine 40 mg/day, sertraline 200 mg/day, fluoxetine 20 mg/day). Subject 1 was initially taking fluoxetine 20 mg/day; she discontinued taking it 6 months before her first operation. Subject 5 was initially taking trazodone 50 mg/day and the dosage was increased to 150 mg/day 9 months after second surgery.

Adverse events.

In the immediate postoperative period, three subjects experienced mild headache, nausea, and vomiting (Subjects 1, 2, and 7). In addition, two reported mild constipation (Subjects 1 and 7) and one noted fatigue (Subject 3). Subject 6 noted mild intermittent nausea for 6 weeks after her first operation.

Three subjects received additional antibiotics. Subject 6 received piperacillin 2 grams IV every 6 hours for 2 weeks after identification of a transport media contaminant, Alcaligenes dentrificans. Subject 7 experienced a fever of 38.5 °C and one donor tissue culture yielded Viridans streptococci in anaerobic broth and Candida albicanson fungal culture. The streptococcus was thought to be a laboratory contaminant and the candida was likely derived from vaginal flora. The subject received a 2-week course of fluconazole 200 mg/day by mouth and vancomycin 700 mg IV every 12 hours, and her fever resolved on postoperative day 3. Subject 2 had a superficial wound infection when the staples from his first procedure were removed at the time of the second (contralateral) operation 1 week later. This infection yielded a positive culture for a methicillin-sensitive Staphylococcus epidermidis species. The subject was treated with vancomycin 800 mg IV every 12 hours for 2 weeks. He had a fever of 38.2 °C for 2 days, followed by resolution. While taking vancomycin, he developed profuse diarrhea. Stool samples were negative for Clostridium difficile toxin, but he was treated empirically with metronidazole 250 mg by mouth four times a day for 10 days with resolution of diarrhea over 72 hours.

Three subjects developed intracranial hemorrhages. Subject 3 was moderately confused for 2 weeks after her first operation. CT scanning revealed a superficial 1 cm cortical hemorrhage in the left frontal (putamenal) needle tract. MRI just before her second operation demonstrated a small, thin subdural hemorrhage (SDH) over the left hemisphere with minimal mass effect. She improved clinically and the SDH was resolved on CT 2 months after the first operation. Subject 1 developed an asymptomatic 2-cm-thick SDH ipsilateral to the first transplant procedure, extending from the floor of the middle cranial fossa to the convexity. This was identified on MRI just before the second transplant operation and was evacuated immediately after the transplant procedure without incident.

Subject 5 developed symptomatic bilateral SDHs following her second transplant operation. Initial MRI after surgery demonstrated bilateral 1 cm subdural hygromas without blood. She and her husband reported that she was doing well after surgery with clear-cut improvement in mobility and chorea. She fell 2 weeks after the second operation while maneuvering around furniture, hit the couch, and then fell to the floor, striking her head. She was reported to be unconscious for 1 to 2 minutes and was taken to a local hospital, where a CT scan of the head was performed. This demonstrated bilateral subdural hygromas, unchanged from her postoperative MRI. Clinically, she initially recovered but she then experienced a progressive decline in mobility and cognition. Repeat CT scanning (6 weeks after her second procedure) revealed bilateral SDHs, 2.5 cm thick on the right side and 1 cm thick on the left. These were evacuated using bilateral burr holes and chronic liquified blood was drained. CT scanning 1 month later demonstrated resolution of SDHs. She improved partially after evacuation of SDHs, but did not regain baseline status and subsequently experienced the worst clinical course of the seven subjects.

Subject 2 required adjustment of his cyclosporine dose. His blood urea nitrogen and creatinine levels increased from 17 mg/dL and 1.0 mg/dL before cyclosporine administration to 39 mg/dL and 3.1 mg/dL 6 weeks after cyclosporine initiation. The cyclosporine dosage was reduced to 2 mg/kg/day for 2 days and IV hydration was provided. Laboratory values returned to normal within 24 hours. He underwent the second operation on the reduced cyclosporine dose, which was then increased to 4 mg/kg/day for 2 weeks and further reduced in the usual manner.

Subject 5 experienced depression. Her mood worsened 9 months after second operation and her trazodone dose was increased from 50 to 150 mg/day.

Subject 2 died suddenly approximately 18 months after his second transplantation procedure. Autopsy revealed early bronchogenic pneumonia, acute and chronic aspiration, severe (>90% occlusion) three-vessel coronary artery disease without myocardial infarction, and severe peripheral vascular disease. The likely cause of death was sudden cardiac arrhythmia secondary to severe atherosclerotic cardiac disease. Results of histologic postmortem evaluation are reported elsewhere.6 In brief, clearly demarcated grafts of typical developing striatal morphology occupied 9.8% of the left caudate–putamen and 7.6% of the right caudate–putamen. Host-derived dopaminergic fibers extended into the grafts. There was no evidence of immune rejection or abnormal expression of mutated huntingtin protein within the fetal allografts.

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Table 2.

UHDRS* motor scores at baseline and 12 months

Efficacy.

Results of neurologic and neuropsychological evaluations are presented in tables 2 through 4. Mean UHDRS motor scores were 32.9 ± 6.2 at baseline and 29.7 ± 7.5 at 12 months (p = 0.24). The mean annual rate of UHDRS motor score worsening was 5.7 ± 5.3 units per year pretransplant and 1.8 ± 8.9 units per year post-transplant (p = 0.31; figure 1). Mean total functional capacity (TFC) scores were 6.6 ± 1.0 at baseline and 7.0 ± 2.2 at 12 months (p = 0.46). The mean annual rate of TFC score change was −1.1 ± 1.7 units per year pretransplant and +0.25 ± 1.3 units per year post-transplant (p = 0.06; figure 2).

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Table 3.

Neurologic scores at baseline and 12 months after transplantation

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Table 4.

Neuropsychological tests at baseline and 12 months after transplantation

Figure

Figure 1. Individual subject Unified Huntington’s disease Rating scale (UHDRS) motor scores before (left) and after (right) transplantation. Mean (heavy) line calculated using mean slopes and intercepts from least squares line for each subject. Black diamonds = Subject 1; black squares = Subject 2; black triangles = Subject 3; open squares = Subject 4; open circles = Subject 5; black circles = Subject 6; open triangles = Subject 7.

Figure

Figure 2. Individual subject total functional capacity (TFC) scores before (left) and after (right) transplantation. Mean (heavy) line calculated using mean slopes and intercepts from least squares line for each subject. Black diamonds = Subject 1; black squares = Subject 2; black triangles = Subject 3; open squares = Subject 4; open circles = Subject 5; black circles = Subject 6; open triangles = Subject 7.

A post-hoc subgroup analysis was performed excluding Subject 5, who experienced cognitive and motor deterioration after the development of symptomatic bilateral SDHs. In the remaining six subjects, UHDRS motor scores were 33.8 ± 6.2 at baseline and 27.5 ± 5.2 at 12 months (p = 0.03).

PET.

PET scans were obtained a mean of 11.1 ± 4.1 months (range, 6 to 18 months) after the second transplant procedure. Group results are presented in table 5. Lentiform regional glucose metabolism was 4.56 ± 0.55 mg/100 g tissue/minute at baseline and 4.63 ± 0.49 mg/100 g tissue/minute at follow-up (p = 1.00). Putamenal D1 receptor binding was 1.39 ± 0.18 at baseline and 1.44 ± 0.16 at follow-up (p = 0.74). Change in UHDRS motor scores correlated most closely with changes in D1 receptor binding in the caudate nucleus (Spearman’s rank correlation = 0.667, p = 0.05) and putamen (Spearman’s rank correlation = 0.655, p = 0.06).

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Table 5.

Results of pre- and post-transplantation PET scan evaluations

Discussion.

SDHs were the most notable adverse events observed in this study. Two subjects developed a total of three SDHs that required surgical evacuation out of a total of 14 transplant procedures. Intraoperative CSF loss causes brain “shrinkage” and shift in patients with cerebral atrophy.5 This leads to targeting difficulties6 and expands the subdural space, thereby predisposing to postoperative SDHs. This safety profile differs dramatically from similar transplant procedures in subjects with advanced PD who typically lack the degree of atrophy seen in even moderate HD. In the same surgeon’s experience (T.F.), no surgically relevant SDH occurred in 66 PD transplant procedures. The incidence of SDH after transplantation in HD might be reduced in the future by the use of drains placed at the time of surgery or the intraoperative use of fibrin glue to cover the burr hole and minimize CSF loss during surgery. However, the risk of SDH may be directly related to the degree of cerebral atrophy. This poses substantial safety concerns and leads us to believe that if further trials are undertaken they should be performed in patients with less atrophy.

One patient died 18 months post-transplantation of an apparent cardiac arrhythmia in the setting of underlying severe three-vessel coronary artery disease and aspiration pneumonia. His death was most likely unrelated to transplantation, although we cannot exclude the possibility that surgery could have worsened swallowing function, leading to aspiration and resulting in an arrhythmia. An accurate and reliable assessment of the effect of transplantation on mortality would require a large, randomized, controlled, and blinded study.

We have demonstrated that fetal striatal tissue transplantation in HD is possible and that transplanted cells can survive for up to 18 months after transplantation and 12 months after discontinuation of cyclosporine.6 In the patient who died, clearly demarcated grafts of typical developing striatal morphology were seen on autopsy, with host-derived dopaminergic fibers extending into the grafts. There was no evidence of immune rejection or abnormal expression of mutated huntingtin protein within the fetal allografts. Thus, the disease process did not appear to adversely affect the grafts.

It is not clear that cyclosporine is necessary for graft survival. We have demonstrated survival of transplanted human embryonic cells for 12 months after cyclosporine discontinuation in both HD and PD.6,23-25 At the doses used, cyclosporine appears to be well tolerated, although creatinine concentrations must be monitored and cyclosporine dosages adjusted as appropriate.

HD is associated with progressive clinical decline. One study36 found a worsening in UHDRS motor scores of 5.97 units per year and a mean rate of decline in TFC scores of 0.56 units per year in a group of 78 patients with HD with a mean age of symptom onset of 37.7 years and a mean duration of illness of 6.7 years. Another study37 found a mean annual rate of TFC score decline of 0.97 units per year in 575 patients with HD with baseline TFC scores of 7 to 13.

In our subjects, no significant changes were observed in UHDRS motor scores from baseline to 12 months. However, a lack of significant worsening might reflect clinical benefit in a progressive neurodegenerative disease. Nonetheless, we did not definitively demonstrate a lack of significant worsening owing to the small number of subjects and the open-label design of the study. We also cannot exclude the influence of random chance, bias, or placebo effects. Comparisons to historical control subjects are of limited usefulness. This problem is compounded by the fact that worsening is not linear throughout the disease. Patients in earlier stages decline faster than patients with more advanced disease.37

We also performed a post-hoc subgroup analysis excluding Subject 5. This subject and her husband reported that she initially improved after her second transplant procedure but experienced motor and cognitive deterioration after a fall that resulted in the development of symptomatic bilateral SDHs. She improved partially after evacuation of SDHs but did not return to baseline status and subsequently exhibited the worst clinical course of the seven subjects. It is our impression that her relatively poor outcome was related to her SDHs rather than to the transplantation per se. If the transplantation procedure can be modified to avoid SDHs in the future, the group results excluding this subject may be more representative of the potential clinical outcome that might be achieved with striatal transplantation. In this group of six subjects, UHDRS motor scores were 33.8 ± 6.2 at baseline and 27.5 ± 5.2 at 12 months (p = 0.03). However, this is a post-hoc analysis and we cannot be certain that the excluded subject would have done better if she had not experienced SDHs.

PET studies of patients with HD have found that striatal glucose metabolism and dopamine receptor binding decrease. One study38 found a mean annual decline of nearly 7% in striatal glucose metabolic activity and another39 found a mean annual decline of 5% in striatal D1 binding. In our study, maintenance of lentiform metabolic activity and putamenal D1 binding may suggest survival of region-appropriate transplanted neurons, but this remains to be proven. In the caudate nucleus, lack of maintenance of glucose metabolism and D1 and D2 binding may be a function of the limited quantity of tissue transplanted into this area. The reason for the lack of maintenance of putamenal D2 binding is unclear but may potentially relate to selective survival of transplanted neurons or differences in the time course or capacity for expression of these receptors.

Other investigators have reported clinical benefit after neural transplantation in HD.32,40,41 One study32 reported motor and cognitive improvement or maintenance and increased striatal glucose metabolism on PET in three of five transplanted patients at 2 years. However, group analyses were not performed. Another study40 reported some improvements in measures of visuoperceptual/conceptual skills, learning and memory, and executive functions in three patients 6 months after transplantation. It is difficult to compare clinical results across these studies because of their descriptive nature and the small number of subjects. Generally, in both series some patients improved and some worsened on various clinical measures and there was no consistent pattern of change across subjects. However, the association of clinical improvement with increased metabolic activity on PET as observed in one study32 suggests that the improvements may be graft related.

There were several important methodologic differences between our transplantation procedure and those of other investigators.32 We transplanted tissue from a very restricted dissection of the developing striatum and only utilized the far lateral aspect of the lateral ventricular eminence.6,16 In an effort to implant sufficient tissue, two to eight developing striata were transplanted per side. Other investigators used a nonselective dissection consisting of the entire ventricular eminence, which is much larger and includes not only the developing striatum but also numerous other brain regions.12 Owing to the comparatively large size of the whole ventricular eminence, these investigators transplanted approximately one striata per side. It is not known what the impact of these differences in dissection may be on mechanism (i.e., connectivity with host vs graft-induced trophic effects) or clinical outcome.4,16 Despite our use of multiple donors, only 8 to 10% of the striatal region transplanted in our autopsy case was occupied by graft material.6 We have not found it possible to obtain eight or more satisfactory33 fetal striatal grafts on a consistent basis. If a large amount of graft tissue is required for optimal results, less specific dissection techniques or striatal cell proliferation methods will be required.

We also distributed tissue differently than other investigators.32 In our trial, tissue was transplanted predominantly into the postcommissural putamen, which is primarily involved in motor circuits.20,30 Additional tissue was placed in the anterior putamen and caudate nucleus if available. These areas are primarily associated with cognitive and neuropsychological function.4,19,20 In contrast, other investigators32 distributed approximately 80% of transplanted tissue into the precommissural putamen and caudate nucleus. It may be important to transplant sufficient tissue into both the anterior and posterior striatum to optimize clinical benefit.

We speculate that striatal transplantation may provide a better benefit to risk ratio if performed earlier in the disease. From a safety perspective, we expect this would reduce the risk of SDH and improve surgical targeting accuracy related to atrophy-associated intraoperative CSF loss.6 Early grafting may also improve efficacy because less gliosis may provide a better “transplant milieu” for graft survival. In our HD subject who died 18 months after transplantation, autopsy revealed grade II disease42 and only 6 of 10 transplant tracts survived, even though there was no evidence of immune rejection.6 In comparison, autopsies revealed 100% of grafts survived in our two subjects with PD who died.23-25 Grafts may also provide trophic support to the host brain to prevent or slow further striatal and second-order degeneration in remote sites.4,6,16,43-45 This potential but unproven benefit would likely be most valuable before extensive neuronal loss has occurred.

Acknowledgments

Supported in part by Tampa General Healthcare and the Hereditary Disease Foundation.

Acknowledgment

The authors thank Dr. Thomas Mueller for his assistance with genetic testing, and Dr. T. Ruth and members of the University of British Columbia–Tri University Meson Facility PET team.

Footnotes

  • See also page 675

  • Received July 17, 2001.
  • Accepted November 16, 2001.

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