Mortality, morbidity, and organ failure are important and common serious harms after surgery. However, there are many candidate measures to describe these outcome domains. Definitions of these ...measures are highly variable, and validity is often unclear. As part of the International Standardised Endpoints in Perioperative Medicine (StEP) initiative, this study aimed to derive a set of standardised and valid measures of mortality, morbidity, and organ failure for use in perioperative clinical trials.
Three domains of endpoints (mortality, morbidity, and organ failure) were explored through systematic literature review and a three-stage Delphi consensus process using methods consistently applied across the StEP initiative. Reliability, feasibility, and patient-centredness were assessed in round 3 of the consensus process.
A high level of consensus was achieved for two mortality time points, 30-day and 1-yr mortality, and these two measures are recommended. No organ failure endpoints achieved threshold criteria for consensus recommendation. The Clavien–Dindo classification of complications achieved threshold criteria for consensus in round 2 of the Delphi process but did not achieve the threshold criteria in round 3 where it scored equivalently to the Post Operative Morbidity Survey. Clavien–Dindo therefore received conditional endorsement as the most widely used measure. No composite measures of organ failure achieved an acceptable level of consensus.
Both 30-day and 1-yr mortality measures are recommended. No measure is recommended for organ failure. One measure (Clavien–Dindo) is conditionally endorsed for postoperative morbidity, but our findings suggest that no single endpoint offers a reliable and valid measure to describe perioperative morbidity that is not dependent on the quality of deli-vered care. Further refinement of current measures, or development of novel measures, of postoperative morbidity might improve consensus in this area.
Abstract Background Mobile phones play a central role in the lives of young people and are being increasingly recognized as valuable tools in health care. However, there is a paucity of studies ...exploring the use of mobile phones in youth outreach mental health services. Our outreach team's experience is that enabling youth to access their therapist directly through mobile phone improves engagement and retention, and short message service (SMS) in particular, is a useful tool for coordinating appointments. The purpose of this study was to audit the content of SMS exchanges between therapists and clients and to investigate the extent of inappropriate SMS use. Method An audit of SMS messages sent and received from an outreach youth mental health service was conducted over a 7-month period. Results The majority of SMS traffic sent to and received from clients was micro-coordinating face-to-face-meetings (76% and 61%, respectively), reflecting a practical real-time use of SMS. Only a small proportion of the client use of SMS was classified as inappropriate (2%). Conclusions The results demonstrate that mobile phones and SMS can be used as a safe, practical way of maintaining contact and coordinating meetings within a youth outreach service.
Abstract
Encouraging clinical outcomes in autologous cellular immunotherapy have garnered hope and excitement. However, limitations of patient-derived cancer immunotherapies remain to be addressed to ...deliver reliable and efficacious therapies with broader applicability. Induced pluripotent stem cells (iPSCs) are a unique, renewable source for the continuous generation of cellular therapeutics and represent a highly promising approach for overcoming many of the limitations of autologous therapy. To advance the promise of iPSC technology as an “off-the-shelf” (OTS) source of cellular therapeutics, several considerations need to be addressed. Ensuring the persistence of allogeneic OTS therapies after adoptive cell transfer across histocompatibility barriers is a key requirement. Establishing a master cell line from genetically engineered clonal iPSC lines with the capacity to continuously generate homogenous populations of highly functional effector cells will also be necessary. Here we demonstrate a comprehensive approach for the generation of immune tolerant effector cells derived from a genetically engineered iPSC master cell line. We successfully combined deletion of classical human leukocyte antigen molecules with expression of immunosuppressive proteins to generate clonal iPSC lines with the ability to escape immune rejection. Utilizing in vitro quantitative live cell analysis we show that OTS-iPSCs elicit a significantly decreased cytotoxic response from both peripheral blood (PB)-NK cells (47.9 vs. 91.4% survival at 3:1 E:T ratio) and PB-T cells (>2.7-fold greater number of OTS-iPSC derived cells remaining at 88 hrs). Additionally, mixed lymphocyte reactions employing unfractionated PB mononuclear cells resulted in significantly decreased activation and proliferation of CD8+ T cells (63.4 vs. 29.6%), CD4+ T cells (70.9 vs. 17.3%) and NK cells (46.8 vs. 11.6%). In preclinical mouse models we demonstrate that OTS-iPSCs exhibit improved persistence in vivo. Bilateral engraftments were established in non-conditioned, fully immune-competent recipient mice using luciferized wildtype and OTS-iPSCs. Daily bioluminescence imaging revealed a significant increase in persistence of OTS-iPSCs during the 48-196 hour post injection window (>5.5 fold greater luminescence at 96 hrs). Using our potent chemically-defined stage-specific monolayer hematopoietic differentiation platform, we demonstrate that OTS-iPSC derived CD34 expressing hematopoietic cells are reproducibly scaled and readily give rise to functional lymphocytes carrying the engineered targeted modality in a homogenous manner (95 +/- 5%). The outlined preclinical data illustrate that iPSCs are an ideal renewable source for OTS hematopoietic cell-based immunotherapies and represent a potentially exponential advancement in adoptive immunotherapy.
Citation Format: Raedun L. Clarke, Matthieu Bauer, Ryan Bjordahl, Jeffrey Sasaki, Brian Groff, Svetlana Gaidarova, Tom Tong Lee, Weijie Lan, Michelle Burrascano, Ramzey Abujarour, Greg Bonello, Megan Robinson, Stewart Abbot, Scott Wolchko, Daniel Shoemaker, Bob Valamehr. Overcoming host histocompatibility barrier to create a renewable source of off-the-shelf effector lymphocytes for adoptive immunotherapy abstract. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 609. doi:10.1158/1538-7445.AM2017-609
Cellular immunotherapies are poised to transform the treatment of cancer and immunological disorders. In the most promising setting to date, genetic modification to the T lymphocytes in the form of ...chimeric antigen receptors (CAR) has dramatically increased therapeutic efficacy with reported initial complete remission rates in acute lymphoblastic leukemia ranging between 80-100%. However, pressing challenges remain to be solved to ensure that engineered T-cell immunotherapies can be cost-effectively and consistently manufactured, and safely and reliably delivered at the scale necessary to support wide patient base commercialization.
Human induced pluripotent stem cell (hiPSC) derived T lymphocytes represent a unique, renewable source of genetically engineered T cells for "off-the-shelf" immunotherapy. Through the precise genetic engineering at the hiPSC stage, clonal and uniform populations of modified cell lines can be banked and reliably tapped into on demand to generate highly efficacious T cells for therapeutic applications. Although great progress has been made, several challenges need to be addressed including the ability to enhance effector function through genome-engineering of persistence, targeting, histocompatibility and controlled safety mechanisms at the hiPSC juncture while retaining the capacity to efficiently and reproducibly generate the intricate stages of lymphocyte development in an accurate and scalable process. We have previously demonstrated that our proprietary reprogramming platform supports efficient and rapid derivation of clonal hiPSC lines with properties indicative of the naïve state of pluripotency. In addition to maintaining a homogeneous population of hiPSCs, our platform enables efficient multi-gene and multi-loci targeted engineering at a single cell level resulting in clonal population of pluripotent cell lines with desired genetic attributes.
Here we will provide an update on our "off-the-shelf" T-cell immunotherapy preclinical program where engineered hiPSC lines are uniquely used as the renewable starting material. We will also highlight our novel differentiation platform to derive definitive hematopoietic progenitor cells termed hemogenic endothelium (HE); a well-defined, small molecule-driven, staged process that is currently being translated into cGMP (current good manufacturing practice) settings. The highly efficient differentiation system (on average >65% hiPSC to CD34 conversion) delivers approximately 100 CD34+ HE cells per each input hiPSC, representing a highly scalable process that is further expanded during lymphocyte differentiation and maturation. To validate that the iCD34+ HE is definitive in nature we demonstrate that during further hematopoietic differentiation the emerging CD43+ hematopoietic cells exhibit Notch dependency and high expression of key genes such as MYB and the HOXA cluster, found only in definitive hematopoietic progenitors. The hiPSC-derived HE exhibits multi-lineage potential and can be successfully cryopreserved and banked, serving as a highly-stable cell bank for subsequent therapeutic use. Through genetic modifications at the single cell hiPSC stage, we confer antigen-specificity via the expression of temporally inducible CARs as premature expression of CAR proteins during in vitro differentiation has been found to skew development towards innate-lymphoid like lineages. Utilizing our stage-specific hematopoietic differentiation platform we have identified the optimal developmental window to induce the expression of CAR proteins to maintain optimal differentiation towards functional effector lymphocytes. The hiPSC-derived engineered T lymphocytes are currently under preclinical investigation for in vitro and in vivo effector function including thymic rejuvenation, T cell repertoire repopulation, target specific recognition and enhanced killing potential. Preliminary data suggests that hiPSC-derived lymphocytes are functional and can home to their respective niche to support initial repopulation in vivo. Our study continues to support that naïve hiPSCs are an ideal renewal source for "off-the-shelf" hematopoietic cell-based immunotherapies and represent a potentially exponential advancement in adoptive T cell therapy.
Clarke:Fate Therapeutics: Employment. Groff:Fate Therapeutics: Employment. Sasaki:Fate Therapeutics: Employment. Bauer:Fate Therapeutics: Employment. Lee:Fate Therapeutics: Employment. Lan:Fate Therapeutics: Employment. Burrascano:Fate Therapeutics: Employment. Abujarour:Fate Therapeutics: Employment. Bonello:Fate Therapeutics: Employment. Robinson:Fate Therapeutics: Employment. Foster:Fate Therapeutics: Employment, Equity Ownership. Robbins:Fate Therapeutics: Employment, Equity Ownership. Wolchko:Fate Therapeutics: Employment. Shoemaker:Fate Therapeutics: Employment, Equity Ownership. Abbot:Fate Therapeutics: Employment. Valamehr:Fate Therapeutics, Inc: Employment.
Human induced pluripotent stem cells (hiPSCs) are a unique population of cells that can serve as an unlimited source for "off-the-shelf" cellular immunotherapeutics. Similar to master cell lines used ...in the manufacture of monoclonal antibodies, engineered hiPSC lines have the potential to serve as a renewable cell source for the consistent manufacture of homogeneous populations of effector cells for the treatment of thousands of patients. However, the creation of an effective master line is largely dependent on the ability to genetically edit hiPSCs in a precise, efficient and clonal manner. Furthermore, the genetically edited hiPSCs must maintain their inherent ability to continuously self-renew while retaining ability to express engineered modalities upon directed differentiation to the cell type of choice.
We have previously reported the use of stage-specific media compositions to enable the footprint-free generation and long-term maintenance of single cell naïve hiPSCs with enhanced clonogenicity, an attribute critical for the derivation of engineered single cell-derived lines. Here we demonstrate the use of our naïve hiPSC platform to precisely introduce, in a site-specific manner, multiple genes into multiple safe harbor loci. By combining our single-cell naïve hiPSC platform with different nuclease-independent and -dependent strategies, we are able to generate large numbers of precisely engineered iPSC clones. The single cell-derived hiPSC clones were subsequently screened in a multiplexed fashion for successful multi-parameter engineering, maintained pluripotency and propensity for differentiation with lack of undesired phenotypes and genomic alterations. Using this approach, we derived individual clones containing a uniform population (>99%) of multi-engineered modalities consisting of tumor targeting, a controllable safety switch and a tracking marker. Moreover, we show that engineered modalities are expressed in undifferentiated and differentiated hiPSCs, including being expressed in >95% of both CD34 positive hematopoietic progenitor cells and CD56 positive natural killer cells. Furthermore, we have generated hiPSC clones with dual suicide genes (inducible Caspase 9 (iCasp9) and Herpes simplex virus thymidine kinase (HSV-TK)) targeted into two independent safe harbor loci, in both mono- and bi-allelic manner. The dual-targeted hiPSC clones were confirmed to have specific insertions into the predicted sites and were screened to exclude random insertions. Concurrent activation of both suicide genes led to complete elimination of engineered hiPSCs and no treatment-refractory cells were observed unlike the case when only one suicide gene was activated. In addition to robust targeted insertions, we were able to generate small insertions and deletions in up to 70% of naïve hiPSCs without selection and homozygous knockout of gene of interest in 100% of cells after selection. Finally, we will discuss efforts to temporally synchronize ectopic gene expression through endogenously regulated promoters by simultaneous endogenous gene disruption and transgene insertion. Overall, we show our naïve hiPSC platform is an ideal renewable source to efficiently generate, genetically engineer, isolate and bank clonally-derived homogenous population of pluripotent cells. These highly-stable pluripotent clonal banks can be repeatedly tapped to facilitate the consistent production of homogenous populations of potent, persistent, scalable and safer off-the-shelf cellular immunotherapeutics.
Abujarour:Fate Therapeutics: Employment. Lan:Fate Therapeutics: Employment. Lee:Fate Therapeutics: Employment. Bonello:Fate Therapeutics: Employment. Meza:Fate Therapeutics: Employment, Equity Ownership. Robinson:Fate Therapeutics: Employment. Clarke:Fate Therapeutics: Employment. Truong:Fate Therapeutics: Employment, Equity Ownership. Robbins:Fate Therapeutics: Employment, Equity Ownership. Rezner:Fate Therapeutics, Inc: Employment, Equity Ownership. Abbot:Fate Therapeutics: Employment. Shoemaker:Fate Therapeutics: Employment, Equity Ownership. Valamehr:Fate Therapeutics, Inc: Employment.
Encouraging clinical outcomes in autologous cellular immunotherapy have garnered hope and excitement. However, considerable challenges and limitations of patient-derived cancer immunotherapies remain ...and need to be addressed in order to consistently deliver reliable and efficacious therapies with broadened applicability. Human induced pluripotent stem cells (hiPSCs) are a unique, renewable source for the continuous generation of cellular therapeutics for the treatment of hematological and non-hematological malignancies, and represent a highly promising approach for overcoming many of the limitations of autologous therapy. To advance the promise of hiPSC technology as an "off-the-shelf" source of cellular therapeutics, several considerations need to be addressed. Enabling cell transfer across histocompatibility barriers to permit persistence and therapeutic efficacy in an allogeneic setting is a key requirement. In addition to improving persistence, the ability to overcome histocompatibility barriers may facilitate multi-dosing regimens which may be a requirement in more advanced and complicated disease settings.
Genetic incompatibilities between donor and recipient among the classical human leukocyte antigen (HLA) molecules is the leading cause of alloresponse by the host immune system and is currently mitigated by immunosuppressive strategies. Unfortunately, this treatment strategy is not only a stressful event for the patient but also damages the endogenous immune system, compromising the patient’s ability to continue to fight the disease and opportunistic infections. Genetic editing of the HLA genes to generate histocompatible universal cell products is a viable opportunity that is currently being investigated. In addition to selective editing of unique genes to avoid a T cell mediated alloresponse, additional considerations such as natural killer (NK) cell-mediated rejection will need to be addressed. We have previously demonstrated that our proprietary reprogramming platform supports efficient and rapid derivation of clonal hiPSC lines with properties indicative of the naïve state of pluripotency. In addition to maintaining a homogeneous renewable population of hiPSCs, our platform is amenable to precise multi-gene and multi-loci targeted engineering at the single cell level, in both nuclease -dependent and -independent strategies. Furthermore, we have shown through small molecule-guided differentiation protocols, these highly-stable pluripotent cell lines can be banked and repeatedly tapped to consistently produce homogenous populations of immune cells with enhanced effector properties.
Here we demonstrate a multi-faceted and comprehensive approach for the generation of immune tolerant hiPSCs and hiPSC-derived immune effector cells. We successfully combined deletion of classical HLA molecules with enforced expression of robust immunosuppressive proteins, including non-classical HLA molecules, to generate clonal hiPSC lines with the ability to escape immune rejection for "off-the-shelf" (OTS-hiPSCs) cellular immunotherapy. Utilizing in vitro real-time quantitative live cell analysis we determined that OTS-hiPSCs elicit a significantly decreased cytotoxic response from both activated peripheral blood (PB)-NK cells and primed PB-T cells compared to wildtype controls. Furthermore we demonstrate that OTS-hiPSCs exhibit improved persistence in xenograft studies in vivo. Bilateral teratomas were formed in a non-conditioned, fully immune-competent recipient mice using luciferized wildtype and OTS-hiPSCs. Daily bioluminescence imaging over a period of 7 days revealed a significant increase (>50 fold difference) in persistence of OTS-hiPSCs compared to wildtype hiPSCs during the 60-144 hour post injection window. Lastly we demonstrate that OTS-hiPSCs can successfully differentiate into functional effector lymphocytes using our potent chemically-defined monolayer hematopoietic differentiation platform. Our current studies focus on the functional characterization of OTS-hiPSC-derived effector lymphocytes in humanized mouse models and generating increased potency of OTS-hiPSC-derived effector lymphocytes through precise genetic engineering of antigen targeting and costimulatory proteins to create and optimized source of "off-the-shelf" cell-based immunotherapies.
Bauer:Fate Therapeutics: Employment. Clarke:Fate Therapeutics: Employment. Sasaki:Fate Therapeutics: Employment. Groff:Fate Therapeutics: Employment. Lee:Fate Therapeutics: Employment. Lan:Fate Therapeutics: Employment. Abujarour:Fate Therapeutics: Employment. Bonello:Fate Therapeutics: Employment. Burrascano:Fate Therapeutics: Employment. Robinson:Fate Therapeutics: Employment. Bjordahl:Fate Therapeutics, Inc: Employment. Gaidarova:Fate Therapeutics: Employment. Abbot:Fate Therapeutics: Employment. Wolchko:Fate Therapeutics: Employment. Shoemaker:Fate Therapeutics: Employment, Equity Ownership. Valamehr:Fate Therapeutics, Inc: Employment.
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Natural killer (NK) cells represent a lineage of immune cells capable of direct cytotoxicity against tumor cells and are a critical source of key inflammatory cytokines such as interferon (IFN)-γ ...and tumor necrosis factor (TNF). NK cell function is often impaired in the setting of cancer, reducing the effectiveness of the endogenous immune system. The unique biological attributes of NK cells, including multifaceted effector function, tumor cell recognition independent of antigen presentation and target cell selectivity independent of HLA-matching, has enabled NK cells from a donor to be adoptively transferred to a patient for the treatment of cancer. This safe and effective administration of donor NK cells to patients validates their potential for broad use as part of an off-the-shelf cancer immunotherapy strategy, including in combination with monoclonal antibody and checkpoint inhibitor therapies.
We have previously shown that human induced pluripotent stem cells (hiPSC) can be clonally-selected, cryopreserved and banked, and that these master pluripotent cell lines (MPCLs) can be used to renewably generate large clonal populations of NK cells. The use of MPCLs represents a highly-promising, off-the-shelf approach to cell-based cancer immunotherapy, with the potential to overcome many of the challenges and limitations of patient-sourced and donor-derived cell therapies. However, to clinically and commercially enable this off-the-shelf strategy, it is essential to efficiently and reproducibly differentiate MPCLs to fully-functional NK cells using a robust and scalable process that meets regulatory requirements.
Here we describe a novel paradigm for the manufacture of hiPSC-derived NK (iNK) cells consisting of a well-defined, small molecule-driven, staged protocol that enables clinical translation and is compatible with current good manufacturing practice (cGMP) requirements. The manufacturing protocol is currently being transferred from the laboratories of Fate Therapeutics to Molecular and Cellular Therapeutics at the University of Minnesota, which is a state-of-the-art GMP/GTP compliant, full-service developer and manufacturer of cell- and tissue-based products.
iNK cell therapy manufacture consists of four unique steps including: 1) the derivation and master cell banking of a clonal pluripotent cell line (> 95% SSEA4+/TRA181+ hiPSCs); 2) differentiation of the clonal pluripotent cell line towards hematopoietic progenitor cells (enriched for > 80% CD34+ cells); 3) differentiation and expansion of iNKs (Figure 1A, approximately 1,000-fold expansion in 14 days); and 4) freeze and thaw of drug product, comprised of a sufficiently pure homogenous population of iNKs (Figure 1B, > 95% CD45+, > 90% CD56+, minimal CD3+ T cells). Importantly, testing at both the molecular and culture stages demonstrate that no hiPSCs exist in the final drug product (limit of detection 1 hiPSC in 1.25 million iNK cells). This novel manufacturing paradigm supports the generation of significant numbers of iNK cells: approximately 1 million-fold cell expansion is achieved in less than 50 days, such that a very small population of hiPSCs can readily produce 1x1012 iNK cells. We estimate that this represents hundreds of doses of drug product per each manufacturing run (Figure 1A). The iNK cells display markedly augmented effector function relative to ex vivo expanded primary peripheral blood or cord blood NK cells with respect to cytokine release (IFN-γ and TNF) and cellular cytotoxicity against various leukemic and solid tumor-derived target cells including K562, Raji, A549 and SKOV3 (Figure 1C).
To enable centralized manufacturing, we established a freeze and thaw strategy that supports greater than 85% viability with a recovery of greater than 80% iNK cells at twenty-four hours post-thaw. Because the freeze process uses an infusible medium formulation, we demonstrated in vitro and in vivo that the iNK cells maintain their efficacy post-thaw and can be immediately infused into patients.
The manufacturing data presented herein support the filing of an Investigational New Drug application for an off-the-shelf iNK cell therapy product to treat advanced hematologic and solid tumor malignancies alone or in combination with monoclonal antibody and checkpoint inhibitor therapies.
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Bjordahl:Fate Therapeutics: Employment, Equity Ownership. Gaidarova:Fate Therapeutics Inc.: Employment, Equity Ownership. Rogers:Fate Therapeutics Inc.: Employment, Equity Ownership. Clarke:Fate Therapeutics Inc.: Employment, Equity Ownership. Groff:Fate Therapeutics Inc.: Employment. Moreno:Fate Therapeutics Inc.: Employment. Abujarour:Fate Therapeutics Inc.: Employment. Robinson:Fate Therapeutics Inc.: Employment. Bonello:Fate Therapeutics Inc.: Employment. Lee:Fate Therapeutics Inc.: Employment, Equity Ownership. Lan:Fate Therapeutics Inc.: Employment, Equity Ownership. Rezner:Fate Therapeutics, Inc.: Employment. Abbot:Fate Therapeutics Inc.: Employment. Wolchko:Fate Therapeutics Inc.: Employment. Kaufman:Fate Therapeutics: Consultancy, Research Funding. Valamehr:Fate Therapeutics: Employment, Equity Ownership. Miller:Oxis Biotech: Consultancy; Celegene: Consultancy; Fate Therapeutics: Consultancy, Research Funding.
Abstract
The unique attributes of a combinatorial tumor recognition system, diminished off-tumor cytotoxicity, and multifaceted effector function make natural killer (NK) cells a prime candidate for ...a universal approach to cancer immunotherapy. In addition, NK cells are the principal mediator of antibody-directed cellular cytotoxicity (ADCC). However, NK cell function is often impaired in the setting of cancer, reducing the effectiveness of the endogenous immune system and the therapeutic efficacy of monoclonal antibodies. To address the need for advanced and combinatorial cancer therapies, we developed a unique and effective strategy to create a renewable source of engineered “off-the-shelf” NK cells with augmented function, including enhanced ADCC and persistence. Key challenges associated with genetic editing, limited expansion, persistence and variability of peripheral blood (PB)-derived NK cells were overcome by utilizing our induced pluripotent stem cell (iPSC) technology as the unlimited starting material for the reproducible and consistent derivation of engineered NK cells. Through targeted transgene integration, we produced a clonal iPSC master cell line to continuously produce NK cells engineered to uniformly express a high affinity, non-cleavable version of CD16 (hnCD16-NK). In directed differentiation, the hnCD16-NK cells displayed homogeneous expression of CD16 (>95%) and a mature CD56+ NK cell phenotype, as exhibited by expression of KIR, NCRs, DNAM-1, and NKG2D. In contrast to endogenous CD16 expression, the engineered hnCD16 molecule was shown to be cleavage resistant upon NK cell activation (>95% CD16+ hnCD16-NK vs. <10% CD16+ PB-derived NK cell, upon target cell-mediated activation), and demonstrated enhanced antibody binding compared to PB-derived NK cells expressing the low-affinity variant. In addition to increased expression of the cytolytic molecules perforin and granzyme B and enhanced direct cytotoxicity against tumor targets, hnCD16-NK cells displayed superior ADCC capacity and cytokine production in response to CD16 stimulation. Importantly, manufacture of hnCD16-NK cells was proven to be highly scalable, delivering up to 107 fold expansion over a 35 day period. The maintained proliferative capacity can be in part associated with longer telomere length seen in hnCD16-NK cells. Furthermore, deletion of classical human leukocyte antigen molecules and ectopic expression of immunosuppressive proteins engineered at the iPSC level provided the ability of hnCD16-NK cells to potentially overcome the host histocompatibility barrier and to improve persistence in the allogeneic setting. In conclusion, the preclinical data presented herein highlight the therapeutic value of hnCD16-iNK cells as an ideal ADCC-mediated “off-the-shelf” NK cell-based immunotherapeutic product with augmented persistence, anti-tumor capacity, manufacturing reliability and preclinical efficacy.
Citation Format: Ryan Bjordahl, Frank Cichocki, Raedun Clarke, Svetlana Gaidarova, Brian Groff, Paul Rogers, Stacey Moreno, Ramzey Abujarour, Greg Bonello, Tom Lee, Weijie Lan, Matthieu Bauer, Dave Robbins, Betsy Rezner, Sarah Cooley, Bruce Walcheck, Stewart Abbot, Bruce Blazar, Scott Wolchko, Daniel Shoemaker, Jeffrey S. Miller, Bahram Valamehr. Renewable and genetically engineered natural killer cells for off-the-shelf adoptive cellular immunotherapy abstract. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 3755. doi:10.1158/1538-7445.AM2017-3755
Natural Killer (NK) cells play a crucial role in immunosurveillance and form a first line of defense against cancer. In comparison to other lymphocytes, NK cells are unique in their capability to ...elicit tumoricidal responses without the need for antigen presentation or prior sensitization. Clinical data from bone marrow transplant and allogeneic NK immunotherapy suggest that MHC mismatch is advantageous in promoting graft-versus-leukemia without eliciting graft-versus-host, providing evidence that NK cells hold promisa as an allogeneic, universal immunotherapeutic. Further, the anti-tumor effect of many monoclonal antibodies is mediated through binding of the low-affinity Fc receptor CD16 on NK cells, which induces tumor cell killing through antibody-dependent cellular cytotoxicity (ADCC). Thus, NK cells represent a unique source of effector cells that can be combined with monoclonal antibodies, bispecific engagers or chimeric antigen receptors to direct tumor specificity and enhance cytotoxicity. Despite the significant potential of NK cell therapy, current clinical practices are limited by the need for large numbers of healthy NK cells, lack of in vivo persistence, and a burdensome manufacturing strategy that requires donor cell extraction, modulation, expansion and re-introduction per each patient.
The ability to generate universally histocompatible and genetically-enhanced NK cells from continuously renewable human induced pluripotent stem cell (hiPSC) lines offers the potential to develop a true "off-the-shelf" cellular immunotherapy. While NK differentiation from hiPSC has been demonstrated, the clonal derivation of engineered hiPSCs to improve effector function has been challenging and the scalability and robustness of the differentiation method has been limited by skewed development towards primitive hematopoiesis and the cumbersome use of embryoid bodies.
Here we highlight our "off-the-shelf" NK cell therapy preclinical program by demonstrating robust and highly scalable generation of functionally mature, genetically targeted and universally histocompatible NK cells. This program utilizes our previously described naïve hiPSC platform where we uniquely create clonal lines of precisely engineered, renewable hiPSCs and drive definitive hematopoiesis in a highly scalable manner. Because hiPSC differentiation is lineage directed, minimal cellular contamination is seen, including the lack of T and B cells, in the final product. Through precise genetic engineering of naïve hiPSC lines, we have engineered HLA-class I deficient NK cells uniformly expressing a high affinity, non-cleavable version of the Fc receptor CD16 (NcHaCD16-NK). The hiPSC-derived NcHaCD16-NKs display markers of maturity, including CD16, KIR, NCRs, and CD94. When compared to conventional cord blood and peripheral blood sourced NK cells, NcHaCD16-NKs exhibit superior cytotoxicity and production of effector cytokines in response to both solid and liquid tumor cell challenge in vitro. NcHaCD16-NKs exhibit augmented cytokine response following Fc-mediated stimulation, demonstrating function competence of the engineered CD16 construct. Because surface expression of CD16 is resistant to activation-induced shedding, NcHaCD16-NKs continuously maintain enhanced ADCC while retaining the capacity for general cytotoxicity. Importantly, the hiPSC-derived hematopoietic cells can be successfully cryopreserved and banked, serving as a highly-stable cell bank for subsequent therapeutic use. Preliminary data also shows NcHaCD16-NKs elicit preferred specificity for cancer stem cells as defined by expression of ALDH1 and surface markers such as CD24. In conclusion, the outlined preclinical data demonstrate the potential therapeutic utility of NK cells developed via precision genetic engineering of a renewable, scalable hiPSC platform, and highlights the therapeutic value of NcHaCD16-NKs as an ideal ADCC-mediated "off-the-shelf" NK cell-based immunotherapeutic product with augmented persistence, anti-tumor capacity and preclinical efficacy.
Bjordahl:Fate Therapeutics, Inc: Employment. Clarke:Fate Therapeutics: Employment. Gaidarova:Fate Therapeutics: Employment. Groff:Fate Therapeutics: Employment. Rogers:Fate Therapeutics, Inc: Employment. Moreno:Fate Therapeutics, Inc.: Employment, Equity Ownership. Abujarour:Fate Therapeutics, Inc.: Employment. Bonello:Fate Therapeutics, Inc.: Employment. Lee:Fate Therapeutics: Employment. Lan:Fate Therapeutics: Employment. Burrascano:Fate Therapeutics: Employment. Bauer:Fate Therapeutics: Employment. Robinson:Fate Therapeutics: Employment. Sasaki:Fate Therapeutics, Inc.: Employment. Kim:Fate Therapeutics, Inc.: Employment. Robbins:Fate Therapeutics: Employment, Equity Ownership. Rezner:Fate Therapeutics, Inc: Employment, Equity Ownership. Abbot:Fate Therapeutics: Employment. Wolchko:Fate Therapeutics: Employment. Shoemaker:Fate Therapeutics: Employment, Equity Ownership. Valamehr:Fate Therapeutics, Inc: Employment.
A preliminary report is presented on modeling studies of the pyloric circuit of the crustacean stomatogastric ganglion. The goal of this research is to understand how this small network is able to ...perform the dynamic adjustments needed to maintain a stable rhythmic pattern over a wide range of frequencies and conditions. A discussion is presented of models of individual cell behaviors and the procedure by which they may be reduced to a manageable form. Some indications of how these intrinsic characteristics may interact to produce the full network behavior are presented
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