This protocol describes the synthesis and characterization of a trans-cyclooctene (TCO)-modified antibody and a 177Lu-labeled tetrazine (Tz) radioligand for pretargeted radioimmunotherapy (PRIT). In addition, it details the use of these two constructs for in vivo biodistribution and longitudinal therapy studies in a murine model of colorectal cancer.
While radioimmunotherapy (RIT) is a promising approach for the treatment of cancer, the long pharmacokinetic half-life of radiolabeled antibodies can result in high radiation doses to healthy tissues. Perhaps not surprisingly, several different strategies have been developed to circumvent this troubling limitation. One of the most promising of these approaches is pretargeted radioimmunotherapy (PRIT). PRIT is predicated on decoupling the radionuclide from the immunoglobulin, injecting them separately, and then allowing them to combine in vivo at the target tissue. This approach harnesses the exceptional tumor-targeting properties of antibodies while skirting their pharmacokinetic drawbacks, thereby lowering radiation doses to non-target tissues and facilitating the use of radionuclides with half-lives that are considered too short for use in traditional radioimmunoconjugates. Over the last five years, our laboratory and others have developed an approach to in vivo pretargeting based on the inverse electron-demand Diels-Alder (IEDDA) reaction between trans-cyclooctene (TCO) and tetrazine (Tz). This strategy has been successfully applied to pretargeted positron emission tomography (PET) and single-photon emission computed tomography (SPECT) imaging with a variety of antibody-antigen systems. In a pair of recent publications, we have demonstrated the efficacy of IEDDA-based PRIT in murine models of pancreatic ductal adenocarcinoma and colorectal carcinoma. In this protocol, we describe protocols for PRIT using a 177Lu-DOTA-labeled tetrazine radioligand ([177Lu]Lu-DOTA-PEG7-Tz) and a TCO-modified variant of the colorectal cancer targeting huA33 antibody (huA33-TCO). More specifically, we will describe the construction of huA33-TCO, the synthesis and radiolabeling of [177Lu]Lu-DOTA-PEG7-Tz, and the performance of in vivo biodistribution and longitudinal therapy studies in murine models of colorectal carcinoma.
Radioimmunotherapy (RIT) — the use of antibodies for the delivery of therapeutic radionuclides to tumors — has long been an enticing approach to the treatment of cancer1,2. Indeed, this promise has been underscored by the United States Food and Drug Administration’s approval of two radioimmunoconjugates for the treatment of Non-Hodgkin’s Lymphoma: 90Y-ibritumomab tiuxetan and 131I-tositumomab3,4. Yet even from its earliest days, the clinical prospects of RIT have been hampered by a critical complication: high radiation dose rates to healthy tissues5,6. Generally speaking, radioimmunoconjugates for RIT are labeled with long-lived radionuclides (e.g., 131I [t½ = 8.0 days] and 90Y [t½ = 2.7 days]) with physical half-lives that dovetail well with the long pharmacokinetic half-lives of immunoglobulins. This is essential, as it ensures that sufficient radioactivity remains once the antibody has reached its optimal biodistribution after several days of circulation. However, this combination of long residence times in the blood and long physical half-lives inevitably results in the irradiation of healthy tissues, thereby reducing therapeutic ratios and limiting the efficacy of therapy7. Several strategies have been explored to circumvent this problem, including the use of truncated antibody fragments such as Fab, Fab', F(ab')2, minibodies, and nanobodies8,9,10. One of the most promising and fascinating, yet undeniably complex, alternative approaches is in vivo pretargeting11.
In vivo pretargeting is an approach to nuclear imaging and therapy that seeks to harness the exquisite affinity and selectivity of antibodies while skirting their pharmacokinetic drawbacks11,12,13. To this end, the radiolabeled antibody used in traditional radioimmunotherapy is deconstructed into two components: a small molecule radioligand and an immunoconjugate that can bind both a tumor antigen and the aforementioned radioligand. The immunoconjugate is injected first and given a ‘head start’, often several days, during which it accumulates in the target tissue and clears from the blood. Subsequently, the small molecule radioligand is administered and either combines with the immunoconjugate at the tumor or rapidly clears from the body. In essence, in vivo pretargeting relies upon performing radiochemistry within the body itself. By reducing the circulation of the radioactivity, this approach simultaneously reduces radiation doses to healthy tissues and facilitates the use of radionuclides (e.g., 68Ga, t½ = 68 min211; As, t½ = 7.2 h) with half-lives that are typically considered incompatible with antibody-based vectors.
Starting in the late 1980s, a handful of different approaches to in vivo pretargeting have been developed, including strategies based on bispecific antibodies, the interaction between streptavidin and biotin, and the hybridization of complementary oligonucleotides14,15,16,17,18. Yet each has been held back to varying degrees by complications, most famously the potent immunogenicity of streptavidin-modified antibodies19,20. Over the last five years, our group and others have developed an approach to in vivo pretargeting based on the rapid and bioorthogonal inverse electron demand Diels-Alder ligation between trans-cyclooctene (TCO) and tetrazine (Tz)21,22,23,24. The most successful of these strategies have employed a TCO-modified antibody and a Tz-bearing radioligand, as TCO is typically more stable in vivo than its Tz partner (Figure 1)25,26. As in other pretargeting methodologies, the mAb-TCO immunoconjugate is administered first and given time to clear from circulation and accumulate in tumor tissue. Subsequently, the small molecule Tz radioligand is injected, after which it either clicks with the immunoconjugate within the target tissue or clears rapidly from the body. This in vivo pretargeting strategy has proven highly effective for PET and SPECT imaging with several different antibody/antigen systems, consistently producing images with high contrast and enabling the use of short-lived radionuclides such as 18F (t½ = 109 min) and 64Cu (t1/2 = 12.7 h)21,22,24. More recently, the efficacy of click-based pretargeted radioimmunotherapy (PRIT) has been demonstrated in murine models of pancreatic ductal adenocarcinoma (PDAC) and colorectal carcinoma27,28. To this end, the therapeutic radionuclide 177Lu (βmax = 498 keV, t1/2 = 6.7 days) was employed in conjunction with two different antibodies: 5B1, which targets carbohydrate antigen 19.9 (CA19.9) ubiquitously expressed in PDAC, and huA33, which targets A33, a transmembrane glycoprotein expressed in >95% of colorectal cancers. In both cases, this approach to 177Lu-PRIT yielded high activity concentrations in tumor tissue, created a dose-dependent therapeutic effect, and simultaneously reduced activity concentrations in healthy tissues compared to traditional directly-labeled radioimmunoconjugates.
In this article, we describe protocols for PRIT using a 177Lu-DOTA-labeled tetrazine radioligand ([177Lu]Lu-DOTA-PEG7-Tz) and a TCO-modified variant of the huA33 antibody (huA33-TCO). More specifically, we describe the construction of huA33-TCO (Figure 2), the synthesis and radiolabeling of [177Lu]Lu-DOTA-PEG7-Tz (Figure 3 and Figure 4), and the performance of in vivo biodistribution and longitudinal therapy studies in murine models of colorectal carcinoma. Furthermore, in the representative results and discussion, we present a sample data set, address possible strategies for the optimization of this approach, and consider this strategy in the wider context of in vivo pretargeting and PRIT. Finally, it is important to note that while we have chosen to focus on pretargeting using huA33-TCO and [177Lu]Lu-DOTA-PEG7-Tz in this protocol, this strategy is highly modular and can be adapted to suit a wide range of antibodies and radionuclides.
所有 in vivo animal experiments described in this work were performed according to approved protocols and executed under the ethical guidelines of the Memorial Sloan Kettering Cancer Center, Weill Cornell Medical Center, and Hunter College Institutional Animal Care and Use Committees (IACUC).
1. The preparation of huA33-TCO
NOTE: The synthesis of huA33-TCO has been previously reported29. However, for the ease of the reader, it is replicated here with adjustments for optimal conditions.
2. The Synthesis of Tz-PEG7-NHBoc
3. The Synthesis of Tz-PEG7-NH2
4. The Synthesis of Tz-PEG7-DOTA
5. 177Lu Radiolabeling of Tz-PEG7-DOTA
CAUTION: This step of the protocol involves the handling and manipulation of radioactivity. Before performing these steps — or performing any other work with radioactivity — researchers should consult with their home institution’s Radiation Safety Department. Take all possible steps to minimize exposure to ionizing radiation.
NOTE: When working with small amounts of radiometals it is recommended that all buffers be free from trace metals to prevent interference in coordination site binding.
6. In vivo Studies
CAUTION: As in Section 5, this step of the protocol involves the handling and manipulation of radioactivity. Before performing these steps, researchers should consult with their home institution’s Radiation Safety Department. Take all possible steps to minimize exposure to ionizing radiation.
The conjugation of TCO to huA33 is predicated on the coupling between the amine-reactive TCO-NHS and the lysine residues on the surface of the immunoglobulin. This method is highly robust and reproducible and reliably yields a degree-of-labeling of 2-4 TCO/mAb. In this case, MALDI-ToF mass spectrometry was employed to confirm a degree of labeling of approximately 4.0 TCO/mAb; a similar value was obtained using a fluorophore-modified tetrazine as a reporter24. The synthesis of the tetrazine ligand is performed in three steps: (1) the coupling of Tz-NHS to a mono-Boc-protected PEG linker (2) the deprotection of this intermediate to yield Tz-PEG7-NH2, and (3) the formation of a thiourea linkage between p-SCN-Bn-DOTA and Tz-PEG7-NH2. This procedure is relatively facile and affords Tz-PEG7-DOTA in an overall yield of ~75%. Each of the intermediates has been characterized by HRMS and 1H-NMR; this data is presented in Table 1.
Moving on to the radiolabeling, 177Lu3+ is typically obtained from commercial suppliers as a chloride salt [177Lu]LuCl3 in 0.5 M HCl. The radiolabeling of Tz-PEG7-DOTA with 177Lu to yield the radioligand [177Lu]Lu-DOTA-PEG7-Tz is very straightforward: in just 20 min, the reaction is complete, producing the desired product in >99% radiochemical purity as determined by radio-iTLC. Typically, no further purification is necessary prior to formulation. A survey of the literature on Tz/TCO-based pretargeting suggests that a Tz:mAb molar ratio of ~1:1 produces the best in vivo data10. As a result, it is not essential to obtain the radioligand in the highest possible molar activity. For example, biodistribution experiments discussed here employ [177Lu]Lu-DOTA-PEG7-Tz with a molar activity of ~12 GBq/µmol. For longitudinal therapy studies, in contrast, [177Lu]Lu-DOTA-PEG7-Tz with higher molar activity was used in order to facilitate the administration of larger doses of radioactivity without changing the number of injected moles of tetrazine.
As will be addressed further in the discussion, biodistribution experiments are of paramount importance to understanding and optimizing any approach to PRIT. In this case, biodistribution experiments were conducted to determine the optimal interval time between the administration of the immunoconjugate and the injection of the radioligand. To this end, we employed athymic nude mice bearing subcutaneous A33 antigen-expressing SW1222 xenografts on their right shoulder. These animals received 100 µg (0.67 nmol) of huA33-TCO 24, 48, 72, or 120 h prior to the injection of [177Lu]Lu-DOTA-PEG7-Tz (9.14 MBq, 0.74 nmol). Figure 5 shows that all injection intervals produce high activity concentrations in the tumor tissue as well as low activity concentrations in healthy organs. The 24 h injection interval affords the highest tumoral uptake at 120 h post-injection: 21.2 ± 2.9%ID/g. Each set of conditions also produces impressive tumor-to-organ activity concentration ratios. Pretargeting with a 24 h interval, for example, yields tumor-to-blood, tumor-to-liver, and tumor-to-muscle ratios of 20 ± 5, 37 ± 7, and 184 ± 30, respectively, 120 h after the administration of the radioligand. Based on these findings, a 24 h interval was chosen for the subsequent longitudinal therapy study (see below).
For the in vivo longitudinal therapy study, cohorts (n = 10) of athymic nude mice bearing subcutaneous SW1222 xenografts on their right flank were administered huA33-TCO (100 ug, 0.67 nmol) 24 hours prior to injection of [177Lu]Lu-DOTA-PEG7-Tz. Three different experimental cohorts were employed, receiving 18.7, 37, or 55.5 MBq of [177Lu]Lu-DOTA-PEG7-Tz (corresponding to molar activities of 24, 45, and 70 GBq/µmol). In addition, two control cohorts received one half of the PRIT regimen: either huA33-TCO (100 ug, 0.67 nmol) without [177Lu]Lu-DOTA-PEG7-Tz or [177Lu]Lu-DOTA-PEG7-Tz (55.5 MBq, 0.74 nmol) without huA33-TCO. These are essential controls to ensure that the therapeutic response is not elicited by either the immunoconjugate or radioligand alone. The volumes of the tumors were measured every 3 days for the first three weeks of the study and then once per week until the conclusion of the experiment (70 days, 10 half-lives of 177Lu). As seen in Figure 6, there is a stark difference in the response of the experimental cohorts compared to the control groups. While the tumors in the mice receiving only one component of the PRIT strategy continue to grow unchecked, the tumors of the mice receiving the full PRIT regimen stop growing and ultimately shrink to volumes well below those measured at the beginning of the study. Importantly, no toxic side effects were observed, and all animals maintained a weight within 20% of their initial mass (Figure 7A). A Kaplan-Meier plot of the data provides an even more striking visualization of the study: while all mice in the control cohorts had to be euthanized within a few weeks, the mice of the experimental cohorts had a perfect record of survival at the end of the investigation (Figure 7B).
Figure 1: Cartoon schematic of pretargeted radioimmunotherapy based on the inverse electron demand Diels-Alder reaction. This figure has been modified from reference #28. Reprinted (adapted) with permission from Membreno, R., Cook, B. E., Fung, K., Lewis, J. S., & Zeglis, B. M. Click-Mediated Pretargeted Radioimmunotherapy of Colorectal Carcinoma. Molecular Pharmaceutics. 15 (4), 1729-1734 (2018). Copyright 2018 American Chemical Society. Please click here to view a larger version of this figure.
Figure 2: Schematic of the construction of huA33-TCO. Please click here to view a larger version of this figure.
Figure 3: Schematic of the synthesis of Tz-PEG7-DOTA. Please click here to view a larger version of this figure.
Figure 4: (A) Schematic of the radiolabeling of [ 177Lu]Lu-DOTA-PEG7-Tz; (B) Representative radio-iTLC chromatogram demonstrating the >98% radiochemical purity of [177Lu]Lu-DOTA-PEG7-Tz. Please click here to view a larger version of this figure.
Figure 5: Biodistribution in of in vivo pretargeting with huA33-TCO and [177Lu]-DOTA-PEG7-Tz in athymic nude mice bearing subcutaneous SW1222 human colorectal cancer tumors using pretargeting intervals of 24 (purple), 48 (green), 72 (orange), or 120 (blue) hours. Data with standard errors from cohorts of n = 4; Statistical analysis was performed by an unpaired Student's t-test, **p < 0.01. This figure has been modified from reference #28. Reprinted (adapted) with permission from Membreno, R., Cook, B. E., Fung, K., Lewis, J. S., & Zeglis, B. M. Click-Mediated Pretargeted Radioimmunotherapy of Colorectal Carcinoma. Molecular Pharmaceutics. 15 (4), 1729-1734 (2018). Copyright 2018 American Chemical Society. Please click here to view a larger version of this figure.
Figure 6: Longitudinal therapy study of 5 groups of mice (n = 10 each) bearing subcutaneous SW1222 tumors depicted in average tumor volume as a function of time (A); and tumor volume normalized to initial volume as a function of time (B). The control groups received either the immunoconjugate without the radioligand (blue) or the radioligand without the immunoconjugate (red). The three treatment groups received huA33-TCO (100 µg, 0.6 nmol) followed 24 h later by either 18.5 (green), 37.0 (purple), or 55.5 (orange) MBq (~0.8 nmol in each case) of [177Lu]-DOTA-PEG7-Tz. By log-rank (Mantel-Cox) test, survival was significant (p < 0.0001) for all treatment groups. This figure has been modified from reference #28. Reprinted (adapted) with permission from Membreno, R., Cook, B. E., Fung, K., Lewis, J. S., & Zeglis, B. M. Click-Mediated Pretargeted Radioimmunotherapy of Colorectal Carcinoma. Molecular Pharmaceutics. 15 (4), 1729-1734 (2018). Copyright 2018 American Chemical Society. Please click here to view a larger version of this figure.
Figure 7: Weight curves for animals during the longitudinal therapy study of 5 groups of mice (n = 10 each) bearing subcutaneous SW1222 tumors (A); the corresponding Kaplan-Meier survival curve (B). The control groups received either the immunoconjugate without the radioligand (blue) or the radioligand without the immunoconjugate (red). The three treatment groups received huA33-TCO (100 µg, 0.6 nmol) followed 24 h later by either 18.5 (green), 37.0 (purple), or 55.5 (orange) MBq (~0.8 nmol in each case) of [177Lu]-DOTA-PEG7-Tz. This figure has been modified from reference #28. Reprinted (adapted) with permission from Membreno, R., Cook, B. E., Fung, K., Lewis, J. S., & Zeglis, B. M. Click-Mediated Pretargeted Radioimmunotherapy of Colorectal Carcinoma. Molecular Pharmaceutics. 15 (4), 1729-1734 (2018). Copyright 2018 American Chemical Society. Please click here to view a larger version of this figure.
Compound | 1H-NMR Shifts | HRMS (ESI) |
500 MHz, DMSO | ||
Tz-PEG7-NHBoc | 10.52 (s, 1H), 8.50 (m, 3H), 7.82 (t, 1H), 7.46 (d, 2H), 6.69 (t, 1H), 4.33 (d, 2H), 3.42 (m, 22H), 3.33 (t, 2H), 3.31 (t, 2H), 3.12 (q, 2H), 2.99 (q, 2H), 2.12 (t, 2H), 2.03 (t, 2H), 2.12 (t, 2H), 1.70 (q, 2H), 1.29 (s, 9H) | m/z calcd. for C35H57N7O11Na: 774.4005; found: 774.4014. |
Tz-PEG7-NH2 | 10.58 (s, 1H), 8.46 (m, 2H), 7.87 (t, 1H), 7.75 (d, 2H), 7.52 (d, 1H), 4.40 (d, 2H), 3.60-3.50 (m, 26H), 3.40 (t, 2H), 3.32 (bs, 2H), 3.20 (q, 2H), 2.99 (bs, 2H), 2.19 (t, 2H), 2.12 (t, 2H), 1.79 (q, 2H). | m/z calcd. for C30H50N7O9: 652.3670; found: 652.3676. |
Tz-PEG7-DOTA | 10.57 (s, 1H), 9.63 (bs, 1H), 8.45 (m, 3H), 7.86 (m, 1H), 7.73 (bs, 1H), 7.54 (d, 2H), 7.41 (m, 2H), 7.19 (m, 2H), 6.54 (bs, 1H), 4.40 (d, 2H), 4.00-3.20 (m, 55H), 3.20 (q, 4H), 2.54 (s, 1H), 2.18 (t, 3H), 2.10 (t, 3H), 1.76 (q, 2H). | m/z calcd. for C50H76N11O15S: 1202.56; found: 1203.5741. |
Table 1. Characterization data for the organic compounds described in this protocol.
One of the strengths of this approach to in vivo pretargeting — especially in relation to strategies predicated on bispecific antibodies and radiolabeled haptens — is its modularity: trans-cyclooctene moieties can be appended to any antibody, and tetrazine radioligands can be radiolabeled with an extraordinary variety of radionuclides without impairing their ability to react with their click partners. Yet the adaptation of this approach to other antibody/antigen system is not as simple as duplicating the protocol described here. Of course, any attempt to create a new mAb-TCO immunoconjugate or a novel tetrazine-bearing radioligand should be accompanied by the appropriate chemical and biological characterization assays, including tests for stability and reactivity. But beyond this, there are two variables that are particularly important to explore and optimize: (1) the mass of mAb-TCO immunoconjugate administered and (2) the interval time between the injection of the mAb-TCO and the administration of the radioligand. Both factors can dramatically influence the in vivo behavior of the pretargeting system. For example, the use of overly high doses of immunoconjugate or interval periods that are too short can result in undesirably high activity concentrations in the blood due to click reactions between the radioligand and immunoconjugate remaining in circulation. Conversely, employing masses of immunoconjugate that are too low or overly long interval periods can needlessly reduce activity concentrations in the tumor due to a failure to saturate the antigen or the inexorable (though slow) isomerization of the trans-cyclooctene to inactive cis-cyclooctene. Along these lines, performing biodistribution experiments using a range of masses of immunoconjugate and pretargeting intervals can be extraordinarily helpful. Of course, it is also recommended that appropriate controls be run in tandem with any in vivo experiments. These include — but are not limited to — experiments featuring antigen-negative cell lines, blocking cohorts that receive a vast excess of unconjugated antibody, the administration of the radioligand alone, the injection of the radioligand following a TCO-lacking immunoconjugate, and in vivo pretargeting using a non-specific, isotype control TCO-bearing immunoconjugate.
Alternatively, imaging experiments can be used for optimization if the therapeutic radionuclide emits positrons or ‘imageable’ photons or if an ‘imageable’ isotopologue of the therapeutic radionuclide is available. Ultimately, the sets of variables that provide the best balance of high tumoral activity concentrations and high tumor-to-background activity concentration ratios should be selected for subsequent longitudinal therapy studies. In the case presented here, 100 µg of huA33-TCO was injected with an interval of 24 h. Dosimetry calculations — particularly those that allow for the calculation of tumor doses and therapeutic ratios — can also be helpful during the process of optimization.
It is important to note that even the promising [177Lu]Lu-DOTA-PEG7-Tz/huA33-TCO system that has been developed could benefit from additional optimization. A comparison between the dosimetry data from this approach to PRIT and traditional RIT with a 177Lu-labeled variant of huA33 reveals that the tumor dose of PRIT lies below that of traditional RIT. Furthermore, the effective dose of the PRIT system (0.054 mSv/MBq) is only slightly lower than that of traditional RIT (0.068 mSv/MBq).
Two remedies to these issues are currently being explored. First, a dendritic scaffold has been developed capable of increasing the number of TCOs appended to each antibody30. In the context of pretargeted PET imaging, this approach dramatically boosts tumoral activity concentrations, and analogous experiments with [177Lu]Lu-DOTA-PEG7-Tz are underway. Second, the use of tetrazine-bearing clearing agents may be useful in the context of PRIT. The administration of clearing agents prior to the injection of the radioligand has been exploited in a variety of pretargeting methodologies as a way to decrease the concentration of residual immunoconjugate in the blood and thus reduce activity concentrations in healthy organs23,31. The use of clearing agents is not without its drawbacks, though; the most notable of which is increasing the complexity of an already admittedly complicated therapeutic modality. Nonetheless, researchers at Memorial Sloan Kettering Cancer Center recently published a compelling report on the creation a Tz-labeled dextran clearing agent for pretargeted PET imaging, and data on the use of this construct in conjunction with [177Lu]Lu-DOTA-PEG7-Tz and huA33-TCO are forthcoming32. Another approach to maximizing the dosimetric benefits of PRIT is the use of radionuclides with shorter physical half-lives. This has proven highly effective for imaging; however, therapeutic radionuclides with short physical half-lives are few and far between.
Finally, we would be remiss if we failed to properly address some of the intrinsic limitations of pretargeting based on the inverse electron demand Diels-Alder reaction. The first of these problems is inherent to all approaches to in vivo pretargeting: the antibody employed cannot be internalized upon binding to the target tissue. This, of course, is essential, as the antibody must remain accessible to the radioligand rather than sequestered in an intracellular compartment. This limitation is admittedly hard to circumvent, though it has been shown recently that antibodies with slow-to-moderate rates of internalizing can be used for in vivo pretargeting33,34. Second, the slow in vivo isomerization of reactive trans-cyclooctene to inactive cis-cyclooctene has the potential to limit the length of the interval between the administration of the TCO-bearing immunoconjugate and the injection of the radioligand. Critically, intervals of up to 120 h have still provided excellent results in the context of both pretargeted PET imaging and PRIT. However, the use of these longer intervals is almost always accompanied by slight reductions in tumoral activity concentrations, a result which may stem from this isomerization. In order to address this issue, several laboratories have attempted to create more stable trans-cyclooctenes without compromising reactivity, while others have tried to develop entirely new dienophiles capable of reacting with tetrazine35. In the coming years, it is our hope that these chemical developments will be leveraged for PRIT.
In the end, PRIT based on the inverse electron demand Diels-Alder ligation is undeniably an emergent and somewhat immature technology. However, we are nonetheless encouraged by the preclinical results we have obtained and excited for the clinical promise of this strategy. We sincerely hope that this protocol encourages others to explore and optimize this approach and thus fuel its journey from the laboratory to the clinic.
The authors have nothing to disclose.
The authors thank Dr. Jacob Houghton for helpful conversations. The authors would also like to thank the NIH for their generous funding (R00CA178205 and U01CA221046).
(E)-Cyclooct-4-enyl 2,5-dioxo-1-pyrrolidinyl carbonate (TCO-NHS) | Sigma-Aldrich | 764523 | Store at -80 °C |
2,5-Dioxo-1-pyrrolidinyl 5-[4-(1,2,4,5-tetrazin-3-yl)benzylamino]-5-oxopentanoate (Tz-NHS) | Sigma-Aldrich | 764701 | Store at -80 °C |
Acetonitrile (MeCN) | Fisher Scientific | A998-4 | |
Ammonium Acetate (NH4OAc) | Fisher Scientific | A639-500 | |
Boc-PEG7-amine (O-(2-Aminoethyl)-O′-[2-(Boc-amino)ethyl]hexaethylene glycol) | Sigma-Aldrich | 70023 | Store at -20 °C |
Dichloromethane (DCM) | Fisher Scientific | D143-1 | |
Dimethyl sulfoxide (DMSO), anhydrous | Fisher Scientific | D12345 | |
EMD Millipore Amicon Ultra-2 Centrifugal Filter Unit | Fisher Scientific | UFC205024 | |
GE Healthcare Disposable PD-10 Desalting Columns | Fisher Scientific | 45-000-148 | |
N,N-Dimethylformamide (DMF), anhydrous | Fisher Scientific | AC610941000 | |
Phosphate Buffered Saline (PBS) | Fisher Scientific | 70-011-044 | 10x Concentrated |
p-SCN-Bn-DOTA | Macrocyclics | B-205 | Store at -20 °C |
Triethylamine (TEA) | Fisher Scientific | AC157911000 | |
Trifluoroacetic Acid (TFA) | Fisher Scientific | A116-50 | |
Tumor measuring device | Peira TM900 | Peira TM900 |