Antibody Conjugates Research Articles

Capillary mediated vitrification is a novel technique that enables storage of antibody critical reagents at ambient temperature: Impact on binding, structure, and laboratory sustainability

Antibodies and antibody conjugates are essential components of life science research, but their inherent instability necessitates cold storage or lyophilization, posing logistical and sustainability challenges. Capillary-mediated vitrification has shown promise as a tool for improving biomolecule stability. In this study, we assess the feasibility of shipping and storing CMV-stabilized antibody reagents at ambient temperature using a purified rabbit polyclonal as a model system. The conditions tested included a simulated temperature excursion, ambient shipping, and storage for approximately two months at room-temperature. Antibody function was measured by both ELISA and Octet bio-layer interferometry kinetic measurements. Yield, aggregation, and thermal stability were assessed by UV/VIS, Size Exclusion Chromatography (SEC), thermal melting, and thermal aggregation studies. Results indicate >97 % protein yield and no impact on the binding activity. No evidence of aggregation or oligomer formation was detected. Addition of the vitrification buffer to the sample matrix resulted in an increase in the aggregation on-set temperature, indicating enhanced thermostability. A slight shift in both the SEC retention time for the main peak and a difference in aggregation behavior at high temperatures were noted post-vitrification. We hypothesize that these differences are related to the interaction of the protein with the saccharide component of the vitrification matrix and the stabilization mechanism of sugars. The cumulative data supports the use of Capillary Mediated Vitrification as a viable alternative to frozen reagent storage, with the potential to significantly impact reagent stability, assay performance, laboratory operations, and sustainability initiatives.

Aqueous Two-Phase Extraction of Single-Chirality Carbon Nanotubes with Functionalized ssDNA for Biomarker-Specific Antibody Conjugation

Multiplexed detection of biomarkers for cancer and chronic inflammatory diseases is necessary to improve diagnostic sensitivity and specificity. Our prior studies and that of others has used near-infrared fluorescent single-walled carbon nanotubes (SWCNT) as sensor transducers because of their sensitivity to the local environment, photostability, and emission in the tissue-transparent window. That work engineered the SWCNT surface through non-covalent interactions with short ssDNA oligonucleotides containing a functional group to which a biomarker-specific antibody was conjugated. Further, previous work by other groups has demonstrated the ability to obtain single SWCNT chiralities using the aqueous two-phase extraction (ATPE) technique with non-functionalized ssDNA sequences. Here, we have incorporated primary amine-functionalized ssDNA sequences into the ATPE separation technique to obtain individual SWCNT chiralities with functionalized ssDNA. To those primary amine-functionalized ssDNA-SWCNT complexes, we conjugated antibodies against two inflammatory cytokines. We investigated the sensitivity and specificity of these individual SWCNT chirality sensors specific to two biomarkers together in buffer and serum, finding that each chirality responds specifically only to its cognate biomarker and not the other. This is the first demonstration of single-chirality, molecularly-specific multiplexed SWCNT sensors. It forms the basis of ongoing work to obtain additional chiral species with other functional groups, as well as to develop multiplexed cytokine sensors for in vivo diagnostics.

Selection of antibody-binding covalent aptamers

Aptamers are oligonucleotides with antibody-like binding function, selected from large combinatorial libraries. In this study, we modified a DNA aptamer library with N-hydroxysuccinimide esters, enabling covalent conjugation with cognate proteins. We selected for the ability to bind to mouse monoclonal antibodies, resulting in the isolation of two distinct covalent binding motifs. The covalent aptamers are specific for the Fc region of mouse monoclonal IgG1 and are cross-reactive with mouse IgG2a and other IgGs. Investigation into the covalent conjugation of the aptamers revealed a dependence on micromolar concentrations of Cu2+ ions which can be explained by residual catalyst remaining after modification of the aptamer library. The aptamers were successfully used as adapters in the formation of antibody-oligonucleotide conjugates (AOCs) for use in detection of HIV protein p24 and super-resolution imaging of actin. This work introduces a new method for the site-specific modification of native monoclonal antibodies and may be useful in applications requiring AOCs or other antibody conjugates.

Super-Resolved Protein Imaging Using Bifunctional Light-Up Aptamers.

Efficient labeling methods for protein visualization with minimal tag size and appropriate photophysical properties are required for single-molecule localization microscopy (SMLM), providing insights into the organization and interactions of biomolecules in cells at the molecular level. Among the fluorescent light-up aptamers (FLAPs) originally developed for RNA imaging, RhoBAST stands out due to its remarkable brightness, photostability, fluorogenicity, and rapid exchange kinetics, enabling super-resolved imaging with high localization precision. Here, we expand the applicability of RhoBAST to protein imaging by fusing it to protein-binding aptamers. The versatility of such bifunctional aptamers is demonstrated by employing a variety of protein-binding aptamers and different FLAPs. Moreover, fusing RhoBAST with the GFP-binding aptamer AP3 facilitates high- and super-resolution imaging of GFP-tagged proteins, which is particularly valuable in view of the widespread availability of plasmids and stable cell lines expressing proteins fused to GFP. The bifunctional aptamers compare favorably with standard antibody-based immunofluorescence protocols, as they are 7-fold smaller than antibody conjugates and exhibit higher bleaching-resistance. We demonstrate the effectiveness of our approach in super-resolution microscopy in secondary mammalian cell lines and primary neurons by RhoBAST-PAINT, an SMLM protein imaging technique that leverages the transient binding of the fluorogenic rhodamine dye SpyRho to RhoBAST.

Antibody Drug Conjugates for Cancer Therapy: From Metallodrugs to Nature-Inspired Payloads.

This review highlights significant advancements in antibody-drug conjugates (ADCs) equipped with metal-based and nature-inspired payloads, focusing on synthetic strategies for antibody conjugation. Traditional methods such us maleimide and succinimide conjugation and classical condensation reactions are prevalent for metallodrugs and natural compounds. However, emerging non-conventional strategies such as photoconjugation are gaining traction due to their milder conditions and, in an aspect which minimizes side reactions, selective formation of ADC. The review also summarizes the therapeutic and diagnostic properties of these ADCs, highlighting their enhanced selectivity and reduced side effects in cancer treatment compared to non-conjugated payloads. ADCs combine the specificity of monoclonal antibodies with the cytotoxicity of chemotherapy drugs, offering a targeted approach to the elimination of cancer cells while sparing healthy tissues. This targeted mechanism has demonstrated impressive clinical efficacy in various malignancies. Key future advancements include improved linker technology for enhanced stability and controlled release of cytotoxic agents, incorporation of novel, more potent, cytotoxic agents, and the identification of new cancer-specific antigens through genomic and proteomic technologies. ADCs are also expected to play a crucial role in combination therapies with immune checkpoint inhibitors, CAR-T cells, and small molecule inhibitors, leading to more durable and potentially curative outcomes. Ongoing research and clinical trials are expanding their capabilities, paving the way for more effective, safer, and personalized treatments, positioning ADCs as a cornerstone of modern medicine and offering new hope to patients.

Engineered Antibodies as Cancer Radiotheranostics.

Radiotheranostics is a rapidly growing approach in personalized medicine, merging diagnostic imaging and targeted radiotherapy to allow for the precise detection and treatment of diseases, notably cancer. Radiolabeled antibodies have become indispensable tools in the field of cancer theranostics due to their high specificity and affinity for cancer-associated antigens, which allows for accurate targeting with minimal impact on surrounding healthy tissues, enhancing therapeutic efficacy while reducing side effects, immune-modulating ability, and versatility and flexibility in engineering and conjugation. However, there are inherent limitations in using antibodies as a platform for radiopharmaceuticals due to their natural activities within the immune system, large size preventing effective tumor penetration, and relatively long half-life with concerns for prolonged radioactivity exposure. Antibody engineering can solve these challenges while preserving the many advantages of the immunoglobulin framework. In this review, the goal is to give a general overview of antibody engineering and design for tumor radiotheranostics. Particularly, the four ways that antibody engineering is applied to enhance radioimmunoconjugates: pharmacokinetics optimization, site-specific bioconjugation, modulation of Fc interactions, and bispecific construct creation are discussed. The radionuclide choices for designed antibody radionuclide conjugates and conjugation techniques and future directions for antibody radionuclide conjugate innovation and advancement are also discussed.

Treatment with chemotherapy plus brentuximab vedotin in anaplastic large cell lymphoma and pregnancy: A case report

Introduction: Brentuximab vedotin (BV) is a CD-30 directed antibody and microtubule inhibitor conjugate indicated for the treatment of multiple types of lymphoma, including anaplastic large cell lymphoma (ALCL). Consensus-based guidelines recommend BV with cyclophosphamide, doxorubicin, and prednisone (CHP) as first-line treatment in a patient with ALCL. Alternative treatment options for ALCL can be limited due to patient-specific factors. Lymphomas account for approximately 11% of cancers in pregnancy. Brentuximab vedotin has not been studied in pregnancy; therefore, making the use of an antibody drug conjugate in this patient the first documented use in pregnancy. Case Report: A 26-year-old female was diagnosed with anaplastic large cell lymphoma at 14 weeks gestation. The patient has a past medical history of ALCL in 2004 at eight years old and a prior miscarriage. Consensus-based guidelines recommend BV with cyclophosphamide, doxorubicin, and prednisone (CHP) as first-line treatment in a patient with ALCL. Treatment with BV plus CHP was initiated at 15 weeks gestation for a total of 6 cycles during the antepartum period. At 33 weeks gestation, the patient delivered a 4-pound infant male without complications, birth defects, or health disparities. Two additional cycles of BV and CHP were administered during the postpartum period. Complete remission has been achieved in this patient. Conclusion: The outcomes in this case indicate the potential safety of BV in patients after the first trimester of pregnancy.

HER2 Status in Low-grade Serous Ovarian Tumors.

Using immunohistochemistry, we examined a large cohort of 135 ovarian tumors, made up of 96 low-grade serous carcinomas (LGSCs) and 39 serous borderline tumors (micropapillary variant, mSBT), with the aim of exploring their HER2 status (overexpression). We followed with comprehensive genomic analyses on this sample set from our previous study, which revealed HER2 mutation in 5% (4/75) of LGSC and 10% (3/29) of mSBT. No cases were evaluated as HER2-positive, but 6 LGSCs and 1 mSBT were scored as HER2 1+, and 2 LGSCs and 1 mSBT showed the so-called HER2 "ultra-low" phenotype. This could be of clinical value as a potential therapeutical target concerning emerging therapeutic treatments (antibody conjugates). However, the clinical significance of this expression still needs to be established.

Electrocatalytic Reduction of Disulfide Bonds across Chemical Modalities.

The chemical properties of disulfides are leveraged in a wide array of applications, ranging from protein-drug conjugates for cancer treatment to self-healing materials. However, disulfide reduction strategies remain severely underdeveloped despite being the key to efficiently accessing the desired targets. Specifically, no homogeneous catalyst has been reported for this reaction, and conditions that allow the use of mild and green reductants (e.g., via electrochemical reduction) are not known. Herein, we unveil a vitamin B12-catalyzed, electrochemically driven protocol for efficiently reducing disulfide bonds in various aqueous buffers over a broad pH range. This robust and simple method is suitable for disulfide reductions of substrates ranging from small molecules to large proteins. Finally, one-pot reduction and conjugation of disulfide bonds in a monoclonal antibody were demonstrated to produce antibody conjugates.

Targeted HER2-positive cancer therapy using ADAPT6 fused to horseradish peroxidase

Targeted cancer therapy is a promising alternative to the currently established cancer treatments, aiming to selectively kill cancer cells while sparing healthy tissues. Hereby, molecular targeting agents, such as monoclonal antibodies, are used to bind to cancer cell surface markers specifically. Although these agents have shown great clinical success, limitations still remain such as low tumor penetration and off-target effects. To overcome this limitation, novel fusion proteins comprised of the two proteins ADAPT6 and Horseradish Peroxidase (HRP) were engineered. Cancer cell targeting is hereby enabled by the small scaffold protein ADAPT6, engineered to specifically bind to human epidermal growth factor receptor 2 (HER2), a cell surface marker overexpressed in various cancer types, while the enzyme HRP oxidizes the nontoxic prodrug indole-3-acetic acid (IAA) which leads to the formation of free radicals and thereby to cytotoxic effects on cancer cells. The high affinity to HER2, as well as the enzymatic activity of HRP, were still present for the ADAPT6-HRP fusion proteins. Further, in vitro cytotoxicity assay using HER2-positive SKOV-3 cells revealed a clear advantage of the fusion proteins over free HRP by association of the fusion proteins directly to the cancer cells and therefore sustained cell killing. This novel strategy of combining ADAPT6 and HRP represents a promising approach and a viable alternative to antibody conjugation for targeted cancer therapy.

Evaluation of a Novel Lateral Emitting Laser Fiber for Near-Infrared Photoimmunotherapy.

Near-infrared photoimmunotherapy (NIR-PIT) is a new cancer therapy that uses NIR light and conjugates of a tumor-targeting monoclonal antibody and phthalocyanine dye. In clinical practice, frontal and cylindrical diffusers are the only options for NIR illumination. However, illumination in a narrow space is technically difficult with such diffusers. Therefore, we evaluated a lateral illumination system using a lateral emitting laser (LEL) fiber. The LEL fiber illuminated a certain area in a lateral direction. NIR-PIT with an LEL fiber reduced luciferase activity in a light-dose-dependent manner in A431-GFP-luc cells in vitro and significantly suppressed tumor proliferation in a xenograft mouse model. To evaluate the usefulness of the LEL fiber in the illumination of a narrow space, a tumor was illuminated from the inside of a cylinder, mimicking a narrow space, and the fluorescence intensity in the tumor was monitored. In the frontal diffuser, NIR light was unevenly delivered and little light reached a distal tumor area from the illuminated side. By contrast, the LEL fiber allowed a uniform illumination of the entire tumor, and a loss of fluorescence was observed even in distal areas. These findings suggested that the LEL fiber can be used for NIR-PIT and is suitable for NIR light illumination in a narrow space.

On-Demand Thio-Succinimide Hydrolysis for the Assembly of Stable Protein-Protein Conjugates.

Chemical post-translational protein-protein conjugation is an important technique with growing applications in biotechnology and pharmaceutical research. Maleimides represent one of the most widely employed bioconjugation reagents. However, challenges associated with the instability of first- and second-generation maleimide technologies are yet to be fully addressed. We report the development of a novel class of maleimide reagents that can undergo on-demand ring-opening hydrolysis of the resulting thio-succinimide. This strategy enables rapid post-translational assembly of protein-protein conjugates. Thio-succinimide hydrolysis, triggered upon application of chemical, photochemical, or enzymatic stimuli, allowed homobifunctional bis-maleimide reagents to be applied in the production of stable protein-protein conjugates, with complete temporal control. Bivalent and bispecific protein-protein dimers constructed from small binders targeting antigens of oncological importance, PD-L1 and HER2, were generated with high purity, stability, and improved functionality compared to monomeric building blocks. The modularity of the approach was demonstrated through elaboration of the linker moiety through a bioorthogonal propargyl handle to produce protein-protein-fluorophore conjugates. Furthermore, extending the functionality of the homobifunctional reagents by temporarily masking reactive thiols included in the linker allowed the assembly of higher order trimeric and tetrameric single-domain antibody conjugates. The potential for the approach to be extended to proteins of greater biochemical complexity was demonstrated in the production of immunoglobulin single-domain antibody conjugates. On-demand control of thio-succinimide hydrolysis combined with the facile assembly of chemically defined homo- and heterodimers constitutes an important expansion of the chemical methods available for generating stable protein-protein conjugates.

Development of Peptide Paratope Mimics Derived from the Anti-ROR1 Antibody and Long-Acting Peptide-Drug Conjugates for Targeted Cancer Therapy.

Antibody-based targeted therapy in cancer faces a challenge due to uneven antibody distribution in solid tumors, hindering effective drug delivery. We addressed this by developing peptide mimetics with nanomolar-range affinity for Receptor Tyrosine Kinase-Like Orphan Receptor 1 (ROR1) using computational methods. These peptides showed both specific targeting and deep penetration in vitro and in vivo. Additionally, we created peptide-drug conjugates (PDCs) by linking targeting peptides to toxin drugs via various linkers and enhancing their in vivo half-life with fatty side chains for albumin binding. The antitumor candidate II-3 displayed exceptional affinity (KD = 1.72 × 10-9 M), internalization efficiency, anticancer potency (IC50 = 0.015 ± 0.002 μM), and pharmacokinetics (t1/2 = 2.6 h), showcasing a rational approach for designing PDCs with favorable tissue distribution and strong tumor penetration.

First site-specific conjugation method for native goat IgG antibodies via glycan remodeling at the conserved Fc region.

Despite their triumph in treating human diseases, antibody therapies for animals have gained momentum more slowly. However, the first approvals of animal antibodies for osteoarthritic pain in cats and dogs may herald the dawn of a new era. For example, goats are vital to economies around the world for their milk, meat, and hide products. It is therefore imperative to develop therapies to safeguard goats-with antibodies at the forefront. Goat antibodies will be crucial in the development of therapeutic antibodies, for example, as tracers to study antibody distribution in vivo, reagents to develop other therapeutic antibodies, and therapeutic agents themselves (e.g., antibody-drug conjugates). Hamstringing this effort is a still-burgeoning understanding of goat antibodies and their derivatization. Historically, goat antibody conjugates were generated through stochastic chemical modifications, producing numerous attachment sites and modification ratios, thereby deleteriously impacting antigen binding. Site-specific methods exist but often require substantial engineering and have not been demonstrated with goat antibodies. Nevertheless, we present herein a novel method to site-specifically conjugate native goat antibodies: chemo-enzymatic remodeling of the native Fc N-glycan introduces a reactive azide handle, after which click chemistry with strained alkyne partners affords homogeneous conjugates labeled only on the Fc domain. This process is robust, and resulting conjugates retain their antigen binding and specificity. To our knowledge, our report is the first for site-specific conjugation of native goat antibodies. Furthermore, our approach should be applicable to other animal antibodies-even with limited structural information-with similar success.

Loncastuximab Tesirine in the Treatment of Relapsed or Refractory Diffuse Large B-Cell Lymphoma.

Currently, a significant percentage of patients with DLBCL are refractory or relapse after a first line of immunochemotherapy. Second relapses after autologous stem cell transplantation or chimeric antigen receptor T-cell therapies present few treatment options and do not yield good results. New molecules have entered the immunotherapy arsenal. Loncastuximab tesirine comprises a humanized anti-CD19 monoclonal conjugated antibody, which consists of an anti-CD19 antibody and cytotoxic alkylating agent, SG3199. Several studies have proven its efficacy in the treatment of refractory cases of DLBCL with a good safety profile, with the main adverse effects being neutropenia, thrombopenia, and liver enzyme involvement. In this review, we explain the mechanism of action of this molecule, the clinical data that have led to its acceptance by the FDA, and the new therapeutic options that are proposed in association with this drug.

Corneal Toxicity in Patients Treated by BELANTAMAB MAFODOTIN: How to Improve and Facilitate Patients Follow-Up Using Refractive Shift?

Purpose: Multiple myeloma (MM) is the second most common neoplastic blood disease worldwide. Belantamab mafodotin is a new antibody conjugate anti-B-cell maturation antigen effective against refractory myelomas. It induces intracorneal microcysts leading to refractive fluctuations. The aim of this study is to assess the value of monitoring refractive fluctuations based on the location of microcystic-like epithelial changes (MECs) to facilitate patient follow-up. Methods: This observational and multicentric study was conducted using data collected from several French centers contacted through secure email through a standardized data collection table. Results: The fluctuation of objective refraction in spherical equivalent confirms a significant myopic shift from peripheral to central forms. A decrease in the best-corrected visual acuity (BCVA), an increase in keratometry, and an increase in central epithelial pachymetry have also been observed when MECs migrate toward the center. Conclusion: The myopization found in our study in patients with central and paracentral MECs is consistent with current literature. Fluctuations in BCVA, keratometry, and epithelial pachymetry are also consistent. This study is the first real-world study and highlights heterogeneity in follow-up, emphasizing the need to establish multidisciplinary follow-up strategies. The analysis of refractive fluctuations appears to be a reproducible and noninvasive screening method that could facilitate patient follow-up without the need for consultation focused on corneal diseases.

On Demand Bioorthogonal Switching of an Antibody-Conjugated SPECT Probe to a Cytotoxic Payload: from Imaging to Therapy.

Antibody-drug conjugates (ADCs) for the treatment of cancer aim to achieve selective delivery of a cytotoxic payload to tumor cells while sparing normal tissue. In vivo, multiple tumor-dependent and -independent processes act on ADCs and their released payloads to impact tumor-versus-normal delivery, often resulting in a poor therapeutic window. An ADC with a labeled payload would make synchronous correlations between distribution and tissue-specific pharmacological effects possible, empowering preclinical and clinical efforts to improve tumor-selective delivery; however, few methods to label small molecules without destroying their pharmacological activity exist. Herein, we present a bioorthogonal switch approach that allows a radiolabel attached to an ADC payload to be removed tracelessly at will. We exemplify this approach with a potent DNA-damaging agent, the pyrrolobenzodiazepine (PBD) dimer, delivered as an antibody conjugate targeted to lung tumor cells. The radiometal chelating group, DOTA, was attached via a novel trans-cyclooctene (TCO)-caged self-immolative para-aminobenzyl (PAB) linker to the PBD, stably attenuating payload activity and allowing tracking of biodistribution in tumor-bearing mice via SPECT-CT imaging (live) or gamma counting (post-mortem). Following TCO-PAB-DOTA reaction with tetrazines optimized for extra- and intracellular reactivity, the label was removed to reveal the unmodified PBD dimer capable of inducing potent tumor cell killing in vitro and in mouse xenografts. The switchable antibody radio-drug conjugate (ArDC) we describe integrates, but decouples, the two functions of a theranostic given that it can serve as a diagnostic for payload delivery in the labeled state, but can be switched on demand to a therapeutic agent (an ADC).

CURRENT DRUG THERAPY OPTIONS FOR DISSEMINATED HER2-POSITIVE BREAST CANCER AT THE KAZAKH SCIENTIFIC RESEARCH INSTITUTE OF ONCOLOGY AND RADIOLOGY: A CLINICAL CASE

Relevance: Distant outcomes of treatment for Her2neu-positive metastatic breast cancer are improving due to access to innovative drug therapies. The study aimed to demonstrate the initial experience of treating a patient with progressive disseminated hormone receptor-positive breast cancer expressing HER2 (3+) and nearly exhausted options for anti-tumor drug therapy using trastuzumab deruxtecan. Methods: The paper describes a clinical case of a female patient born in 1977 who was diagnosed with Stage IV breast cancer (T1N1M1), invasive ductal carcinoma, and treated at the Kazakh Institute of Oncology and Radiology (Almaty, Kazakhstan). Immunohistochemical luminal subtype “B” with Her2neu (3+) expression. Metastatic involvement of skeletal bones with pain syndrome, lungs, liver, axillary, parasternal, and para-mediastinal lymph nodes. Since June 2023, monoclonal antibody conjugate trastuzumab deruxtecan therapy was initiated. The efficacy of fifth-line therapy was assessed using RECIST 1.1 before and during treatment. According to RECIST 1.1., target lesions included a conglomerate of hyperplastic axillary lymph nodes on the right, measuring 1.6 cm, parasternal lymph node 1.6 cm, a lesion in the parenchyma of the lower lobe of the left lung 1.3 cm, lesions (n=2) in the parenchyma of segment 2 of the left liver lobe 1.8 cm and 3.6 cm. Non-target lesion: hyperplastic para-mediastinal lymph nodes SLD 9.9 cm. Results: Pain syndrome was completely relieved after treatment. According to RECIST 1.1. in April 2024, after 11 courses of therapy, target lesions showed size reduction: conglomerate of hyperplastic axillary lymph nodes on the right decreased to 1.0 cm, lesion in the parenchyma of the lower lobe of the left lung increased to 2.7 cm, parasternal lymph node was not visualized, lesions (n=2) in the parenchyma of segment 2 of the left liver lobe measured 1.6 cm and 2.7 cm. Non-target lesion: hyperplastic para-mediastinal lymph nodes were not visualized. Conclusion: According to the clinical study data (DESTINY-Breast02), applying antibody-drug conjugate (ADC) demonstrates better objective response and progression-free survival time in patients previously treated with trastuzumab and taxanes.

Chemical Production of Cytotoxic Bispecific Antibodies Using the Ugi Multicomponent Reaction.

Bispecific antibodies (bsAbs) have recently emerged as a promising platform for the treatment of several conditions, most importantly cancer. Based on the combination of two different antigen-binding motifs in a single macromolecule; bsAbs can either display the combined characteristics of their parent antibodies, or new therapeutic features, inaccessible by the sole combination of two distinct antibodies. While bsAbs are traditionally produced by molecular biology techniques, the chemical development of bsAbs holds great promises and strategies have just begun to surface. In this context, we took advantage of a chemical strategy based on the use of the Ugi reaction for the site-selective conjugation of whole antibodies and coupled the resulting conjugates in a bioorthogonal manner with Fab fragments, derived from various antibodies. We thus managed to produce five different bsAbs with 2 : 1 valency, with yields ranging from 20 % to 48 %, and showed that the affinity of the parent antibody was preserved in all bsAbs. We further demonstrated the interest of our strategy by producing two other bsAbs behaving as cytotoxic T cell engagers with IC50 values in the picomolar range in vitro.

Growth‐Induced Extinction Development of Gold Nanoclusters as Signal Transducers for Quantitative Immunoassays

AbstractSignal transducers are crucial in bioassay platforms for converting target detection into recordable signals. Commonly used color development for immunoassays involves enzymes and colorimetric substrates. However, due to cost and environmental issues, practical point‐of‐care testing requires alternative signal transducers. Growth‐induced extinction (absorption and scattering) of gold nanoclusters (AuNCs) is proposed as a novel approach for quantitative immunoassays. AuNCs devoid of localized surface plasmon resonance (LSPR) are used as seeds for growth reactions. Through reactions with a growth solution comprised of gold precursor and mild reductant, AuNCs of varying concentrations underwent controlled growth, resulting in nanoparticles of different sizes exhibiting distinct LSPR‐mediated extinction bands. Notably, the seed concentration exhibited a robust correlation with the resulting extinction of the grown particles on a small scale of 110 µL for a 96‐well microplate platform. To demonstrate this signal transduction mechanism, immunosorbent assays are performed using the conjugates of AuNC and detection antibody. The sandwich‐type assay successfully quantified a model antigen, human immunoglobulin G (hIgG), by monitoring LSPR wavelength and absorbance. This assay demonstrated a working range of 0.001–1 µg mL−1 and limit of detection of 1.19 ng mL−1. Signal transducers using the growth of AuNCs offer new alternative candidates for immunoassay platforms.