Destacats

Cada any, un comitè d'experts s'ha d'enfrontar a la difícil tasca d'escolllir, d'entre totes les publicacions ICREA, unes poques que destaquin sobre la resta. És tot un repte: de vegades els debats s'acaloren, i sempre són difícils, però acaba sortint-ne una llista amb les millors publicacions de l'any. No es concedeix cap premi, i l'únic reconeixement addicional és l'honor d'ésser presentat com a Highlight. Cada publicació té alguna cosa especial, sia una solució especialment elegant a un vell problema, un resó espectacular als mitjans de comunicació o simplement, la fascinació d'una idea revolucionària. Independentment del motiu, es tracta dels millors dels millors i, com a tals, ens plau compartir-los aquí.

LIST OF SCIENTIFIC HIGHLIGHTS

Format: yyyy
  • Seeing Single Nanocrystals by Stimulated Emission (2019)

    van Hulst, Niek F. (ICFO)

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    Seeing Single Nanocrystals by Stimulated Emission

    Detection and imaging of single-molecules has become routine over the last 3 decades, with a wide range of applications, particularly in biology, but also in physics and chemistry. To date such imaging relies almost fully on detection of fluorescence as the red-shifted photons are easily counted and the background is virtually zero. Yet fluorescence imaging has its limits: first, only fluorescent (or labelled) samples can be perceived; second fluorescence is prone to bleaching; and finally fluorescence, spontaneous emission, is a slow, occurring on a timescale of nanoseconds. As a result one misses out on all coherences, vibrational dynamics, and ultrafast energy or charge transfer.

    At ICFO, we have developed a complementary approach, based on the detection of stimulated emission, with several advantages. All molecules can be stimulated to emit a photon, also those that do not fluoresce. Most importantly the stimulation is ultrafast, in fact instantaneous, such that bleaching is avoided, while femto-picosecond dynamics of excited states is traced. The downside is that the stimulating laser beam also produces a significant amount of background light. We have overcome this challenge by using synchronized pump and probe pulses from the same broadband laser, ultrafast modulation, balanced and phase sensitive detection.

    In a first application, we show stimulated emission imaging of individual colloidal quantum dots at room temperature, while simultaneously recording the depleted spontaneous emission, enabling us to trace the carrier population through the entire photocycle. By capturing the femtosecond evolution of the stimulated emission signal, together with the nanosecond fluorescence, we disentangle the ultrafast charge trajectories in the excited state and determine the populations that experience stimulated emission, spontaneous emission, and excited-state absorption processes.

    Next we would like to extend our stimulated microscopy of single quantum systems to molecules and biomolecular complexes.

  • Neuromelanin: When darkness is the light to follow.   (2019)

    Vila Bover, Miquel (VHIR)

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    Neuromelanin: When darkness is the light to follow.  

    In Parkinson’s disease (PD) there is a preferential degeneration of neurons containing the dark-brown cytoplasmic pigment neuromelanin (NM), especially dopaminergic neurons of the substantia nigra the loss of which leads to the classical motor symptoms of PD. In humans, NM appears in early childhood and accumulates progressively with age, and increasing age is the main risk factor for developing PD. While the loss of pigmented nigral neurons in PD was first established a century ago and constitutes the cardinal pathologic diagnostic criteria for the disease, the potential contribution of NM to PD pathogenesis has remained largely unknown because, in contrast to humans, laboratory animal species commonly used in experimental research, such as rodents, lack NM. Thus, a factor so intimately linked to PD such as NM has been surprisingly neglected to date in experimental in vivo paradigms of the disease.

    To overcome this major limitation, we developed the first genetically-engineered rodent model exhibiting age-dependent production and accumulation of human-like NM within PD-vulnerable nigral neurons, at levels up to those reached in elderly humans. Using this unique animal model, we found that progressive intracellular build-up of NM with age ultimately compromised neuronal function when allowed to accumulate above a specific threshold, eventually triggering in an age-dependent manner all the main pathological features of PD. Relevant to humans, intracellular NM levels reached this pathogenic threshold in PD patients and pre-PD subjects but not in healthy elderly individuals. Importantly, the lowering of intracellular NM by gene therapy to levels below this pathogenic threshold reversed PD symptoms and pathology in NM-producing rodents. These results suggest that progressive, age-dependent intracellular NM accumulation above a pathogenic threshold might be responsible for the initiation of PD. Accordingly, strategies to maintain or decrease intracellular NM to levels below its pathogenic threshold may provide unprecedented therapeutic opportunities to prevent, halt or delay neuronal dysfunction and degeneration linked to PD and, in a broader sense, brain aging.

  • Rivers as main pathway of microplastic pollution to the ocean (2019)

    Ziveri, Patrizia (ICTA-UAB)

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    Rivers as main pathway of microplastic pollution to the ocean

    Rivers are considered the main pathway for microplastic pollution to reach oceans.  Microplastics are particles or fibers smaller than 5 mm. They can be “primary” microplastics such as raw material used to create plastic products (pellets), small particles used for cosmetic purposes, beads for industrial abrasive blasting media or fibers for textile purposes, or “secondary” microplastics, originating from the degradation of larger plastic items. Until now, studies on microplastic pollution have focused on their presence in oceans and seas, with little consideration given to rivers and estuaries as main sources of these pollutants. A recent study focussing on the Ebro Delta shows that Ebro's  surface waters annually discharge approximately 2.2 billion microplastics into the Mediterranean Sea.

    In the study, the values found in benthic sediments are 3-6 X higher than on sandy beaches of the estuarine system. This concentration is due to the influence of the salt wedge - spacing between fresh water and ocean water - where the flow velocity is lower and the retention time is longer. Overall, 70% of the microplastics found in the Ebro River Delta are synthetic fibers, followed by plastic fragments and films. Most of these fibers arrive to the river through wastewater effluents and treatment plants as a consequence of domestic and commercial laundry. Up to 2000 fibers can be released washing a single garment of clothing. Wastewater treatment plants are not able to remove all the textile fibers. 

    Transitional fresh and marine water systems - particularly near urbanized areas - are critical for microplastic research. Estimating the residence times of microplastics in this dynamic corridor to the ocean can help evaluate the hazard of these pollutants to organisms and ecosystems and, by extension, to human health.

  • Scaling silicon quantum photonics technology (2018)

    Acín Dal Maschio, Antonio (ICFO)

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    Scaling silicon quantum photonics technology

    Integrated Quantum Photonics allows the routing and control of single particles of light with intrinsically high stability and precision. However to date it has been limited to small-scale demonstrations in which only a small number of components are integrated on a chip. It is thus in high demand to scale up the integrated photonic circuits and increase the complexity and computational power of modern quantum information processing technologies that would enable many revolutionary applications. In fact, coherently and precisely controlling large quantum devices and complex multidimensional entanglement systems has been a challenging task owing to the complex interactions of correlated particles in large quantum systems.

    In an international research effort led by scientists from the University of Bristol’s Quantum Engineering Technology Labs, we demonstrated the first ever large-scale integrated quantum photonic circuit, which can generate, control and analyze high-dimensional entanglement with unprecedented high precision and generality. A programmable bipartite path-encoded multidimensional entangled system with dimension up to 15×15 was demonstrated, where each photon exists over 15 optical paths at the same time and the two photons are entangled with each other there. This multidimensional entanglement system is achieved by scaling up the silicon-photonics quantum circuits via a single chip integration of 550 optical components including 16 identical photon-pair sources, 93 optical phase-shifters, 122 beam-splitters, among other optical elements. The quantum chip was realised using a scalable silicon photonics technology, similar to today’s electronic circuits, which would provide a path to manufacture massive components for the realization of an optical quantum computer. The work was a joint effort of the Peking University, the Technical University of Denmark, ICFO, the Max Planck Institute of Quantum Optics, the Polish Academy of Sciences (PAS) and the University of Copenhagen.

  • A new paediatric-friendly formulation for the treatment of malaria in infants and young children (2018)

    Bassat Orellana, Quique (ISGlobal)

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    A new paediatric-friendly formulation for the treatment of malaria in infants and young children

    Paediatric-friendly formulations for the treatment of infants with malaria are scarce. A multicentre Phase II trial in sub-Saharan Africa, led by the Barcelona Institute for Global Health (ISGlobal), showed that a water-dispersible tablet is safe, efficacious and easy to administer to young children with uncomplicated P. falciparum malaria, and should set the basis for improving treatment compliance and efficacy in the population-group at most risk of developing life-threatening complications.

    Eurartesim™, a fixed-dose combination composed of dihydroartemisinin (DHA) and piperaquine phosphate (PQP), has been adopted by several endemic countries as first-line treatment of uncomplicated malaria due to its longer half-life and long post-treatment prophylactic effects. However, as infants and very young children are generally unable to swallow pills, Eurartesim™ tablets need to be crushed and mixed with water, resulting in possible loss of active ingredients and under-dosing. In addition, crushed antimalarial tablets have an unpleasant bitter taste causing children to spit them out.

    To overcome these problems, a new water dispersible tablet of DHA/PQP was developed for oral administration in infants and young children and tested in a large phase II multicentre trial with 300 African infants (6–12 months of age) from Mozambique, Burkina Faso, The Gambia, DR-Congo and Tanzania. Safety and efficacy was compared to that of the marketed tablet. Results showed that a standard three-day treatment with the new dispersible DHA/PQP paediatric formulation is as efficacious as the crushed Eurartesim™ tablets and has a comparable safety profile.

    “This highly efficacious formulation should be made readily available to all children below 5 years of age” says Quique Bassat, ISGlobal researcher and principal investigator of the study. “It is easy and safe to administer, and provides better grounds for enhanced compliance and effective treatment. This should facilitate drug registration by Regulatory Authorities, prequalification by WHO and, finally, its full adoption in malaria control programmes".

  • The discovery of a new class of immunotherapies for metastatic colorectal cancer (2018)

    Batlle Gómez, Eduard (IRB Barcelona)

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    The discovery of a new class of immunotherapies for metastatic colorectal cancer

    Colorectal cancer (CRC) kills around 700,000 people worldwide every year. The majority of these deaths are the result of the dissemination of the disease to foreign organs. The emergence of new treatment options for patients with late-stage CRC has extended survival periods, yet metastases remain incurable in the majority of patients. Our lab generated for the first time genetically engineered mouse models that develop aggressive human-like CRCs. Analysis of the process of metastasis in these mouse models revealed that tumor cells build an immunoprivileged microenvironment during organ colonization, that promotes T-cell exclusion and blocks the acquisition of an anti-tumor immune effector phenotype. We showed that this mechanism depends on elevated levels of the hormone TGF-beta present in the microenvironment of these metastases. Inhibition of TGF-beta signaling reverts this process and unleashes a potent cytotoxic T cell response against tumor cells, which is long lasting and protects mice from metastatic disease. In mice with progressed liver metastatic disease, blockade of TGF-beta signaling rendered tumors susceptible to anti-PD-1/PD-L1checkpoint immunotherapy. We show that dual TGF-beta/checkpoint therapy cures mice suffering from overt metastatic disease. Our findings suggest that TGF-beta signaling inhibitors may have broad applications to treat patients with advanced CRC. Their efficacy will soon be tested in clinical trials.