Your search keyword '"Goldman, Nathan"' showing total 25 results

1. Lasing in Non-Hermitian Flat Bands: Quantum Geometry, Coherence, and the Fate of Kardar-Parisi-Zhang Physics.

Author

Amelio I and Goldman N

Abstract

We show that lasing in flat-band lattices can be stabilized by means of the geometrical properties of the Bloch states, in settings where the single-particle dispersion is flat in both its real and imaginary parts. We illustrate a general projection method and compute the collective excitations, which display a diffusive behavior ruled by quantum geometry through a peculiar coefficient involving gain, losses and interactions, and entailing resilience against modulational instabilities. Then, we derive an equation of motion for the phase dynamics and identify a Kardar-Parisi-Zhang term of geometric origin. This term is shown to exactly cancel whenever the real and imaginary parts of the laser nonlinearity are proportional to each other, or when the uniform-pairing condition is satisfied. We confirm our results through numerical studies of the π-flux diamond chain. This Letter highlights the key role of Bloch geometric effects in nonlinear dissipative systems and KPZ physics, with direct implications for the design of laser arrays with enhanced coherence.

Published

2024

2. Cold-Atom Elevator: From Edge-State Injection to the Preparation of Fractional Chern Insulators.

Author

Wang B, Aidelsburger M, Dalibard J, Eckardt A, and Goldman N

Abstract

Optical box traps offer new possibilities for quantum-gas experiments. Building on their exquisite spatial and temporal control, we propose to engineer system-reservoir configurations using box traps, in view of preparing and manipulating topological atomic states in optical lattices. First, we consider the injection of particles from the reservoir to the system: this scenario is shown to be particularly well suited to activating energy-selective chiral edge currents, but also to prepare fractional Chern insulating ground states. Then, we devise a practical evaporative-cooling scheme to effectively cool down atomic gases into topological ground states. Our open-system approach to optical-lattice settings provides a new path for the investigation of ultracold quantum matter, including strongly correlated and topological phases.

Published

2024

3. Experimental demonstration of topological bounds in quantum metrology.

Author

Yu M, Li X, Chu Y, Mera B, Ünal FN, Yang P, Liu Y, Goldman N, and Cai J

Abstract

Quantum metrology is deeply connected to quantum geometry, through the fundamental notion of quantum Fisher information. Inspired by advances in topological matter, it was recently suggested that the Berry curvature and Chern numbers of band structures can dictate strict lower bounds on metrological properties, hence establishing a strong connection between topology and quantum metrology. In this work, we provide a first experimental verification of such topological bounds, by performing optimal quantum multi-parameter estimation and achieving the best possible measurement precision. By emulating the band structure of a Chern insulator, we experimentally determine the metrological potential across a topological phase transition, and demonstrate strong enhancement in the topologically non-trivial regime. Our work opens the door to metrological applications empowered by topology, with potential implications for quantum many-body systems., (© The Author(s) 2024. Published by Oxford University Press on behalf of China Science Publishing & Media Ltd.)

Published

2024

4. Nonlinear topological symmetry protection in a dissipative system.

Author

Coen S, Garbin B, Xu G, Quinn L, Goldman N, Oppo GL, Erkintalo M, Murdoch SG, and Fatome J

Abstract

We investigate experimentally and theoretically a system ruled by an intricate interplay between topology, nonlinearity, and spontaneous symmetry breaking. The experiment is based on a two-mode coherently-driven optical resonator where photons interact through the Kerr nonlinearity. In presence of a phase defect, the modal structure acquires a synthetic Möbius topology enabling the realization of spontaneous symmetry breaking in inherently bias-free conditions without fine tuning of parameters. Rigorous statistical tests confirm the robustness of the underlying symmetry protection, which manifests itself by a periodic alternation of the modes reminiscent of period-doubling. This dynamic also confers long term stability to various localized structures including domain walls, solitons, and breathers. Our findings are supported by an effective Hamiltonian model and have relevance to other systems of interacting bosons and to the Floquet engineering of quantum matter. They could also be beneficial to the implementation of coherent Ising machines., (© 2024. The Author(s).)

Published

2024

5. Connecting the Many-Body Chern Number to Luttinger's Theorem through Středa's Formula.

Author

Peralta Gavensky L, Sachdev S, and Goldman N

Abstract

Relating the quantized Hall response of correlated insulators to many-body topological invariants is a key challenge in topological quantum matter. Here, we use Středa's formula to derive an expression for the many-body Chern number in terms of the single-particle interacting Green's function and its derivative with respect to a magnetic field. In this approach, we find that this many-body topological invariant can be decomposed in terms of two contributions, N_{3}[G]+ΔN_{3}[G], where N_{3}[G] is known as the Ishikawa-Matsuyama invariant and where the second term involves derivatives of Green's function and the self-energy with respect to the magnetic perturbation. As a by-product, the invariant N_{3}[G] is shown to stem from the derivative of Luttinger's theorem with respect to the probe magnetic field. These results reveal under which conditions the quantized Hall conductivity of correlated topological insulators is solely dictated by the invariant N_{3}[G], providing new insight on the origin of fractionalization in strongly correlated topological phases.

Published

2023

6. Realization of a fractional quantum Hall state with ultracold atoms.

Author

Léonard J, Kim S, Kwan J, Segura P, Grusdt F, Repellin C, Goldman N, and Greiner M

Abstract

Strongly interacting topological matter 1 exhibits fundamentally new phenomena with potential applications in quantum information technology 2,3 . Emblematic instances are fractional quantum Hall (FQH) states 4 , in which the interplay of a magnetic field and strong interactions gives rise to fractionally charged quasi-particles, long-ranged entanglement and anyonic exchange statistics. Progress in engineering synthetic magnetic fields 5-21 has raised the hope to create these exotic states in controlled quantum systems. However, except for a recent Laughlin state of light 22 , preparing FQH states in engineered systems remains elusive. Here we realize a FQH state with ultracold atoms in an optical lattice. The state is a lattice version of a bosonic ν = 1/2 Laughlin state 4,23 with two particles on 16 sites. This minimal system already captures many hallmark features of Laughlin-type FQH states 24-28 : we observe a suppression of two-body interactions, we find a distinctive vortex structure in the density correlations and we measure a fractional Hall conductivity of σ H /σ 0  = 0.6(2) by means of the bulk response to a magnetic perturbation. Furthermore, by tuning the magnetic field, we map out the transition point between the normal and the FQH regime through a spectroscopic investigation of the many-body gap. Our work provides a starting point for exploring highly entangled topological matter with ultracold atoms 29-33 ., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

7. Publisher Correction: Quantized topological pumping of solitons in nonlinear photonics and ultracold atomic mixtures.

Author

Mostaan N, Grusdt F, and Goldman N

Published

2022

8. Quantized topological pumping of solitons in nonlinear photonics and ultracold atomic mixtures.

Author

Mostaan N, Grusdt F, and Goldman N

Abstract

Exploring the interplay between topological band structures and tunable nonlinearities has become possible with the development of synthetic lattice systems. In this emerging field of nonlinear topological physics, an experiment revealed the quantized motion of solitons in Thouless pumps and suggested that this phenomenon was dictated by the Chern number of the band from which solitons emanate. Here, we elucidate the origin of this nonlinear topological effect, by showing that the motion of solitons is established by the quantized displacement of the underlying Wannier functions. Our general theoretical approach, which fully clarifies the central role of the Chern number in solitonic pumps, provides a framework for describing the topological transport of nonlinear excitations in a broad class of physical systems. Exploiting this interdisciplinarity, we introduce an interaction-induced topological pump for ultracold atomic mixtures, where solitons of impurity atoms experience a quantized drift resulting from genuine interaction processes with their environment., (© 2022. The Author(s).)

Published

2022

9. A synthetic monopole source of Kalb-Ramond field in diamond.

Author

Chen M, Li C, Palumbo G, Zhu YQ, Goldman N, and Cappellaro P

Abstract

Magnetic monopoles play a central role in areas of physics that range from electromagnetism to topological matter. String theory promotes conventional vector gauge fields of electrodynamics to tensor gauge fields and predicts the existence of more exotic tensor monopoles. Here, we report the synthesis of a tensor monopole in a four-dimensional parameter space defined by the spin degrees of freedom of a single solid-state defect in diamond. Using two complementary methods, we characterized the tensor monopole by measuring its quantized topological charge and its emanating Kalb-Ramond field. By introducing a fictitious external field that breaks chiral symmetry, we further observed an intriguing spectral transition, characterized by spectral rings protected by mirror symmetries. Our work demonstrates the possibility of emulating exotic topological structures inspired by string theory.

Published

2022

10. The Weyl side of ultracold matter.

Author

Goldman N and Yefsah T

Subjects

Orbit

Published

2021

11. Experimental measurement of the quantum geometric tensor using coupled qubits in diamond.

Author

Yu M, Yang P, Gong M, Cao Q, Lu Q, Liu H, Zhang S, Plenio MB, Jelezko F, Ozawa T, Goldman N, and Cai J

Abstract

Geometry and topology are fundamental concepts, which underlie a wide range of fascinating physical phenomena such as topological states of matter and topological defects. In quantum mechanics, the geometry of quantum states is fully captured by the quantum geometric tensor. Using a qubit formed by an NV center in diamond, we perform the first experimental measurement of the complete quantum geometric tensor. Our approach builds on a strong connection between coherent Rabi oscillations upon parametric modulations and the quantum geometry of the underlying states. We then apply our method to a system of two interacting qubits, by exploiting the coupling between the NV center spin and a neighboring 13 C nuclear spin. Our results establish coherent dynamical responses as a versatile probe for quantum geometry, and they pave the way for the detection of novel topological phenomena in solid state., (© The Author(s) 2019. Published by Oxford University Press on behalf of China Science Publishing & Media Ltd.)

Published

2020

12. Coupling ultracold matter to dynamical gauge fields in optical lattices: From flux attachment to ℤ 2 lattice gauge theories.

Author

Barbiero L, Schweizer C, Aidelsburger M, Demler E, Goldman N, and Grusdt F

Abstract

From the standard model of particle physics to strongly correlated electrons, various physical settings are formulated in terms of matter coupled to gauge fields. Quantum simulations based on ultracold atoms in optical lattices provide a promising avenue to study these complex systems and unravel the underlying many-body physics. Here, we demonstrate how quantized dynamical gauge fields can be created in mixtures of ultracold atoms in optical lattices, using a combination of coherent lattice modulation with strong interactions. Specifically, we propose implementation of ℤ 2 lattice gauge theories coupled to matter, reminiscent of theories previously introduced in high-temperature superconductivity. We discuss a range of settings from zero-dimensional toy models to ladders featuring transitions in the gauge sector to extended two-dimensional systems. Mastering lattice gauge theories in optical lattices constitutes a new route toward the realization of strongly correlated systems, with properties dictated by an interplay of dynamical matter and gauge fields., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2019

13. Revealing Tensor Monopoles through Quantum-Metric Measurements.

Author

Palumbo G and Goldman N

Abstract

Monopoles are intriguing topological objects, which play a central role in gauge theories and topological states of matter. While conventional monopoles are found in odd-dimensional flat spaces, such as the Dirac monopole in three dimensions and the non-Abelian Yang monopole in five dimensions, more exotic objects were predicted to exist in even dimensions. This is the case of "tensor monopoles," which are associated with tensor (Kalb-Ramond) gauge fields, and which can be defined in four-dimensional flat spaces. In this work, we investigate the possibility of creating and measuring such a tensor monopole in condensed-matter physics by introducing a realistic three-band model defined over a four-dimensional parameter space. Our probing method is based on the observation that the topological charge of this tensor monopole, which we relate to a generalized Berry curvature, can be directly extracted from the quantum metric. We propose a realistic three-level atomic system, where tensor monopoles could be generated and revealed through quantum-metric measurements.

Published

2018

14. State-recycling and time-resolved imaging in topological photonic lattices.

Author

Mukherjee S, Chandrasekharan HK, Öhberg P, Goldman N, and Thomson RR

Abstract

Photonic lattices-arrays of optical waveguides-are powerful platforms for simulating a range of phenomena, including topological phases. While probing dynamics is possible in these systems, by reinterpreting the propagation direction as time, accessing long timescales constitutes a severe experimental challenge. Here, we overcome this limitation by placing the photonic lattice in a cavity, which allows the optical state to evolve through the lattice multiple times. The accompanying detection method, which exploits a multi-pixel single-photon detector array, offers quasi-real time-resolved measurements after each round trip. We apply the state-recycling scheme to intriguing photonic lattices emulating Dirac fermions and Floquet topological phases. We also realise a synthetic pulsed electric field, which can be used to drive transport within photonic lattices. This work opens an exciting route towards the detection of long timescale effects in engineered photonic lattices and the realisation of hybrid analogue-digital simulators.

Published

2018

15. Experimental Observation of Aharonov-Bohm Cages in Photonic Lattices.

Author

Mukherjee S, Di Liberto M, Öhberg P, Thomson RR, and Goldman N

Abstract

We report on the experimental realization of a uniform synthetic magnetic flux and the observation of Aharonov-Bohm cages in photonic lattices. Considering a rhombic array of optical waveguides, we engineer modulation-assisted tunneling processes that effectively produce nonzero magnetic flux per plaquette. This synthetic magnetic field for light can be tuned at will by varying the phase of the modulation. In the regime where half a flux quantum is realized in each plaquette, all the energy bands dramatically collapse into nondispersive (flat) bands and all eigenstates are completely localized. We demonstrate this Aharonov-Bohm caging by studying the propagation of light in the bulk of the photonic lattice. Besides, we explore the dynamics on the edge of the lattice and discuss how the corresponding edge states can be continuously connected to the topological edge states of the Creutz ladder. Our photonic lattice constitutes an appealing platform where the interplay between engineered gauge fields, frustration, localization, and topological properties can be finely studied.

Published

2018

16. Probing topology by "heating": Quantized circular dichroism in ultracold atoms.

Author

Tran DT, Dauphin A, Grushin AG, Zoller P, and Goldman N

Abstract

We reveal an intriguing manifestation of topology, which appears in the depletion rate of topological states of matter in response to an external drive. This phenomenon is presented by analyzing the response of a generic two-dimensional (2D) Chern insulator subjected to a circular time-periodic perturbation. Because of the system's chiral nature, the depletion rate is shown to depend on the orientation of the circular shake; taking the difference between the rates obtained from two opposite orientations of the drive, and integrating over a proper drive-frequency range, provides a direct measure of the topological Chern number (ν) of the populated band: This "differential integrated rate" is directly related to the strength of the driving field through the quantized coefficient η 0 = ν/ ℏ 2 , where h = 2π ℏ is Planck's constant. Contrary to the integer quantum Hall effect, this quantized response is found to be nonlinear with respect to the strength of the driving field, and it explicitly involves interband transitions. We investigate the possibility of probing this phenomenon in ultracold gases and highlight the crucial role played by edge states in this effect. We extend our results to 3D lattices, establishing a link between depletion rates and the nonlinear photogalvanic effect predicted for Weyl semimetals. The quantized circular dichroism revealed in this work designates depletion rate measurements as a universal probe for topological order in quantum matter.

Published

2017

17. Experimental observation of anomalous topological edge modes in a slowly driven photonic lattice.

Author

Mukherjee S, Spracklen A, Valiente M, Andersson E, Öhberg P, Goldman N, and Thomson RR

Abstract

Topological quantum matter can be realized by subjecting engineered systems to time-periodic modulations. In analogy with static systems, periodically driven quantum matter can be topologically classified by topological invariants, whose non-zero value guarantees the presence of robust edge modes. In the high-frequency limit of the drive, topology is described by standard topological invariants, such as Chern numbers. Away from this limit, these topological numbers become irrelevant, and novel topological invariants must be introduced to capture topological edge transport. The corresponding edge modes were coined anomalous topological edge modes, to highlight their intriguing origin. Here we demonstrate the experimental observation of these topological edge modes in a 2D photonic lattice, where these propagating edge states are shown to coexist with a quasi-localized bulk. Our work opens an exciting route for the exploration of topological physics in time-modulated systems operating away from the high-frequency regime.

Published

2017

18. Dynamic Optical Lattices of Subwavelength Spacing for Ultracold Atoms.

Author

Nascimbene S, Goldman N, Cooper NR, and Dalibard J

Abstract

We propose a scheme for realizing lattice potentials of subwavelength spacing for ultracold atoms. It is based on spin-dependent optical lattices with a time-periodic modulation. We show that the atomic motion is well described by the combined action of an effective, time-independent lattice of small spacing, together with a micromotion associated with the time modulation. A numerical simulation shows that an atomic gas can be adiabatically loaded into the effective lattice ground state, for time scales comparable to the ones required for adiabatic loading of standard optical lattices. We generalize our scheme to a two-dimensional geometry, leading to Bloch bands with nonzero Chern numbers. The realization of lattices of subwavelength spacing allows for the enhancement of energy scales, which could facilitate the achievement of strongly correlated (topological) states.

Published

2015

19. Observation of a Localized Flat-Band State in a Photonic Lieb Lattice.

Author

Mukherjee S, Spracklen A, Choudhury D, Goldman N, Öhberg P, Andersson E, and Thomson RR

Abstract

We demonstrate the first experimental realization of a dispersionless state, in a photonic Lieb lattice formed by an array of optical waveguides. This engineered lattice supports three energy bands, including a perfectly flat middle band with an infinite effective mass. We analyze, both experimentally and theoretically, the evolution of well-prepared flat-band states, and show their remarkable robustness, even in the presence of disorder. The realization of flat-band states in photonic lattices opens an exciting door towards quantum simulation of flat-band models in a highly controllable environment.

Published

2015

20. Complications from computed tomography-guided core needle biopsy for patients receiving stereotactic body radiation therapy for early-stage lesions of the lung.

Author

Chowdhry VK, Chowdhry AK, Goldman N, Scalzetti EM, Grage RA, and Bogart JA

Subjects

Aged, Aged, 80 and over, Carcinoma, Non-Small-Cell Lung pathology, Carcinoma, Non-Small-Cell Lung radiotherapy, Chest Tubes statistics & numerical data, Female, Humans, Lung diagnostic imaging, Lung Neoplasms pathology, Lung Neoplasms radiotherapy, Male, Middle Aged, Neoplasm Staging, Pneumothorax etiology, Radiosurgery, Retrospective Studies, Risk, Tomography, X-Ray Computed, Biopsy, Large-Core Needle adverse effects, Carcinoma, Non-Small-Cell Lung diagnosis, Image-Guided Biopsy adverse effects, Lung pathology, Lung Neoplasms diagnosis

Abstract

Background: Obtaining a tissue diagnosis has traditionally been standard practice before initiating therapy for early-stage non-small-cell lung cancer (NSCLC). In several recent studies from Europe and Asia, a substantial proportion of patients have received stereotactic body radiation therapy (SBRT) based only on the imaging characteristics of the suspicious lesion. The underlying assumption is that the risk of percutaneous needle biopsy may outweigh the benefits in a population that generally has underlying pulmonary dysfunction and other medical comorbidity. Nevertheless, there is limited information regarding biopsy-related complication rates in high-risk patients with early-stage NSCLC who are treated with SBRT., Materials and Methods: This was a retrospective review of outcomes after biopsy in patients treated with SBRT. Complications of percutaneous core needle biopsy were analyzed in relation to patient and tumor characteristics. Each biopsy event was analyzed independently for patients with multiple biopsies., Results: A total of 112 percutaneous biopsies were performed in 103 patients. Pneumothorax of any degree was observed in 40 patients (35%) (95% CI, 27%-45%), and 12 patients (10.7%) had a clinically significant pneumothorax requiring chest tube placement (95% CI, 6%-18%). The time to first fraction of SBRT was not different in patients who had a pneumothorax or placement of a chest tube. On multivariate analysis, age, performance status, smoking history, pack-years of smoking, chronic obstructive pulmonary disease history, and forced expiratory volume in the first second of expiration were not statistically significantly associated with chest tube placement., Conclusion: Computed tomography-guided needle biopsy in a primarily medically inoperable patient population is safe, with an acceptable degree of complications., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

21. Extracting the Chern number from the dynamics of a Fermi gas: implementing a quantum Hall bar for cold atoms.

Author

Dauphin A and Goldman N

Abstract

We propose a scheme to measure the quantized Hall conductivity of an ultracold Fermi gas initially prepared in a topological Chern insulating phase and driven by a constant force. We show that the time evolution of the center of mass, after releasing the cloud, provides a direct and clear signature of the topologically invariant Chern number. We discuss the validity of this scheme, highlighting the importance of driving the system with a sufficiently strong force to displace the cloud over measurable distances while avoiding band-mixing effects. The unusual shapes of the driven atomic cloud are qualitatively discussed in terms of a semiclassical approach.

Published

2013

22. Direct imaging of topological edge states in cold-atom systems.

Author

Goldman N, Dalibard J, Dauphin A, Gerbier F, Lewenstein M, Zoller P, and Spielman IB

Subjects

Physics, Cold Temperature, Gases chemistry, Models, Chemical, Phase Transition, Quantum Theory

Abstract

Detecting topological order in cold-atom experiments is an ongoing challenge, the resolution of which offers novel perspectives on topological matter. In material systems, unambiguous signatures of topological order exist for topological insulators and quantum Hall devices. In quantum Hall systems, the quantized conductivity and the associated robust propagating edge modes--guaranteed by the existence of nontrivial topological invariants--have been observed through transport and spectroscopy measurements. Here, we show that optical-lattice-based experiments can be tailored to directly visualize the propagation of topological edge modes. Our method is rooted in the unique capability for initially shaping the atomic gas and imaging its time evolution after suddenly removing the shaping potentials. Our scheme, applicable to an assortment of atomic topological phases, provides a method for imaging the dynamics of topological edge modes, directly revealing their angular velocity and spin structure.

Published

2013

23. Detecting chiral edge states in the Hofstadter optical lattice.

Author

Goldman N, Beugnon J, and Gerbier F

Abstract

We propose a realistic scheme to detect topological edge states in an optical lattice subjected to a synthetic magnetic field, based on a generalization of Bragg spectroscopy sensitive to angular momentum. We demonstrate that using a well-designed laser probe, the Bragg spectra provide an unambiguous signature of the topological edge states that establishes their chiral nature. This signature is present for a variety of boundaries, from a hard wall to a smooth harmonic potential added on top of the optical lattice. Experimentally, the Bragg signal should be very weak. To make it detectable, we introduce a "shelving method," based on Raman transitions, which transfers angular momentum and changes the internal atomic state simultaneously. This scheme allows us to detect the weak signal from the selected edge states on a dark background, and drastically improves the detectivity. It also leads to the possibility to directly visualize the topological edge states, using in situ imaging, offering a unique and instructive view on topological insulating phases.

Published

2012

24. Cell-compatible, multicomponent protein arrays with subcellular feature resolution.

Author

Mei Y, Cannizzaro C, Park H, Xu Q, Bogatyrev SR, Yi K, Goldman N, Langer R, and Anderson DG

Subjects

Animals, Cell Adhesion, Cell Line, Cell Movement, Fluorescence, Humans, Mice, Subcellular Fractions, Myoblasts cytology, Protein Array Analysis methods

Published

2008

25. Comparison of effects of 2 harvesting methods on fat autograft.

Author

Park H, Williams R, Goldman N, Choe H, Kobler J, Lopez-Guerra G, Heaton JT, Langer R, and Zeitels SM

Subjects

Abdominal Fat cytology, Abdominal Fat enzymology, Abdominal Fat surgery, Adult, Animals, Cell Proliferation, Female, Ferrets, Glycerolphosphate Dehydrogenase metabolism, Humans, Immunohistochemistry, Male, Transplantation, Autologous, Vacuum Curettage, Vocal Cords surgery, Abdominal Fat transplantation, Lipectomy methods

Abstract

Objectives/hypothesis: Fat preparation for vocal-fold injection medialization is typically done by scraping of excised fat or by lipo-aspiration; however, lipo-aspiration is substantially more efficient. Considering this, we compared viability of fat tissues obtained by these two techniques. We also examined whether basic fibroblast growth factor (bFGF) would increase cell proliferation in samples harvested by these methods., Study Design: Harvesting techniques (scraping and lipo-aspiration) were compared using both human and ferret fat. In vitro assays were used to assess tissue viability and cell proliferation., Methods: Human (n = 5) and ferret (n = 15) abdominal fat specimens were harvested by scraping and lipo-aspiration, for a total of 40 specimens. Alamar Blue and glycerol-3-phosphate dehydrogenase assays were used to quantitatively assess metabolic activity and cellular damage immediately after harvest. PicoGreen assays assessed cell proliferation by quantifying total DNA in harvested specimens after 0, 14, or 21 days in culture. The effects of bFGF (10 ng/mL) on proliferation were measured for the same timepoints., Results: The glycerol-3-phosphate dehydrogenase assay indicated that lipo-aspiration caused more initial tissue damage (12 +/- 5 mU/mL) than scraping (5 +/- 3 mU/mL), but cell metabolic activity was similar in both groups based on the Alamar Blue assay. Cell proliferation at 14 and 21 days was significantly higher for lipo-aspirated fat than for scraped fat (92.5 +/- 8.8 vs. 55.1 +/- 1.3 ng DNA at 14 days and 111.1 +/- 10.5 vs. 44.6 +/- 4.1 ng DNA at 21 days). bFGF increased fibroblast-like cell proliferation significantly for both harvesting methods at day 21., Conclusions: Lipo-aspiration caused more initial damage than scraping, but may yield better long-term viability based on increased proliferation. bFGF may enhance cellularity of the stromal component grafted adipose tissue.

Published

2008