Your search keyword '"Perelman LT"' showing total 44 results

1. Coupling and scattering power exchange between phonon modes observed in surface-enhanced Raman spectra of single-wall carbon nanotubes on silver colloidal clusters

Author

Kneipp, K., Perelman, Lt, Kneipp, H., Backman, V., Ado Jorio, Dresselhaus, G., and Dresselhaus, Ms

2. Label-free characterization of organoids with quantitative confocal Raman spectral imaging.

Author

Coughlan MF and Perelman LT

Subjects

Organoids, Serogroup, Stem Cells, Diagnostic Imaging, Drug Discovery

Abstract

Stem cell-derived organoids have the potential to significantly improve the drug discovery process. However, a key challenge is monitoring the maturation process and drug response. In this issue of Cell Reports Methods , LaLone et al. have shown that quantitative confocal Raman spectral imaging, a label-free technique, can reliably monitor organoid development, drug accumulation, and drug metabolism., Competing Interests: The authors declare no competing interests., (© 2023 The Author(s).)

Published

2023

3. In vivo detection of bile duct pre-cancer with endoscopic light scattering spectroscopy.

Author

Pleskow DK, Sawhney MS, Upputuri PK, Berzin TM, Coughlan MF, Khan U, Glyavina M, Zhang X, Chen L, Sheil CJ, Cohen JM, Vitkin E, Zakharov YN, Itzkan I, Zhang L, Qiu L, and Perelman LT

Subjects

Humans, Prospective Studies, Cholangiopancreatography, Endoscopic Retrograde methods, Bile Ducts diagnostic imaging, Bile Ducts, Intrahepatic, Spectrum Analysis, Bile Duct Neoplasms diagnostic imaging, Cholangiocarcinoma

Abstract

Bile duct cancer is the second most common primary liver cancer, with most diagnoses occurring in the advanced stages. This leads to a poor survival rate, which means a technique capable of reliably detecting pre-cancer in the bile duct is urgently required. Unfortunately, radiological imaging lacks adequate accuracy for distinguishing dysplastic and benign biliary ducts, while endoscopic techniques, which can directly assess the bile duct lining, often suffer from insufficient sampling. Here, we report an endoscopic optical light scattering technique for clinical evaluation of the malignant potential of the bile duct. This technique employs an ultraminiature spatial gating fiber optic probe compatible with cholangioscopes and endoscopic retrograde cholangiopancreatography (ERCP) catheters. The probe allowed us to investigate the internal cellular composition of the bile duct epithelium with light scattering spectroscopy (LSS) and phenotypic properties of the underlying connective tissue with diffuse reflectance spectroscopy (DRS). In a pilot in vivo double-blind prospective study involving 29 patients undergoing routine ERCP procedures, the technique detected malignant transformation with 97% accuracy, showing that biliary duct pre-cancer can be reliably identified in vivo non-invasively., (© 2023. The Author(s).)

Published

2023

4. Biopsy channel of the endoscope as a potential source of infectious droplets during GI endoscopy.

Author

Coughlan MF, Sawhney MS, Pleskow DK, Khan U, Silva-Santisteban A, Ahmed A, Zhang X, Glyavina M, Chen L, Upputuri PK, Zakharov YN, Zhang L, Qiu L, and Perelman LT

Subjects

Humans, Endoscopy, Gastrointestinal, Biopsy, Endoscopy, Water, Endoscopes, Communicable Diseases

Abstract

Background and Aims: During endoscopy, droplets with the potential to transmit infectious diseases are known to emanate from a patient's mouth and anus, but they may also be expelled from the biopsy channel of the endoscope. The main goal of our study was to quantify droplets emerging from the biopsy channel during clinical endoscopy., Methods: A novel light-scattering device was used to measure droplets emanating from the biopsy channel. An endoscopy model was created, and in vitro measurements were carried out during air insufflation, air and water suctioning, and the performance of biopsy sampling. Similar measurements were then made on patients undergoing endoscopy, with all measurements taking place over 2 days to minimize variation., Results: During in vitro testing, no droplets were observed at the biopsy channel during air insufflation or air and water suctioning. In 3 of 5 cases, droplets were observed during biopsy sampling, mostly when the forceps were being removed from the endoscope. In the 22 patients undergoing routine endoscopy, no droplets were observed during air insufflation and water suctioning. Droplets were detected in 1 of 11 patients during air suctioning. In 9 of 18 patients undergoing biopsy sampling and 5 of 6 patients undergoing snare polypectomies, droplets were observed at the biopsy channel, mostly when instruments were being removed from the endoscope., Conclusions: We found that the biopsy channel may be a source of infectious droplets, especially during the removal of instruments from the biopsy channel. When compared with droplets reported from the mouth and anus, these droplets were larger in size and therefore potentially more infectious., (Copyright © 2022 American Society for Gastrointestinal Endoscopy. Published by Elsevier Inc. All rights reserved.)

Published

2022

5. Development of a Scalable Three-Dimensional Culture of Human Induced Pluripotent Stem Cells-Derived Liver Organoids.

Author

Pettinato G, Perelman LT, and Fisher RA

Subjects

Cell Differentiation, Embryoid Bodies, Hepatocytes metabolism, Humans, Liver, Induced Pluripotent Stem Cells, Organoids

Abstract

Human induced pluripotent stem cells (hiPSCs) represent a powerful tool for the generation of specialized cells to be used in regenerative medicine as well as hepatocellular repopulation tool to treat liver metabolic diseases such as nonalcoholic steatohepatitis (NASH). Here we describe a strategy to obtain fully functional liver organoids from hiPSCs in a scalable manner. Our approach uses a two-step process, with a first step involving the scalable formation of homogeneous and uniform-sized human embryoid bodies (hEBs), followed by the application of a four-step liver differentiation protocol for the derivation of liver organoids that possess all the features of primary human hepatocytes. This chapter will also illustrate the characterization of the liver organoids by directed biomolecular techniques., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2022

6. Rapid detection and identification of bacteria directly from whole blood with light scattering spectroscopy based biosensor.

Author

Qiu L, Zhang L, Horowitz GL, Turzhitsky V, Coughlan MF, Glyavina M, Khan U, Zakharov YN, Vitkin E, Itzkan I, and Perelman LT

Abstract

Bacterial infections are one of the major causes of death worldwide. The identification of a bacterial species that is the source of an infection generally takes a long time, and often exceeds the treatment window for seriously ill patients. Many of these deaths are preventable if the bacterial species can be identified quickly. Here we present an optical spectroscopic method for rapid detection and identification of bacteria directly from whole blood using a light scattering spectroscopy technique. This technique was originally developed to detect pre-cancerous changes in epithelial tissues, characterize changes in tissue on the cellular scale, and characterize biological structures comparable to or smaller than a single wavelength. We demonstrate here that not only can an inexpensive light scattering spectroscopy-based biosensor rapidly detect and identify four bacteria species in the blood, responsible for the majority of death causing infections, but that species-level identification can potentially be made based on approximately one thousand bacterial cells per milliliter of blood. Observing entire colonies or performing susceptibility testing is therefore not required., Competing Interests: Declaration of competing interest The authors declare that they have no conflict of interest. Declaration of interests The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Published

2021

7. Measuring Droplets Expelled During Endoscopy to Investigate COVID-19 Transmission Risk.

Author

Coughlan MF, Sawhney MS, Pleskow DK, Sheil CJ, Qiu L, and Perelman LT

Subjects

Colonoscopy, Equipment and Supplies, Humans, Lasers, Light, Risk Assessment, SARS-CoV-2, COVID-19 transmission, Endoscopy, Occupational Exposure analysis, Scattering, Radiation

Published

2021

8. Spectroscopic label-free microscopy of changes in live cell chromatin and biochemical composition in transplantable organoids.

Author

Pettinato G, Coughlan MF, Zhang X, Chen L, Khan U, Glyavina M, Sheil CJ, Upputuri PK, Zakharov YN, Vitkin E, D'Assoro AB, Fisher RA, Itzkan I, Zhang L, Qiu L, and Perelman LT

Subjects

Cell Differentiation, Chromatin, Endothelial Cells, Humans, Microscopy, Induced Pluripotent Stem Cells, Organoids

Abstract

Organoids formed from human induced pluripotent stem cells (hiPSCs) could be a limitless source of functional tissue for transplantations in many organs. Unfortunately, fine-tuning differentiation protocols to form large quantities of hiPSC organoids in a controlled, scalable, and reproducible manner is quite difficult and often takes a very long time. Recently, we introduced a new approach of rapid organoid formation from dissociated hiPSCs and endothelial cells using microfabricated cell-repellent microwell arrays. This approach, when combined with real-time label-free Raman spectroscopy of biochemical composition changes and confocal light scattering spectroscopic microscopy of chromatin transition, allows for monitoring live differentiating organoids without the need to sacrifice a sample, substantially shortening the time of protocol fine-tuning. We used this approach to both culture and monitor homogeneous liver organoids that have the main functional features of the human liver and which could be used for cell transplantation liver therapy in humans., (Copyright © 2021 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

2021

9. Coherent confocal light scattering spectroscopic microscopy evaluates cancer progression and aggressiveness in live cells and tissue.

Author

Pleskow DK, Zhang L, Turzhitsky V, Coughlan MF, Khan U, Zhang X, Sheil CJ, Glyavina M, Chen L, Shinagare S, Zakharov YN, Vitkin E, Itzkan I, Perelman LT, and Qiu L

Abstract

The observation of biological structures in live cells beyond the diffraction limit with super-resolution fluorescence microscopy is limited by the ability of fluorescence probes to permeate live cells and the effect of these probes, which are often toxic, on cellular behavior. Here we present a coherent confocal light scattering and absorption spectroscopic microscopy that for the first time enables the use of large numerical aperture optics to characterize structures in live cells down to 10 nm spatial scales, well beyond the diffraction limit. Not only does this new capability allow high resolution microscopy with light scattering contrast, but it can also be used with almost any light scattering spectroscopic application which employs lenses. We demonstrate that the coherent light scattering contrast based technique allows continuous temporal tracking of the transition from non-cancerous to an early cancerous state in live cells, without exogenous markers. We also use the technique to sense differences in the aggressiveness of cancer in live cells and for label free identification of different grades of cancer in resected tumor tissues., Competing Interests: The authors declare no competing financial interest.

Published

2021

10. Two-photon polymerization nanofabrication of ultracompact light scattering spectroscopic probe for detection of pre-cancer in pancreatic cyst.

Author

Sheil CJ, Khan U, Zakharov YN, Coughlan MF, Pleskow DK, Sawhney MS, Berzin TM, Cohen JM, Glyavina M, Zhang L, Itzkan I, Perelman LT, and Qiu L

Abstract

Pancreatic cancer has one of the worst survival rates of all major cancers, with pancreatic cystic lesions accounting for one in three pancreatic surgeries. The current gold-standard for diagnosis of pancreatic cyst malignancy is based on the endoscopic ultrasound guided fine-needle aspiration (EUS-FNA) procedure, which suffers from a low accuracy in detecting malignancy. Here we present the design and two-photon polymerization based fabrication of refractive and reflective non-contact probes, capable of rapid surveillance of the entire internal cyst surface-an advance over the contact probe we recently developed that allowed, for the first time, reliable evaluation of pancreatic cyst malignant potential in vivo . We employed a novel two-photon polymerization technique, which allows direct laser-writing to an accuracy of tens of nanometers, to fit the probe within the 540 micrometer internal diameter EUS-FNA needle. The newly constructed probes show excellent separation of the illumination and collection beams, essential for proper operation of the spatial gating method. These probes can be used clinically to perform rapid "optical biopsy", ultimately eliminating unnecessary pancreatic surgeries on benign cysts and dangerous delays in surgical removal of malignant cysts, improving patient prognosis and quality of life.

Published

2021

11. Multispectral Endoscopy with Light Gating for Early Cancer Detection.

Author

Qiu L, Zhang L, Turzhitsky V, Khan U, Zakharov Y, Kantekure K, Vitkin E, Itzkan I, Pleskow DK, Sawhney M, Berzin TM, Goldsmith JD, and Perelman LT

Abstract

This paper reports the application of endoscopic light scattering spectroscopy (LSS) with light gating to detect malignancies in the biliary and pancreatic ducts, and also reviews the application of endoscopic LSS for differentiating cystic neoplasms in the pancreas and detecting invisible dysplasia in Barrett's esophagus. Information about tissue structure within the superficial epithelium where malignancy starts is present within the spectra of reflected light. Fortunately, this component of the reflected light is not yet randomized. However multiple scattering randomizes the signal from the underlying connective tissue which obscures the desired signal. In order to extract diagnostic information from the reflected signal the multiple scattering component related to connective tissue scattering and absorption must be removed. This is accomplished using described here spatial or polarization gating implemented with endoscopically compatible fiber optic probes.

Published

2019

12. Picoanalysis of Drugs in Biofluids with Quantitative Label-Free Surface-Enhanced Raman Spectroscopy.

Author

Turzhitsky V, Zhang L, Horowitz GL, Vitkin E, Khan U, Zakharov Y, Qiu L, Itzkan I, and Perelman LT

Subjects

Nanocomposites chemistry, Biosensing Techniques methods, Spectrum Analysis, Raman methods

Abstract

The enormous increase of Raman signal in the vicinity of metal nanoparticles allows surface-enhanced Raman spectroscopy (SERS) to be employed for label-free detection of substances at extremely low concentrations. However, the ultimate potential of label-free SERS to identify pharmaceutical compounds at low concentrations, especially in relation to biofluid sensing, is far from being fully realized. Opioids are a particular challenge for rapid clinical identification because their molecular structural similarities prevent their differentiation with immunolabeling approaches. In this paper, a new method called quantitative label-free SERS (QLF-SERS) which involves the formation of halide-conjugated gold nanoclusters trapping the analyte of interest near the SERS hot spots is reported, and it is demonstrated that it yields a 10 5 fold improvement in the detection limit over previously reported results for the entire class of clinically relevant opioids and their metabolites. Measurements of opioid concentrations in multicomponent mixtures are also demonstrated. QLF-SERS has comparable detection limits as currently existing laboratory urine drug testing techniques but is significantly faster and inexpensive and, therefore, can be easily adapted as part of a rapid clinical laboratory routine., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

13. Multispectral light scattering endoscopic imaging of esophageal precancer.

Author

Qiu L, Chuttani R, Pleskow DK, Turzhitsky V, Khan U, Zakharov YN, Zhang L, Berzin TM, Yee EU, Sawhney MS, Li Y, Vitkin E, Goldsmith JD, Itzkan I, and Perelman LT

Abstract

Esophageal adenocarcinoma is the most rapidly growing cancer in America. Although the prognosis after diagnosis is unfavorable, the chance of a successful outcome increases tremendously if detected early while the lesion is still dysplastic. Unfortunately, the present standard-of-care, endoscopic surveillance, has major limitations, since dysplasia is invisible, often focal, and systematic biopsies typically sample less than one percent of the esophageal lining and therefore easily miss malignancies. To solve this problem we developed a multispectral light scattering endoscopic imaging system. It surveys the entire esophageal lining and accurately detects subcellular dysplastic changes. The system combines light scattering spectroscopy, which detects and identifies invisible dysplastic sites by analyzing light scattered from epithelial cells, with rapid scanning of the entire esophageal lining using a collimated broadband light beam delivered by an endoscopically compatible fiber optic probe. Here we report the results of the first comprehensive multispectral imaging study, conducted as part of routine endoscopic procedures performed on patients with suspected dysplasia. In a double-blind study that characterized the system's ability to serve as a screening tool, 55 out of 57 patients were diagnosed correctly. In addition, a smaller double-blind comparison of the multispectral data in 24 patients with subsequent pathology at locations where 411 biopsies were collected yielded an accuracy of 90% in detecting individual locations of dysplasia, demonstrating the capability of this method to serve as a guide for biopsy.

Published

2018

14. Light scattering spectroscopy identifies the malignant potential of pancreatic cysts during endoscopy.

Author

Zhang L, Pleskow DK, Turzhitsky V, Yee EU, Berzin TM, Sawhney M, Shinagare S, Vitkin E, Zakharov Y, Khan U, Wang F, Goldsmith JD, Goldberg S, Chuttani R, Itzkan I, Qiu L, and Perelman LT

Abstract

Pancreatic cancers are usually detected at an advanced stage and have poor prognosis. About one fifth of these arise from pancreatic cystic lesions. Yet not all lesions are precancerous, and imaging tools lack adequate accuracy for distinguishing precancerous from benign cysts. Therefore, decisions on surgical resection usually rely on endoscopic ultrasound-guided fine needle aspiration (EUS-FNA). Unfortunately, cyst fluid often contains few cells, and fluid chemical analysis lacks accuracy, resulting in dire consequences, including unnecessary pancreatic surgery for benign cysts and the development of cancer. Here, we report an optical spectroscopic technique, based on a spatial gating fibre-optic probe, that predicts the malignant potential of pancreatic cystic lesions during routine diagnostic EUS-FNA procedures. In a double-blind prospective study in 25 patients, with 14 cysts measured in vivo and 13 postoperatively, the technique achieved an overall accuracy of 95%, with a 95%confidence interval of 78-99%, in cysts with definitive diagnosis., Competing Interests: Competing financial interests The authors declare no competing financial interests.

Published

2017

15. Cancer exosomes perform cell-independent microRNA biogenesis and promote tumorigenesis.

Author

Melo SA, Sugimoto H, O'Connell JT, Kato N, Villanueva A, Vidal A, Qiu L, Vitkin E, Perelman LT, Melo CA, Lucci A, Ivan C, Calin GA, and Kalluri R

Subjects

Animals, Argonaute Proteins metabolism, Breast Neoplasms genetics, Carboxypeptidases metabolism, Case-Control Studies, DEAD-box RNA Helicases metabolism, Female, Gene Expression Regulation, Neoplastic, Humans, MCF-7 Cells, Mice, RNA Processing, Post-Transcriptional, RNA-Binding Proteins metabolism, Ribonuclease III metabolism, Transcriptome, Breast Neoplasms metabolism, Carcinogenesis metabolism, Exosomes physiology, MicroRNAs biosynthesis

Abstract

Exosomes are secreted by all cell types and contain proteins and nucleic acids. Here, we report that breast cancer associated exosomes contain microRNAs (miRNAs) associated with the RISC-Loading Complex (RLC) and display cell-independent capacity to process precursor microRNAs (pre-miRNAs) into mature miRNAs. Pre-miRNAs, along with Dicer, AGO2, and TRBP, are present in exosomes of cancer cells. CD43 mediates the accumulation of Dicer specifically in cancer exosomes. Cancer exosomes mediate an efficient and rapid silencing of mRNAs to reprogram the target cell transcriptome. Exosomes derived from cells and sera of patients with breast cancer instigate nontumorigenic epithelial cells to form tumors in a Dicer-dependent manner. These findings offer opportunities for the development of exosomes based biomarkers and therapies., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

16. Rapid optimization of metal nanoparticle surface modification with high-throughput gel electrophoresis.

Author

Beskorovaynyy AV, Kopitsyn DS, Novikov AA, Ziangirova M, Skorikova GS, Kotelev MS, Gushchin PA, Ivanov EV, Getmansky MD, Itzkan I, Muradov AV, Vinokurov VA, and Perelman LT

Abstract

The ability to effectively control and optimize surface modification of metal nanoparticles is paramount to the ability to employ metal nanoparticles as diagnostic and therapeutic agents in biology and medicine. Here we present a high-throughput two-dimensional-grid gel electrophoresis cell (2D-GEC)-based method, capable of optimizing the surface modification of as many as 96 samples of metal nanoparticles in approximately 1 h. The 2D-GEC method determines not only the average zeta-potential of the modified particles but also the homogeneity of the surface modification by measuring the distance between the front of the sample track and the area where the maximum optical density is achieved. The method was tested for optimizing pH and concentration of the modifiers (pM) for functionalizing gold nanorod thiol-containing acidic agents.

Published

2014

17. Spectroscopy of scattered light for the characterization of micro and nanoscale objects in biology and medicine.

Author

Turzhitsky V, Qiu L, Itzkan I, Novikov AA, Kotelev MS, Getmanskiy M, Vinokurov VA, Muradov AV, and Perelman LT

Subjects

Spectrum Analysis, Raman, Biology, Light, Metal Nanoparticles, Nanomedicine, Scattering, Radiation

Abstract

The biomedical uses for the spectroscopy of scattered light by micro and nanoscale objects can broadly be classified into two areas. The first, often called light scattering spectroscopy (LSS), deals with light scattered by dielectric particles, such as cellular and sub-cellular organelles, and is employed to measure their size or other physical characteristics. Examples include the use of LSS to measure the size distributions of nuclei or mitochondria. The native contrast that is achieved with LSS can serve as a non-invasive diagnostic and scientific tool. The other area for the use of the spectroscopy of scattered light in biology and medicine involves using conducting metal nanoparticles to obtain either contrast or electric field enhancement through the effect of the surface plasmon resonance (SPR). Gold and silver metal nanoparticles are non-toxic, they do not photobleach, are relatively inexpensive, are wavelength-tunable, and can be labeled with antibodies. This makes them very promising candidates for spectrally encoded molecular imaging. Metal nanoparticles can also serve as electric field enhancers of Raman signals. Surface enhanced Raman spectroscopy (SERS) is a powerful method for detecting and identifying molecules down to single molecule concentrations. In this review, we will concentrate on the common physical principles, which allow one to understand these apparently different areas using similar physical and mathematical approaches. We will also describe the major advancements in each of these areas, as well as some of the exciting recent developments.

Published

2014

18. Spectral Imaging with Scattered Light: From Early Cancer Detection to Cell Biology.

Author

Qiu L, Turzhitsky V, Chuttani R, Pleskow D, Goldsmith JD, Guo L, Vitkin E, Itzkan I, Hanlon EB, and Perelman LT

Abstract

This article reports the evolution of scanning spectral imaging techniques using scattered light for minimally invasive detection of early cancerous changes in tissue and cell biology applications. Optical spectroscopic techniques have shown promising results in the diagnosis of disease on a cellular scale. They do not require tissue removal, can be performed in vivo, and allow for real time diagnoses. Fluorescence and Raman spectroscopy are most effective in revealing molecular properties of tissue. Light scattering spectroscopy (LSS) relates the spectroscopic properties of light elastically scattered by small particles, such as epithelial cell nuclei and organelles, to their size, shape and refractive index. It is capable of characterizing the structural properties of tissue on cellular and sub-cellular scales. However, in order to be useful in the detection of early cancerous changes which are otherwise not visible to the naked eye, it must rapidly survey a comparatively large area while simultaneously detecting these cellular changes. Both goals are achieved by combining LSS with spatial scanning imaging. Two examples are described in this article. The first reviews a clinical system for screening patients with Barrett's esophagus. The second presents a novel advancement in confocal light absorption and scattering spectroscopic (CLASS) microscopy.

Published

2012

19. Photon diffusion near the point-of-entry in anisotropically scattering turbid media.

Author

Vitkin E, Turzhitsky V, Qiu L, Guo L, Itzkan I, Hanlon EB, and Perelman LT

Subjects

Anisotropy, Computer Simulation, Diffusion, Epithelium pathology, Humans, Molecular Imaging statistics & numerical data, Monte Carlo Method, Photons, Scattering, Radiation, Skin Neoplasms pathology, Spectrum Analysis statistics & numerical data, Molecular Imaging methods, Skin Neoplasms diagnosis, Spectrum Analysis methods

Abstract

From astronomy to cell biology, the manner in which light propagates in turbid media has been of central importance for many decades. However, light propagation near the point-of-entry in turbid media has never been analytically described, until now. Here we report a straightforward and accurate method that overcomes this longstanding, unsolved problem in radiative transport. Our theory properly treats anisotropic photon scattering events and takes the specific form of the phase function into account. As a result, our method correctly predicts the spatially dependent diffuse reflectance of light near the point-of-entry for any arbitrary phase function. We demonstrate that the theory is in excellent agreement with both experimental results and Monte Carlo simulations for several commonly used phase functions.

Published

2011

20. Gold nanorod light scattering labels for biomedical imaging.

Author

Qiu L, Larson TA, Vitkin E, Guo L, Hanlon EB, Itzkan I, Sokolov KV, and Perelman LT

Abstract

Gold nanorods can be used as extremely bright labels for differential light scattering measurements using two closely spaced wavelengths, thereby detecting human disease through several centimeters of tissue in vivo. They have excellent biocompatibility, are non-toxic, and are not susceptible to photobleaching. They have narrow, easily tunable plasmon spectral lines and thus can image multiple molecular targets simultaneously. Because of their small size, gold nanorods can be transported to various tissues inside the human body via the vasculature and microvasculature, and since they are smaller than vascular pore sizes, they can easily cross vascular space and enter individual cells.

Published

2010

21. Multispectral scanning during endoscopy guides biopsy of dysplasia in Barrett's esophagus.

Author

Qiu L, Pleskow DK, Chuttani R, Vitkin E, Leyden J, Ozden N, Itani S, Guo L, Sacks A, Goldsmith JD, Modell MD, Hanlon EB, Itzkan I, and Perelman LT

Subjects

Barrett Esophagus complications, Biopsy methods, Diagnostic Imaging methods, Endoscopy methods, Esophageal Neoplasms complications, Gastroesophageal Reflux complications, Humans, Hyperplasia pathology, Spectrum Analysis methods, Barrett Esophagus pathology, Esophageal Neoplasms pathology, Esophagoscopy methods, Esophagus pathology, Gastroesophageal Reflux pathology

Abstract

Esophageal cancer is increasing in frequency in the United States faster than any other cancer. Barrett's esophagus, an otherwise benign complication of esophageal reflux, affects approximately three million Americans and precedes almost all cases of esophageal cancer. If detected as high-grade dysplasia (HGD), most esophageal cancers can be prevented. Standard-of-care screening for dysplasia uses visual endoscopy and a prescribed pattern of biopsy. This procedure, in which a tiny fraction of the affected tissue is selected for pathological examination, has a low probability of detection because dysplasia is highly focal and visually indistinguishable. We developed a system called endoscopic polarized scanning spectroscopy (EPSS), which performs rapid optical scanning and multispectral imaging of the entire esophageal surface and provides diagnoses in near real time. By detecting and mapping suspicious sites, guided biopsy of invisible, precancerous dysplasia becomes practicable. Here we report the development of EPSS and its application in several clinical cases, one of which merits special consideration.

Published

2010

22. Light-scattering spectroscopy differentiates fetal from adult nucleated red blood cells: may lead to noninvasive prenatal diagnosis.

Author

Lim KH, Salahuddin S, Qiu L, Fang H, Vitkin E, Ghiran IC, Modell MD, Takoudes T, Itzkan I, Hanlon EB, Sachs BP, and Perelman LT

Subjects

Adult, Erythroblasts cytology, Female, Humans, Pregnancy, Erythrocytes cytology, Fetus cytology, Light, Prenatal Diagnosis methods, Scattering, Radiation, Spectrum Analysis methods

Abstract

Present techniques for prenatal diagnosis are invasive and present significant risks of fetal loss. Noninvasive prenatal diagnosis utilizing fetal nucleated red blood cells (fNRBC) circulating in maternal peripheral blood has received attention, since it poses no risk to the fetus. However, because of the failure to find broadly applicable identifiers that can differentiate fetal from adult NRBC, reliable detection of viable fNRBC in amounts sufficient for clinical use remains a challenge. In this Letter we show that fNRBC light-scattering spectroscopic signatures may lead to a clinically useful method of minimally invasive prenatal genetic testing.

Published

2009

23. Diagnostic imaging of esophageal epithelium with clinical endoscopic polarized scanning spectroscopy instrument.

Author

Qiu L, Chuttani R, Zhang S, Feng J, Itani S, Fang H, Pleskow D, Sawhney MS, Salahuddin S, Modell MD, Vitkin E, Hanlon EB, Itzkan I, and Perelman LT

Subjects

Biopsy, Diagnostic Imaging, Epithelial Cells pathology, Equipment Design, Fiber Optic Technology, Humans, Microscopy, Polarization instrumentation, Reproducibility of Results, Spectrum Analysis methods, Barrett Esophagus pathology, Esophageal Neoplasms pathology, Esophagoscopy methods, Microscopy, Polarization methods

Abstract

This letter reports the development of an endoscopic polarized scanning spectroscopy (EPSS) instrument compatible with existing endoscopes. This instrument uses light scattering spectroscopy (LSS). In proof-of-principle studies using a single-point instrument, LSS has successfully demonstrated the ability to identify pre-cancer in the epithelial tissues of five different organs, including Barrett's esophagus (BE). The EPSS instrument can provide real time in vivo information on the location of otherwise invisible high grade dysplasia (HGD), a predictor of adenocarcinoma, and thus can serve as a guide for biopsy. It should greatly reduce the time and labor involved in performing screening and obtaining diagnoses, cause less patient discomfort and ensure that fewer biopsies are required for the reliable location of pre-cancerous lesions.

Published

2009

24. Scattering differentiates Alzheimer disease in vitro.

Author

Hanlon EB, Perelman LT, Vitkin EI, Greco FA, McKee AC, and Kowall NW

Subjects

Absorption, Alzheimer Disease pathology, Brain pathology, Humans, In Vitro Techniques, Models, Statistical, Spectrophotometry, Infrared, Spectroscopy, Fourier Transform Infrared methods, Spectroscopy, Near-Infrared methods, Alzheimer Disease diagnosis, Optics and Photonics, Scattering, Radiation

Abstract

The molecular bases of Alzheimer disease and related neurodegenerative disorders are becoming better understood, but the means for definitive diagnosis and monitoring in vivo remain lacking. Near-infrared optical spectroscopy offers a potential solution. We acquired transmission and reflectance spectra of thin brain tissue slabs, from which we calculated wavelength-dependent absorption and reduced scattering coefficients from 470-1000 nm. The reduced scattering coefficients in the near infrared clearly differentiated Alzheimer from control specimens. Diffuse reflectance spectra of gross brain tissue in vitro confirmed this observation. These results suggest a means for diagnosing and monitoring Alzheimer disease in vivo, using near-infrared optical spectroscopy.

Published

2008

25. Confocal light absorption and scattering spectroscopic microscopy monitors organelles in live cells with no exogenous labels.

Author

Itzkan I, Qiu L, Fang H, Zaman MM, Vitkin E, Ghiran IC, Salahuddin S, Modell M, Andersson C, Kimerer LM, Cipolloni PB, Lim KH, Freedman SD, Bigio I, Sachs BP, Hanlon EB, and Perelman LT

Subjects

Cell Line, Cell Survival, Humans, Microscopy methods, Organelles

Abstract

This article reports the development of an optical imaging technique, confocal light absorption and scattering spectroscopic (CLASS) microscopy, capable of noninvasively determining the dimensions and other physical properties of single subcellular organelles. CLASS microscopy combines the principles of light-scattering spectroscopy (LSS) with confocal microscopy. LSS is an optical technique that relates the spectroscopic properties of light elastically scattered by small particles to their size, refractive index, and shape. The multispectral nature of LSS enables it to measure internal cell structures much smaller than the diffraction limit without damaging the cell or requiring exogenous markers, which could affect cell function. Scanning the confocal volume across the sample creates an image. CLASS microscopy approaches the accuracy of electron microscopy but is nondestructive and does not require the contrast agents common to optical microscopy. It provides unique capabilities to study functions of viable cells, which are beyond the capabilities of other techniques.

Published

2007

26. Confocal light absorption and scattering spectroscopic microscopy.

Author

Fang H, Qiu L, Vitkin E, Zaman MM, Andersson C, Salahuddin S, Kimerer LM, Cipolloni PB, Modell MD, Turner BS, Keates SE, Bigio I, Itzkan I, Freedman SD, Bansil R, Hanlon EB, and Perelman LT

Subjects

Equipment Design, Equipment Failure Analysis, Feasibility Studies, Image Enhancement methods, Microscopy, Confocal methods, Reproducibility of Results, Scattering, Radiation, Sensitivity and Specificity, Spectrum Analysis methods, Tomography, Optical Coherence methods, Image Enhancement instrumentation, Microscopy, Confocal instrumentation, Spectrum Analysis instrumentation, Tomography, Optical Coherence instrumentation

Abstract

We have developed a novel optical method for observing submicrometer intracellular structures in living cells, which is called confocal light absorption and scattering spectroscopic (CLASS) microscopy. It combines confocal microscopy, a well-established high-resolution microscopic technique, with light-scattering spectroscopy. CLASS microscopy requires no exogenous labels and is capable of imaging and continuously monitoring individual viable cells, enabling the observation of cell and organelle functioning at scales of the order of 100 nm.

Published

2007

27. Optical diagnostic technology based on light scattering spectroscopy for early cancer detection.

Author

Perelman LT

Subjects

Early Diagnosis, Humans, Light, Neoplasms diagnosis, Optics and Photonics, Precancerous Conditions diagnosis, Scattering, Radiation, Spectrum Analysis methods

Abstract

This article reviews the application of optical diagnostic technology based on light scattering spectroscopy for minimally invasive detection of precancerous and early cancerous changes in a variety of organs. Optical spectroscopic techniques have shown promising results in the diagnosis of diseases at the cellular scale. They do not require tissue removal, can be performed in vivo and allow for real-time diagnosis. While fluorescence and Raman spectroscopy are most effective in revealing the molecular properties of tissue, the novel technique, light scattering spectroscopy, is capable of characterizing the structural properties of tissue at the cellular and subcellular scale.

Published

2006

28. Optical spectroscopy noninvasively monitors response of organelles to cellular stress.

Author

Schuele G, Vitkin E, Huie P, O'Connell-Rodwell C, Palanker D, and Perelman LT

Subjects

Animals, Cell Line, Epithelial Cells cytology, Epithelial Cells physiology, Hot Temperature, Humans, Mice, NIH 3T3 Cells, Refractometry methods, Heat-Shock Proteins metabolism, Organelles metabolism, Organelles ultrastructure, Oxidative Stress physiology, Pigment Epithelium of Eye cytology, Pigment Epithelium of Eye physiology, Spectrum Analysis methods

Abstract

Fast and noninvasive detection of cellular stress is extremely useful for fundamental research and practical applications in medicine and biology. We discovered that light scattering spectroscopy enables us to monitor the transformations in cellular organelles under thermal stress. At the temperatures triggering expression of heat shock proteins, the refractive index of mitochondria increase within 1 min after the onset of heating, indicating enhanced metabolic activity. At higher temperatures and longer exposures, the organelles increase in size. This technique provides an insight into metabolic processes within organelles larger than 50 nm without exogenous staining and opens doors for noninvasive real-time assessment of cellular stress.

Published

2005

29. Imaging human epithelial properties with polarized light-scattering spectroscopy.

Author

Gurjar RS, Backman V, Perelman LT, Georgakoudi I, Badizadegan K, Itzkan I, Dasari RR, and Feld MS

Subjects

Cell Nucleus pathology, Cell Nucleus ultrastructure, Colonic Polyps diagnosis, Colonic Polyps pathology, Epithelial Cells pathology, Epithelial Cells ultrastructure, Humans, Optics and Photonics, Precancerous Conditions diagnosis, Precancerous Conditions pathology, Scattering, Radiation, Spectrum Analysis instrumentation, Tumor Cells, Cultured, Epithelial Cells cytology, Spectrum Analysis methods

Abstract

Biomedical imaging with light-scattering spectroscopy (LSS) is a novel optical technology developed to probe the structure of living epithelial cells in situ without need for tissue removal. LSS makes it possible to distinguish between single backscattering from epithelial-cell nuclei and multiply scattered light. The spectrum of the single backscattering component is further analyzed to provide quantitative information about the epithelial-cell nuclei such as nuclear size, degree of pleomorphism, degree of hyperchromasia and amount of chromatin. LSS imaging allows mapping these histological properties over wide areas of epithelial lining. Because nuclear enlargement, pleomorphism and hyperchromasia are principal features of nuclear atypia associated with precancerous and cancerous changes in virtually all epithelia, LSS imaging can be used to detect precancerous lesions in optically accessible organs.

Published

2001

30. Fluorescence, reflectance, and light-scattering spectroscopy for evaluating dysplasia in patients with Barrett's esophagus.

Author

Georgakoudi I, Jacobson BC, Van Dam J, Backman V, Wallace MB, Müller MG, Zhang Q, Badizadegan K, Sun D, Thomas GA, Perelman LT, and Feld MS

Subjects

Cell Nucleus pathology, Humans, Light, Scattering, Radiation, Spectrometry, Fluorescence, Barrett Esophagus pathology, Esophagus pathology

Abstract

Background & Aims: The aim of this study was to assess the potential of 3 spectroscopic techniques (fluorescence, reflectance, and light-scattering spectroscopy) individually and in combination, for evaluating low- and high-grade dysplasia in patients with Barrett's esophagus (BE)., Methods: Fluorescence spectra at 11 excitation wavelengths and a reflectance spectrum were acquired in approximately 1 second from each site before biopsy using an optical fiber probe. The measured fluorescence spectra were combined with the reflectance spectra to extract the intrinsic tissue fluorescence. The reflectance spectra provided morphologic information about the bulk tissue, whereas light-scattering spectroscopy was used to determine cell nuclear crowding and enlargement in Barrett's epithelium., Results: Significant differences were observed between dysplastic and nondysplastic BE in terms of intrinsic fluorescence, bulk scattering properties, and levels of epithelial cell nuclear crowding and enlargement. The combination of all 3 techniques resulted in superior sensitivity and specificity for separating high-grade from non-high-grade and dysplastic from nondysplastic epithelium., Conclusions: Intrinsic fluorescence, reflectance, and light-scattering spectroscopies provide complementary information about biochemical and morphologic changes that occur during the development of dysplasia. The combination of these techniques (Tri-Modal Spectroscopy) can serve as an excellent tool for the evaluation of dysplasia in BE.

Published

2001

31. Endoscopic detection of dysplasia in patients with Barrett's esophagus using light-scattering spectroscopy.

Author

Wallace MB, Perelman LT, Backman V, Crawford JM, Fitzmaurice M, Seiler M, Badizadegan K, Shields SJ, Itzkan I, Dasari RR, Van Dam J, and Feld MS

Subjects

Aged, Aged, 80 and over, Female, Humans, Male, Middle Aged, Retrospective Studies, Scattering, Radiation, Sensitivity and Specificity, Single-Blind Method, Barrett Esophagus pathology, Esophagoscopy methods, Esophagus pathology

Abstract

Background & Aims: We conducted a study to assess the potential of light-scattering spectroscopy (LSS), which can measure epithelial nuclear enlargement and crowding, for in situ detection of dysplasia in patients with Barrett's esophagus., Methods: Consecutive patients with suspected Barrett's esophagus underwent endoscopy and systematic biopsy. Before biopsy, each site was sampled by LSS using a fiberoptic probe. Diffusely reflected white light was spectrally analyzed to obtain the size distribution of cell nuclei in the mucosal layer, from which the percentage of enlarged nuclei and the degree of crowding were determined. Dysplasia was assigned if more than 30% of the nuclei exceeded 10 microm and the histologic findings compared with those of 4 pathologists blinded to the light-scattering assessment. The data were then retrospectively analyzed to further explore the diagnostic potential of LSS., Results: Seventy-six sites from 13 patients were sampled. All abnormal sites and a random sample of nondysplastic sites were reviewed by the pathologists. The average diagnoses were 4 sites from 4 different patients as high-grade dysplasia (HGD), 8 sites from 5 different patients as low-grade dysplasia (LGD), 12 as indefinite for dysplasia, and 52 as nondysplastic Barrett's. The sensitivity and specificity of LSS for detecting dysplasia (either LGD or HGD) were 90% and 90%, respectively, with all HGD and 87% of LGD sites correctly classified. Decision algorithms using both nuclear enlargement and crowding further improved diagnostic accuracy, and accurately classified samples into the 4 histologic categories., Conclusions: LSS can reliably detect LGD and HGD in patients with Barrett's esophagus.

Published

2000

32. Detection of preinvasive cancer cells.

Author

Backman V, Wallace MB, Perelman LT, Arendt JT, Gurjar R, Müller MG, Zhang Q, Zonios G, Kline E, McGilligan JA, Shapshay S, Valdez T, Badizadegan K, Crawford JM, Fitzmaurice M, Kabani S, Levin HS, Seiler M, Dasari RR, Itzkan I, Van Dam J, and Feld MS

Subjects

Carcinoma pathology, Cell Nucleus pathology, Epithelium pathology, Evaluation Studies as Topic, Humans, Neoplasm Invasiveness, Scattering, Radiation, Precancerous Conditions pathology, Spectrum Analysis methods

Published

2000

33. Surface-enhanced and normal stokes and anti-stokes Raman spectroscopy of single-walled carbon nanotubes.

Author

Kneipp K, Kneipp H, Corio P, Brown SD, Shafer K, Motz J, Perelman LT, Hanlon EB, Marucci A, Dresselhaus G, and Dresselhaus MS

Subjects

Colloids, Scattering, Radiation, Surface Properties, Carbon, Silver, Spectrum Analysis, Raman methods

Abstract

Surface enhancement factors of at least 10(12) for the Raman scattering of single-walled carbon nanotubes in contact with fractal silver colloidal clusters result in measuring very narrow Raman bands corresponding to the homogeneous linewidth of the tangential C-C stretching mode in semiconducting nanotubes. Normal and surface-enhanced Stokes and anti-Stokes Raman spectra are discussed in the framework of selective resonant Raman contributions of semiconducting or metallic nanotubes to the Stokes or anti-Stokes spectra, respectively, of the population of vibrational levels due to the extremely strong surface-enhanced Raman process, and of phonon-phonon interactions.

Published

2000

34. Feasibility of field-based light scattering spectroscopy.

Author

Yang C, Perelman LT, Wax A, Dasari RR, and Feld MS

Subjects

Cell Nucleus chemistry, Cell Nucleus ultrastructure, Feasibility Studies, Interferometry, Light, Microspheres, Models, Theoretical, Phantoms, Imaging, Polystyrenes, Reproducibility of Results, Spectrum Analysis standards, Gelatin chemistry, Gelatin ultrastructure, Scattering, Radiation, Spectrum Analysis methods

Abstract

Light scattering spectroscopy (LSS) is a new technique capable of accurately measuring the features of nuclei and other cellular organelles in situ. We present the considerations required to implement and interpret field-based detection in LSS, where the scattered electric field is detected interferometrically, and demonstrate that the technique is experimentally feasible. A theoretical formalism for modeling field-based LSS signals based on Mie scattering is presented. Phase-front uniformity is shown to play an important and novel role. Results of heterodyne experiments with polystyrene microspheres that localize LSS signals to a region about 30 microns in axial extent are reported. In addition, differences between field-based LSS and the earlier intensity-based LSS are discussed.

Published

2000

35. Optical computed tomography in a turbid medium using early arriving photons.

Author

Chen K, Perelman LT, Zhang Q, Dasari RR, and Feld MS

Subjects

Algorithms, Light, Models, Theoretical, Phantoms, Imaging, Scattering, Radiation, Optics and Photonics, Photons, Polystyrenes chemistry, Tomography methods

Abstract

We employ photon migration to image absorbing objects embedded in a turbid medium. For improved resolution, we use early arriving photons (a few hundred picoseconds in excess of the time of flight), a regime in which the diffusion approximation breaks down. Our image reconstruction method is based on extension of x-ray computed tomography (CT) to the optical regime. The CT algorithm must be generalized to take into account the distributions of photon paths. We express the point spread function (PSF) in terms of the Green's function for the transport equation. This PSF then provides weighting functions for use in a generalized series expansion method of x-ray CT. Experiments were performed on a turbid medium with scattering and absorption properties similar to those of human breast tissue. Multiple absorbers were embedded into the medium to mimic tumors. Coaxial transmission scans were collected in two projections, and the early-time portions were analyzed. Through accurate modeling, we could remove the blurring associated with multiple scattering and obtain high-resolution images. Our results show that the diffusion approximation PSF is inadequate to describe the early arriving photons. A PSF incorporating causality is required to reconstruct accurate images of turbid media.

Published

2000

36. Physical properties of hydrated tissue determined by surface interferometry of laser-induced thermoelastic deformation.

Author

Dark ML, Perelman LT, Itzkan I, Schaffer JL, and Field MS

Subjects

Elasticity, Equipment Design, Humans, Interferometry instrumentation, Lasers, Menisci, Tibial physiology, Scattering, Radiation, Interferometry methods, Knee Joint physiology

Abstract

Knee meniscus is a hydrated tissue; it is a fibrocartilage of the knee joint composed primarily of water. We present results of interferometric surface monitoring by which we measure physical properties of human knee meniscal cartilage. The physical response of biological tissue to a short laser pulse is primarily thermomechanical. When the pulse is shorter than characteristic times (thermal diffusion time and acoustic relaxation time) stresses build and propagate as acoustic waves in the tissue. The tissue responds to the laser-induced stress by thermoelastic expansion. Solving the thermoelastic wave equation numerically predicts the correct laser-induced expansion. By comparing theory with experimental data, we can obtain the longitudinal speed of sound, the effective optical penetration depth and the Grüneisen coefficient. This study yields information about the laser tissue interaction and determines properties of the meniscus samples that could be used as diagnostic parameters.

Published

2000

37. Diffuse reflectance spectroscopy of human adenomatous colon polyps in vivo.

Author

Zonios G, Perelman LT, Backman V, Manoharan R, Fitzmaurice M, Van Dam J, and Feld MS

Abstract

Diffuse reflectance spectra were collected from adenomatous colon polyps (cancer precursors) and normal colonic mucosa of patients undergoing colonoscopy. We analyzed the data by using an analytical light diffusion model, which was tested and validated on a physical tissue model composed of polystyrene beads and hemoglobin. Four parameters were obtained: hemoglobin concentration, hemoglobin oxygen saturation, effective scatterer density, and effective scatterer size. Normal and adenomatous tissue sites exhibited differences in hemoglobin concentration and, on average, in effective scatterer size, which were in general agreement with other studies that employ standard methods. These results suggest that diffuse reflectance can be used to obtain tissue information about tissue structure and composition in vivo.

Published

1999

38. Spatial coherence of forward-scattered light in a turbid medium.

Author

Yang C, An K, Perelman LT, Dasari RR, and Feld MS

Subjects

Lasers, Microspheres, Polystyrenes, Extraterrestrial Environment, Light, Models, Theoretical, Scattering, Radiation

Abstract

We study spatially coherent forward-scattered light propagating in a turbid medium of moderate optical depth (0-9 mean free paths). Coherent detection was achieved by using a tilted heterodyne geometry, which desensitizes coherent detection of the attenuated incident light. We show that the degree of spatial coherence is significantly higher for light scattered only once in comparison with that for multiply scattered light and that it approaches a small constant value for large numbers of scattering events.

Published

1999

39. Distribution of the paths of early-arriving photons traversing a turbid medium.

Author

Winn JN, Perelman LT, Chen K, Wu J, Dasari RR, and Feld MS

Abstract

We describe experiments to measure the spatial and the temporal distribution of photons traversing a turbid medium in the early-arriving regime in which the photons are multiply scattered but are not completely randomized. The photon paths are resolved temporally by a streak camera and spatially by an adjustable absorbing screen with a small aperture. The results are compared with predictions of a theory based on path integrals (PIs) and with the standard diffusion approximation. The PI theory agrees with the data for both long and short times of flight; this agreement is in contrast to the diffusion approximation, which fails for short times. An alternative PI calculation, based on the use of an effective Lagrangian, also agrees with the experiments. PI theory succeeds because it preserves causality. The implications for optical tomography are discussed.

Published

1998

40. Photon migration of near-diffusive photons in turbid media: a Lagrangian-based approach.

Author

Perelman LT, Winn J, Wu J, Dasari RR, and Feld MS

Subjects

Diffusion, Mathematics, Photons, Scattering, Radiation

Abstract

We show that light transport in a turbid medium can be described by a path integral with a quasi-particle Lagrangian. The most probable trajectory over which photons can be found can be obtained from this Lagrangian. This approach extends the diffusion approximation to the near-diffusive regime, in which photons travel only a few transport mean free paths.

Published

1997

41. Time-dependent photon migration using path integrals.

Author

Perelman LT, Wu J, Wang Y, Itzkan I I, Dasari RR, and Feld MS

Published

1995

42. The thermoelastic basis of short pulsed laser ablation of biological tissue.

Author

Itzkan I, Albagli D, Dark ML, Perelman LT, von Rosenberg C, and Feld MS

Subjects

Animals, Elasticity, Hot Temperature, Humans, Laser Therapy, Lasers, Models, Theoretical

Abstract

Strong evidence that short-pulse laser ablation of biological tissues is a photomechanical process is presented. A full three-dimensional, time-dependent solution to the thermoelastic wave equation is compared to the results of experiments using an interferometric surface monitor to measure thermoelastic expansion. Agreement is excellent for calibrations performed on glass and on acrylic at low laser fluences. For cortical bone, the measurements agree well with the theoretical predictions once optical scattering is included. The theory predicts the presence of the tensile stresses necessary to rupture the tissue during photomechanical ablation. The technique is also used to monitor the ablation event both before and after material is ejected.

Published

1995

43. Photomechanical basis of laser ablation of biological tissue.

Author

Albagli D, Dark M, Perelman LT, von Rosenberg C, Itzkan I, and Feld MS

Abstract

The photomechanical model of laser ablation of biological tissue asserts that ablation is initiated when the laser-induced tensile stress exceeds the ultimate tensile strength of the target. We show that, unlike the one-dimensional thermoelastic model of laser-induced stress generation that has appeared in the literature, the full three-dimensional solution predicts the development of significant tensile stresses on the surface of the target, precisely where ablation is observed to occur. An interferometric technique has been developed to measure the time-dependent thermoelastic expansion, and the results for subthreshold laser fluences are in precise agreement with the predictions of the three-dimensional model.

Published

1994

44. Photon migration in turbid media using path integrals.

Author

Perelman LT, Wu J, Itzkan I I, and Feld MS

Published

1994