8 results on '"Nimmagadda, Likitha"'
Search Results
2. Quantification of follicles in human ovarian tissue using image processing software and trained artificial intelligence†
- Author
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Blevins, Gabrielle M, Flanagan, Colleen L, Kallakuri, Sridula S, Meyer, Owen M, Nimmagadda, Likitha, Hatch, James D, Shea, Sydney A, Padmanabhan, Vasantha, and Shikanov, Ariella
- Abstract
Cancer survival rates in prepubertal girls and young women have risen in recent decades due to increasingly efficient treatments. However, many such treatments are gonadotoxic, causing premature ovarian insufficiency, loss of fertility, and ovarian endocrine function. Implantation of donor ovarian tissue encapsulated in immune-isolating capsules is a promising method to restore physiological endocrine function without immunosuppression or risk of reintroducing cancer cells harbored by the tissue. The success of this approach is largely determined by follicle density in the implanted ovarian tissue, which is analyzed manually from histologic sections and necessitates specialized, time-consuming labor. To address this limitation, we developed a fully automated method to quantify follicle density that does not require additional coding. We first analyzed ovarian tissue from 12 human donors between 16 and 37 years old using semi-automated image processing with manual follicle annotation and then trained artificial intelligence program based on follicle identification and object classification. One operator manually analyzed 102 whole slide images from serial histologic sections. Of those, 77 images were assessed by a second manual operator, followed with an automated method utilizing artificial intelligence. Of the 1181 follicles the control operator counted, the comparison operator counted 1178, and the artificial intelligence counted 927 follicles with 80% of those being correctly identified as follicles. The three-stage artificial intelligence pipeline finished 33% faster than manual annotation. Collectively, this report supports the use of artificial intelligence and automation to select tissue donors and grafts with the greatest follicle density to ensure graft longevity for premature ovarian insufficiency treatment.Automated follicle identification performed by a trained artificial intelligence program performs similarly to human operators while being one-third faster.Graphical Abstract
- Published
- 2024
- Full Text
- View/download PDF
3. A protocol for visualization of murine in situ neurovascular interfaces
- Author
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Dang, Danielle D., primary, Chandrashekhar, Vikram, additional, Chandrashekhar, Vibhu, additional, Ghabdanzanluqui, Nagela, additional, Knutsen, Russell H., additional, Nazari, Matthew A., additional, Nimmagadda, Likitha, additional, Donahue, Danielle R., additional, McGavern, Dorian B., additional, Kozel, Beth A., additional, Heiss, John D., additional, Pacak, Karel, additional, Zhuang, Zhengping, additional, and Rosenblum, Jared S., additional
- Published
- 2023
- Full Text
- View/download PDF
4. Presence of ovarian stromal aberrations after cessation of testosterone therapy in a transgender mouse model
- Author
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Kinnear, Hadrian M, primary, Hashim, Prianka H, additional, Dela Cruz, Cynthia, additional, Chang, Faith L, additional, Rubenstein, Gillian, additional, Nimmagadda, Likitha, additional, Ramamoorthi Elangovan, Venkateswaran, additional, Jones, Andrea, additional, Brunette, Margaret A, additional, Hannum, D Ford, additional, Li, Jun Z, additional, Padmanabhan, Vasantha, additional, Moravek, Molly B, additional, and Shikanov, Ariella, additional
- Published
- 2023
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- View/download PDF
5. A mouse model mimicking gender-affirming treatment with pubertal suppression followed by testosterone in transmasculine youth
- Author
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Dela Cruz, Cynthia, primary, Kinnear, Hadrian M, additional, Hashim, Prianka H, additional, Wandoff, Abigail, additional, Nimmagadda, Likitha, additional, Chang, Faith L, additional, Padmanabhan, Vasantha, additional, Shikanov, Ariella, additional, and Moravek, Molly B, additional
- Published
- 2022
- Full Text
- View/download PDF
6. A mouse model mimicking gender-affirming treatment with pubertal suppression followed by testosterone in transmasculine youth.
- Author
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Cruz, Cynthia Dela, Kinnear, Hadrian M, Hashim, Prianka H, Wandoff, Abigail, Nimmagadda, Likitha, Chang, Faith L, Padmanabhan, Vasantha, Shikanov, Ariella, and Moravek, Molly B
- Subjects
GENDER affirming care ,LABORATORY mice ,ANIMAL disease models ,RESEARCH grants ,OVARIAN reserve ,INDUCED ovulation - Abstract
STUDY QUESTION Can mice serve as a translational model to examine the reproductive consequences of pubertal suppression with GnRH agonist (GnRHa) followed by testosterone (T) administration, a typical therapy in peripubertal transmasculine youth? SUMMARY ANSWER An implanted depot with 3.6 mg of GnRHa followed by T enanthate at 0.45 mg weekly can be used in peripubertal female mice for investigating the impact of gender-affirming hormone therapy in transmasculine youth. WHAT IS KNOWN ALREADY There is limited knowledge available in transgender medicine to provide evidence-based fertility care, with the current guidelines being based on the assumption of fertility loss. We recently successfully developed a mouse model to investigate the reproductive consequences of T therapy given to transgender men. On the other hand, to our knowledge, there is no mouse model to assess the reproductive outcomes in peripubertal transmasculine youth. STUDY DESIGN, SIZE, DURATION A total of 80 C57BL/6N female mice were used in this study, with n = 7 mice in each experimental group. PARTICIPANTS/MATERIALS, SETTING, METHODS We first assessed the effectiveness of GnRHa in arresting pubertal development in the female mice. In this experiment, 26-day-old female mice were subcutaneously implanted with a GnRHa (3.6 mg) depot. Controls underwent a sham surgery. Animals were euthanized at 3, 9, 21 and 28 days after the day of surgery. In the second experiment, we induced a transmasculine youth mouse model. C57BL/6N female mice were subcutaneously implanted with a 3.6 mg GnRHa depot on postnatal day 26 for 21 days and this was followed by weekly injections of 0.45 mg T enanthate for 6 weeks. The control for the GnRH treatment was sham surgery and the control for T treatment was sesame oil vehicle injections. Animals were sacrificed 0.5 weeks after the last injection. The data collected included the day of the vaginal opening and first estrus, daily vaginal cytology, weekly and terminal reproductive hormones levels, body/organ weights, ovarian follicular distribution and corpora lutea (CL) counts. MAIN RESULTS AND THE ROLE OF CHANCE GnRHa implanted animals remained in persistent diestrus and had reduced levels of FSH (P = 0.0013), LH (P = 0.0082) and estradiol (P = 0.0155), decreased uterine (P < 0.0001) and ovarian weights (P = 0.0002), and a lack of CL at 21 days after GnRHa implantation. T-only and GnRHa+T-treated animals were acyclic throughout the treatment period, had sustained elevated levels of T, suppressed LH levels (P < 0.0001), and an absence of CL compared to controls (P < 0.0001). Paired ovarian weights were reduced in the T-only and GnRHa+T groups compared with the control and GnRHa-only groups. LARGE SCALE DATA N/A. LIMITATIONS, REASONS FOR CAUTION Although it is an appropriate tool to provide relevant findings, precaution is needed to extrapolate mouse model results to mirror human reproductive physiology. WIDER IMPLICATIONS OF THE FINDINGS To our knowledge, this study describes the first mouse model mimicking gender-affirming hormone therapy in peripubertal transmasculine youth. This model provides a tool for researchers studying the effects of GnRHa-T therapy on other aspects of reproduction, other organ systems and transgenerational effects. The model is supported by GnRHa suppressing puberty and maintaining acyclicity during T treatment, lower LH levels and absence of CL. The results also suggest GnRHa+T therapy in peripubertal female mice does not affect ovarian reserve, since the number of primordial follicles was not affected by treatment. STUDY FUNDING/COMPETING INTEREST(S) This work was supported by the Michigan Institute for Clinical and Health Research grants KL2 TR 002241 and UL1 TR 002240 (C.D.C.); National Institutes of Health grants F30-HD100163 and T32-HD079342 (H.M.K.); University of Michigan Office of Research funding U058227 (A.S.); American Society for Reproductive Medicine/Society for Reproductive Endocrinology and Infertility grant (M.B.M.); and National Institutes of Health R01-HD098233 (M.B.M.). The University of Virginia Center for Research in Reproduction Ligand Assay and Analysis Core Facility was supported by the Eunice Kennedy Shriver NICHD/NIH grants P50-HD028934 and R24-HD102061. The authors declare that they have no competing interests. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
7. A protocol for visualization of murine in situneurovascular interfaces
- Author
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Dang, Danielle D., Chandrashekhar, Vikram, Chandrashekhar, Vibhu, Ghabdanzanluqui, Nagela, Knutsen, Russell H., Nazari, Matthew A., Nimmagadda, Likitha, Donahue, Danielle R., McGavern, Dorian B., Kozel, Beth A., Heiss, John D., Pacak, Karel, Zhuang, Zhengping, and Rosenblum, Jared S.
- Abstract
Mapping cranial vasculature and adjacent neurovascular interfaces in their entirety will enhance our understanding of central nervous system function in any physiologic state. We present a workflow to visualize in situmurine vasculature and surrounding cranial structures using terminal polymer casting of vessels, iterative sample processing and image acquisition, and automated image registration and processing. While this method does not obtain dynamic imaging due to mouse sacrifice, these studies can be performed before sacrifice and processed with other acquired images.
- Published
- 2023
- Full Text
- View/download PDF
8. A mouse model mimicking gender-affirming treatment with pubertal suppression followed by testosterone in transmasculine youth.
- Author
-
Dela Cruz C, Kinnear HM, Hashim PH, Wandoff A, Nimmagadda L, Chang FL, Padmanabhan V, Shikanov A, and Moravek MB
- Subjects
- Male, Animals, Mice, Humans, Female, Adolescent, Mice, Inbred C57BL, Disease Models, Animal, Gonadotropin-Releasing Hormone, Testosterone, Heptanoates
- Abstract
Study Question: Can mice serve as a translational model to examine the reproductive consequences of pubertal suppression with GnRH agonist (GnRHa) followed by testosterone (T) administration, a typical therapy in peripubertal transmasculine youth?, Summary Answer: An implanted depot with 3.6 mg of GnRHa followed by T enanthate at 0.45 mg weekly can be used in peripubertal female mice for investigating the impact of gender-affirming hormone therapy in transmasculine youth., What Is Known Already: There is limited knowledge available in transgender medicine to provide evidence-based fertility care, with the current guidelines being based on the assumption of fertility loss. We recently successfully developed a mouse model to investigate the reproductive consequences of T therapy given to transgender men. On the other hand, to our knowledge, there is no mouse model to assess the reproductive outcomes in peripubertal transmasculine youth., Study Design, Size, Duration: A total of 80 C57BL/6N female mice were used in this study, with n = 7 mice in each experimental group., Participants/materials, Setting, Methods: We first assessed the effectiveness of GnRHa in arresting pubertal development in the female mice. In this experiment, 26-day-old female mice were subcutaneously implanted with a GnRHa (3.6 mg) depot. Controls underwent a sham surgery. Animals were euthanized at 3, 9, 21 and 28 days after the day of surgery. In the second experiment, we induced a transmasculine youth mouse model. C57BL/6N female mice were subcutaneously implanted with a 3.6 mg GnRHa depot on postnatal day 26 for 21 days and this was followed by weekly injections of 0.45 mg T enanthate for 6 weeks. The control for the GnRH treatment was sham surgery and the control for T treatment was sesame oil vehicle injections. Animals were sacrificed 0.5 weeks after the last injection. The data collected included the day of the vaginal opening and first estrus, daily vaginal cytology, weekly and terminal reproductive hormones levels, body/organ weights, ovarian follicular distribution and corpora lutea (CL) counts., Main Results and the Role of Chance: GnRHa implanted animals remained in persistent diestrus and had reduced levels of FSH (P = 0.0013), LH (P = 0.0082) and estradiol (P = 0.0155), decreased uterine (P < 0.0001) and ovarian weights (P = 0.0002), and a lack of CL at 21 days after GnRHa implantation. T-only and GnRHa+T-treated animals were acyclic throughout the treatment period, had sustained elevated levels of T, suppressed LH levels (P < 0.0001), and an absence of CL compared to controls (P < 0.0001). Paired ovarian weights were reduced in the T-only and GnRHa+T groups compared with the control and GnRHa-only groups., Large Scale Data: N/A., Limitations, Reasons for Caution: Although it is an appropriate tool to provide relevant findings, precaution is needed to extrapolate mouse model results to mirror human reproductive physiology., Wider Implications of the Findings: To our knowledge, this study describes the first mouse model mimicking gender-affirming hormone therapy in peripubertal transmasculine youth. This model provides a tool for researchers studying the effects of GnRHa-T therapy on other aspects of reproduction, other organ systems and transgenerational effects. The model is supported by GnRHa suppressing puberty and maintaining acyclicity during T treatment, lower LH levels and absence of CL. The results also suggest GnRHa+T therapy in peripubertal female mice does not affect ovarian reserve, since the number of primordial follicles was not affected by treatment., Study Funding/competing Interest(s): This work was supported by the Michigan Institute for Clinical and Health Research grants KL2 TR 002241 and UL1 TR 002240 (C.D.C.); National Institutes of Health grants F30-HD100163 and T32-HD079342 (H.M.K.); University of Michigan Office of Research funding U058227 (A.S.); American Society for Reproductive Medicine/Society for Reproductive Endocrinology and Infertility grant (M.B.M.); and National Institutes of Health R01-HD098233 (M.B.M.). The University of Virginia Center for Research in Reproduction Ligand Assay and Analysis Core Facility was supported by the Eunice Kennedy Shriver NICHD/NIH grants P50-HD028934 and R24-HD102061. The authors declare that they have no competing interests., (© The Author(s) 2022. Published by Oxford University Press on behalf of European Society of Human Reproduction and Embryology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)
- Published
- 2023
- Full Text
- View/download PDF
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